Product Description
You can choose the 1 type that you need form these product introction.
If you have any question,please contact me.
HangZhou CHINAMFG Machinery Co.,ltd is a company specialized in research, manufacture and service of speed gearbox. Ever since establishment, we have been persisting in technical innovation, advancing the techonology to our products while maintaining our strict quality controls. It is the reason that our products branding ”Xihu (West Lake) Dis.n” have enjoyed such successful global sales.
At present, our company mainly supplies 5 series products as RV worm gearbox, UDL series speed variator,PC series helical gear unit,G3 helical geared motor and SRC helical gearbox. The products are widely applied in the mechanical equipment field such as food and beverage,cement,package,chemical and dyeing, rubber and plastic, CNC machine tool,etc.
Our products have been processed ISO 9001 Quality System Certification and exported to Italy,Spain,Britain,Poland,Turkey.The USA and other European countries,earn the good reputation with our outstanding quality and service.
Customers first,customers satisfaction, excellent after sale service and incessant innovation are our tenet and motto. We will go all out to provide all the customers with high quality and service. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery, Car |
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Hardness: | Hardened Tooth Surface |
Installation: | Vertical and Horizontal |
Samples: |
US$ 69.9/Piece
1 Piece(Min.Order) | Order Sample |
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Customization: |
Available
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.shipping-cost-tm .tm-status-off{background: none;padding:0;color: #1470cc}
Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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Payment Method: |
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Initial Payment Full Payment |
Currency: | US$ |
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Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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Can variator motors be used in both fixed and variable speed applications?
Yes, variator motors can be used in both fixed and variable speed applications. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed motors, are designed to provide flexibility in adjusting the motor’s speed according to the specific requirements of the application. This versatility allows them to be used in a wide range of applications, whether the desired speed is fixed or variable.
Here are some key points to consider regarding the use of variator motors in fixed and variable speed applications:
- Fixed Speed Applications: In fixed speed applications, where a constant speed is required throughout the operation, variator motors can still be used effectively. The motor can be set at the desired fixed speed during installation or through the control system. The advantage of using variator motors in fixed speed applications is that they often offer high efficiency and reliable performance, which can contribute to energy savings and reduced maintenance needs.
- Variable Speed Applications: Variator motors are particularly well-suited for variable speed applications, where the speed requirements may change based on different operational conditions or process demands. These motors allow for precise control over the motor’s speed, enabling optimization of the application’s performance. By adjusting the speed according to the specific requirements, variator motors can improve energy efficiency, enhance process control, reduce wear and tear on mechanical components, and enable better synchronization with other system elements.
- Speed Adjustment Range: Variator motors offer a wide range of adjustable speeds, allowing them to accommodate both fixed and variable speed applications. The speed adjustment range can vary depending on the specific model and type of variator motor. Some motors may have a limited range, while others can provide a broad range of speeds, spanning from low RPMs to high RPMs. When selecting a variator motor for a specific application, it’s essential to consider the required speed range and ensure that the motor can operate within those speed limits.
- Control Options: Variator motors often come with various control options that allow for easy adjustment of the motor’s speed. These control options can include manual control through potentiometers or dials, digital control through interface panels or keypads, or even programmable control through communication protocols such as Modbus or Ethernet. These control options facilitate the use of variator motors in both fixed and variable speed applications, as they provide flexibility in setting and changing the desired speed.
- Application Versatility: Variator motors are versatile and find applications in various industries and sectors. They can be used in applications such as conveyors, pumps, fans, compressors, mixers, machine tools, HVAC systems, robotics, and more. This versatility demonstrates how variator motors can be utilized effectively in both fixed and variable speed applications across different industries.
Overall, the use of variator motors offers flexibility and adaptability to meet the speed requirements of different applications, whether fixed or variable. By selecting the appropriate motor model, determining the desired speed range, and utilizing the available control options, variator motors can provide efficient and reliable performance in a wide range of applications.
Are there cost considerations when choosing variator motors for industrial use?
Yes, there are several cost considerations that come into play when choosing variator motors for industrial use. Here’s a detailed explanation:
When selecting variator motors for industrial applications, it’s important to evaluate not only the initial purchase cost but also the overall cost of ownership throughout the motor’s lifespan. Here are some key cost considerations to keep in mind:
- Motor Cost: The initial purchase cost of the variator motor is an important consideration. The cost can vary depending on factors such as motor power rating, brand, quality, and additional features. It’s essential to compare prices from different suppliers and manufacturers to ensure a competitive and reasonable cost for the motor.
- Efficiency: The energy efficiency of the variator motor can have a significant impact on long-term operating costs. More efficient motors consume less energy, resulting in reduced electricity bills. It’s advisable to choose high-efficiency motors that meet or exceed the minimum efficiency standards set by regulatory bodies, such as the International Electrotechnical Commission (IEC) or the National Electrical Manufacturers Association (NEMA). Although high-efficiency motors may have a higher initial cost, the energy savings over the motor’s lifespan can offset the additional investment.
- Maintenance and Service: Consider the maintenance requirements and associated costs of variator motors. Motors that require regular maintenance, such as lubrication, bearing replacements, or brush inspections, may have higher maintenance costs compared to maintenance-free or sealed motor designs. It’s important to factor in the anticipated maintenance needs and costs when evaluating the overall cost of ownership.
- Durability and Reliability: Variator motors that are built to withstand harsh operating conditions and have a long service life can offer cost advantages in the long run. Although more durable and reliable motors may have a higher upfront cost, they can minimize the need for premature motor replacements, reduce downtime, and lower maintenance and repair expenses. It’s crucial to assess the motor’s quality, reputation, and warranty provisions to gauge its expected durability and reliability.
- Control and Automation: Variator motors often come with various control options and compatibility with automation systems. While these features can enhance operational efficiency and control, they may have associated costs. Consider the cost of control devices, such as variable frequency drives (VFDs), sensors, and monitoring equipment. Additionally, if integrating the motor into an existing automation system, ensure compatibility and account for any necessary upgrades or modifications.
- Application-Specific Requirements: Some industrial applications may have specific motor requirements that can impact costs. For example, if the motor needs to operate in extreme temperatures, hazardous environments, or corrosive atmospheres, special motor designs or materials may be necessary, which can increase costs. It’s important to evaluate any application-specific requirements and associated costs when selecting variator motors.
- Future Expandability: Consider the scalability and expandability of the motor system. If there are possibilities of future capacity expansions or modifications to the industrial process, choosing a motor that can accommodate such changes can prevent the need for a costly motor replacement in the future.
By carefully considering these cost factors, industrial users can make informed decisions when selecting variator motors that strike a balance between upfront costs and long-term operational expenses. It’s advisable to consult with motor suppliers, engineers, and industry experts to assess the specific cost considerations relevant to the industrial application and ensure the optimal motor choice.
Are there specific types of variator motors designed for certain tasks or environments?
Yes, there are specific types of variator motors that are designed to suit certain tasks or operate effectively in specific environments. Here are some examples:
- Variable Frequency Drives (VFDs): VFDs are a type of variator motor designed for electric motors. They are widely used in various industrial applications and are particularly suited for tasks that require precise speed control. VFDs allow for adjustable speed by varying the frequency of the electrical power supplied to the motor. They are commonly utilized in applications such as pumps, fans, conveyors, and machine tools.
- Hydraulic Variator Motors: Hydraulic variator motors are designed for applications that require high torque and ruggedness. They are commonly used in heavy machinery, construction equipment, and industrial processes where hydraulic power is readily available. Hydraulic variators control the motor speed by adjusting the flow rate and pressure of the hydraulic fluid, allowing for variable speed operation in demanding environments.
- Variable Transmission Systems: Some variator motors are designed with variable transmission systems, such as mechanical gearboxes. These motors are suitable for applications that require adjustable speed through gear ratio changes. They are commonly used in automotive applications, industrial machinery, and equipment that benefit from mechanical speed control mechanisms.
- Electronically Controlled Variator Motors: Certain variator motors incorporate advanced electronic control systems to achieve variable speed control. These motors are often used in automation and robotics applications, where precise and programmable speed control is essential. The electronic control systems allow for integration with other control systems and enable sophisticated control algorithms to optimize performance.
- Explosion-proof Variator Motors: In hazardous environments where the presence of flammable gases or dust is a concern, explosion-proof variator motors are designed to meet strict safety standards. These motors are constructed with special enclosures, seals, and components that prevent the ignition of hazardous substances. They are commonly used in industries such as oil and gas, chemical processing, and mining.
These are just a few examples of specific types of variator motors designed for particular tasks or environments. It’s important to select the appropriate variator motor that meets the requirements of the specific application, taking into consideration factors such as speed range, load characteristics, environmental conditions, safety considerations, and regulatory compliance.
editor by CX 2024-05-17
China supplier Jwb-X Series Stepless Speed Variator with Flange Mounting vacuum pump distributors
Product Description
JWB Series Speed Variator
1. Features:
JWB-X type
- Sizes: ≥04
- Power up to 1.5 kW or more
- Cases in RAL 5571 blue cast iron
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors: 2-10r/min;4.7-23.5r/min;15-75r/min;20-100r/min, 28-140r/min, 30-150r/min;40-200r/min;60-300r/min;80-400r/min;100-500r/min;190-950r/min.
- Output Torque value max 1002Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control handwheel positionable on either side
- Slipping speed to max load at 5%
- Regulation sensibility: 0,5 rpm
- Painted with blue epoxy-polyester powder
JWB-X B type
- Sizes:01,02,03 and 04
- Power up to 1.5 kW or less
- Cases in die-cast aluminium alloy
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors: 2r/min-20r/min;4.7r/min-23.5r/min;6.5-32.5r/min, 8-40r/min, 9-45r/min, 13-65r/min, 15r/min-75r/min;18-90r/min, 25-125r/min, 28r/min-140r/min;40r/min-200r/min;60r/min-300r/min;80r/min-400r/min;100r/min-500r/min;190r/min-950r/min.
- Output Torque value max 795 Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control hand wheel positionable on either side
- Slipping speed to max load at 5%
- Regulation sensibility: 0,5 rpm
- Painted with blue epoxy-polyester powder
2. Technical parameters
Type | Output Torque | Output Shaft Dia. | Output Speed Range | 2rpm-950rpm | |
SWB01 | 2.6-1.6N.m | φ11 | Applicable Motor Power | 0.18kW-7.5kW | |
SWB02 | 258-1.8N.m | φ14,φ24,φ28,φ32 | |||
SWB03 | 426-4N.m | φ24,φ28,φ38 | Input Options | With Inline AC Motor | |
SWB04 | 795-8N.m | φ28,φ38,φ42 | With IEC Motor | ||
SWB05 | 535-16N.m | φ38,φ48,φ55 | With Input Shaft | ||
SWB06 | 1002-40N.m | φ42,φ55,φ70 | With Input Flange |
About Us
ZheJiang CHINAMFG Drive Co.,Ltd,the predecessor was a state-owned military mould enterprise, was established in 1965. CHINAMFG specializes in the complete power transmission solution for high-end equipment manufacturing industries based on the aim of “Platform Product, Application Design and Professional Service”.
Starshine have a strong technical force with over 350 employees at present, including over 30 engineering technicians, 30 quality inspectors, covering an area of 80000 square CHINAMFG and kinds of advanced processing machines and testing equipments. We have a good foundation for the industry application development and service of high-end speed reducers & variators owning to the provincial engineering technology research center,the lab of gear speed reducers, and the base of modern R&D.
Our Team
Quality Control
Quality:Insist on Improvement,Strive for Excellence With the development of equipment manufacturing indurstry,customer never satirsfy with the current quality of our products,on the contrary,wcreate the value of quality.
Quality policy:to enhance the overall level in the field of power transmission
Quality View:Continuous Improvement , pursuit of excellence
Quality Philosophy:Quality creates value
3. Incoming Quality Control
To establish the AQL acceptable level of incoming material control, to provide the material for the whole inspection, sampling, immunity. On the acceptance of qualified products to warehousing, substandard goods to take return, check, rework, rework inspection; responsible for tracking bad, to monitor the supplier to take corrective
measures to prevent recurrence.
4. Process Quality Control
The manufacturing site of the first examination, inspection and final inspection, sampling according to the requirements of some projects, judging the quality change trend;
found abnormal phenomenon of manufacturing, and supervise the production department to improve, eliminate the abnormal phenomenon or state.
5. FQC(Final QC)
After the manufacturing department will complete the product, stand in the customer’s position on the finished product quality verification, in order to ensure the quality of
customer expectations and needs.
6. OQC(Outgoing QC)
After the product sample inspection to determine the qualified, allowing storage, but when the finished product from the warehouse before the formal delivery of the goods, there is a check, this is called the shipment inspection.Check content:In the warehouse storage and transfer status to confirm, while confirming the delivery of the
product is a product inspection to determine the qualified products.
7. Certification.
Packing
Delivery
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Motor, Machinery, Agricultural Machinery, Ceramics/Porcelain |
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Hardness: | Hardened Tooth Surface |
Installation: | Horizontal Type |
Layout: | Expansion |
Gear Shape: | Planet Wheel |
Step: | Stepless |
Customization: |
Available
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Can variator motors be used in both fixed and variable speed applications?
Yes, variator motors can be used in both fixed and variable speed applications. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed motors, are designed to provide flexibility in adjusting the motor’s speed according to the specific requirements of the application. This versatility allows them to be used in a wide range of applications, whether the desired speed is fixed or variable.
Here are some key points to consider regarding the use of variator motors in fixed and variable speed applications:
- Fixed Speed Applications: In fixed speed applications, where a constant speed is required throughout the operation, variator motors can still be used effectively. The motor can be set at the desired fixed speed during installation or through the control system. The advantage of using variator motors in fixed speed applications is that they often offer high efficiency and reliable performance, which can contribute to energy savings and reduced maintenance needs.
- Variable Speed Applications: Variator motors are particularly well-suited for variable speed applications, where the speed requirements may change based on different operational conditions or process demands. These motors allow for precise control over the motor’s speed, enabling optimization of the application’s performance. By adjusting the speed according to the specific requirements, variator motors can improve energy efficiency, enhance process control, reduce wear and tear on mechanical components, and enable better synchronization with other system elements.
- Speed Adjustment Range: Variator motors offer a wide range of adjustable speeds, allowing them to accommodate both fixed and variable speed applications. The speed adjustment range can vary depending on the specific model and type of variator motor. Some motors may have a limited range, while others can provide a broad range of speeds, spanning from low RPMs to high RPMs. When selecting a variator motor for a specific application, it’s essential to consider the required speed range and ensure that the motor can operate within those speed limits.
- Control Options: Variator motors often come with various control options that allow for easy adjustment of the motor’s speed. These control options can include manual control through potentiometers or dials, digital control through interface panels or keypads, or even programmable control through communication protocols such as Modbus or Ethernet. These control options facilitate the use of variator motors in both fixed and variable speed applications, as they provide flexibility in setting and changing the desired speed.
- Application Versatility: Variator motors are versatile and find applications in various industries and sectors. They can be used in applications such as conveyors, pumps, fans, compressors, mixers, machine tools, HVAC systems, robotics, and more. This versatility demonstrates how variator motors can be utilized effectively in both fixed and variable speed applications across different industries.
Overall, the use of variator motors offers flexibility and adaptability to meet the speed requirements of different applications, whether fixed or variable. By selecting the appropriate motor model, determining the desired speed range, and utilizing the available control options, variator motors can provide efficient and reliable performance in a wide range of applications.
What resources are available for further learning about the principles and applications of variator motors?
There are several resources available for further learning about the principles and applications of variator motors. Here’s a detailed explanation:
1. Books and Publications: Numerous books and publications cover the principles, design, and applications of variator motors. Some recommended titles include “Variable Speed AC Drives with Inverter Output Filters” by Jaroslaw Guzinski and Haitham Abu-Rub, “Electric Motors and Drives: Fundamentals, Types, and Applications” by Austin Hughes and Bill Drury, and “Variable Frequency Drives: Installation and Troubleshooting” by Glen A. Mazur. These resources provide in-depth knowledge on variator motor technology, control strategies, and practical implementation.
2. Online Courses and Tutorials: Online learning platforms like Udemy, Coursera, and edX offer courses and tutorials on electric motors, motor control, and power electronics. These courses cover variator motor principles, operation, and applications, providing a structured learning experience with video lectures, quizzes, and assignments. Some courses are specifically focused on variable frequency drives (VFDs) and their applications.
3. Technical Documentation and Application Notes: Manufacturers of variator motors and associated equipment often provide technical documentation, application notes, and white papers that delve into the principles and applications of variator motors. These resources can be found on the manufacturers’ websites and offer valuable insights into motor selection, installation, and operation.
4. Professional Journals and Research Papers: Academic and professional journals in the fields of electrical engineering, power electronics, and industrial automation publish research papers and articles on variator motors. IEEE Transactions on Industrial Electronics, IEEE Industry Applications Magazine, and International Journal of Electrical Power & Energy Systems are some examples of publications that cover topics related to variator motors. Access to these resources may require subscriptions or membership in relevant professional organizations.
5. Webinars and Online Presentations: Webinars and online presentations hosted by motor manufacturers, industry associations, or technology companies can provide valuable insights into the principles and applications of variator motors. These events often feature subject matter experts who share their knowledge, discuss case studies, and answer questions from participants. Recordings of past webinars are sometimes made available for on-demand viewing.
6. Industry Forums and Discussion Groups: Online forums and discussion groups focused on electrical engineering, motor control, or industrial automation can be valuable resources for learning about variator motors. Platforms like Electrical Engineering Stack Exchange, Control.com, and LinkedIn groups dedicated to motor control offer opportunities to ask questions, engage in discussions, and learn from the experiences of industry professionals.
7. Manufacturer Training Programs: Some variator motor manufacturers offer training programs and workshops that cover the principles, operation, and applications of their products. These programs may include hands-on exercises, demonstrations, and technical support. Contacting the manufacturers directly or checking their websites can provide information on available training opportunities.
When exploring these resources, it’s important to consider the credibility of the source, relevance to specific applications, and the date of publication to ensure the information aligns with the latest advancements in variator motor technology.
By utilizing these resources, individuals can deepen their understanding of variator motors and enhance their knowledge of the principles and applications associated with this technology.
What is a variator motor, and how does it differ from traditional motors?
A variator motor, also known as a variable speed motor, is a type of motor that allows for adjustable speed control. Unlike traditional motors that operate at a fixed speed, variator motors provide the ability to vary the rotational speed to meet specific application requirements. Here are some key points differentiating variator motors from traditional motors:
- Speed Control: The primary difference between variator motors and traditional motors is the ability to control the speed. Traditional motors typically operate at a fixed speed determined by the motor’s design and the frequency of the power supply. In contrast, variator motors feature mechanisms that allow for adjustable speed control, enabling users to increase or decrease the rotational speed as needed.
- Operating Principle: Variator motors achieve variable speed control through various mechanisms. One common approach is the use of adjustable transmission systems, such as variable frequency drives (VFDs) or mechanical gearboxes. These systems allow for changes in the motor’s output speed by adjusting the input power frequency or gear ratio. Other variator motors may employ electronic or hydraulic control systems to modulate the motor’s speed based on input signals or user commands.
- Application Flexibility: The ability to adjust the speed makes variator motors highly versatile and suitable for a wide range of applications. They can be employed in situations where precise speed control, energy efficiency, or the ability to adapt to changing operational requirements is critical. Variator motors find applications in industrial machinery, conveyors, pumps, fans, and other systems where speed modulation is beneficial.
- Energy Efficiency: Variator motors often exhibit higher energy efficiency compared to traditional motors, especially when operating at reduced speeds. By adjusting the motor’s speed to match the required output, variator motors can minimize energy wastage associated with running at fixed speeds. This energy-saving capability can lead to reduced operating costs and improved overall system efficiency.
- Cost and Complexity: Variator motors, due to their speed control capabilities, can be more complex and costly compared to traditional motors. The additional components required for speed modulation, such as variable frequency drives or control systems, can increase the overall system complexity and initial investment. However, the benefits of adjustable speed control and energy efficiency often outweigh the higher upfront costs in many applications.
In summary, a variator motor allows for adjustable speed control, enabling users to change the rotational speed to meet specific application requirements. With their ability to modulate speed, variator motors offer greater flexibility, energy efficiency, and application versatility compared to traditional motors.
editor by CX 2024-05-17
China Hot selling Manual Governor Friction Wheel Speed Regulation Speed Variator wholesaler
Product Description
JWB-X SERIES SPEED VARIATOR
Characteristics
JWB-X With great reliability developed over 30 years of service, the JWB-X series is a valid alternative to electronic drives and is easy to use and maintain.
The JWB-X type in cast iron includes a wide range of models with flange, feet, with input shaft or in motorized version, are available in size number 04 and 05 ,input power is 1.1kw, 1.5kw,2.2kw,3kw,4kw.
The low-cost, light weight JWB-X B versions in aluminium,are available in size number 01, 02 and 03,04, input power is 0.18kw,0.25kw,0.37kw,0.55kw , 0.75kw,1.1kw and 1.5kw.
All type Certifications Available: ISO,CE,CQC,TUV,CCC certificate.
JWB-X type
- Sizes: 04,05
- Motor Power from 1.1 kW to 4 kW (Incldue 1.1kW,1.5kW,2.2kW,3kW,4kW)
- Cases in RAL 5571 blue cast iron
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190-950r/min; 100-500r/min;80-400r/min;60-300r/min;40-200r/min;
30-150r/min;28-140r/min; 20-100r/min; 15-75r/min;4.7-23.5r/min;2-10r/min;
Output Torque value max 535Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control handwheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
JWB-X B type
- Sizes: 01,02,03 and 04
- Motor Power up to 1.5 kW or less
(Incldue 0.18kW,0.25kW,0.37kW,0.55kW,0.75kW,1.1kW,1.5kW)
- Cases in die-cast aluminium alloy
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190r/min-950r/min; 100r/min-500r/min;80r/min-400r/min;60r/min-300r/min;
40r/min-200r/min;28r/min-140r/min;25-125r/min; 18-90r/min; 15r/min-75r/min;
13-65r/min; 9-45r/min; 8-40r/min; 6.5-32.5r/min;4.7r/min-23.5r/min;2r/min-10r/min.
- Output Torque value max 795 Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control hand wheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
SPEED VARIATOR | Output Speed Range: | ||||
SWB SERIES | 2rpm-950rpm | ||||
Applicable Motor Power: | |||||
0.18kW-7.5kW | |||||
Input Options 1: | |||||
Type | Old Type | Output Torque | Output Shaft Dia. | With Inline AC Motor | |
SWB01 | JWB01 | 2.6-1.6N.m | φ11 | Input Options 2: | |
SWB02 | JWB02 | 258-1.8N.m | φ14, φ24, φ28, φ32 | With IEC Motor | |
SWB03 | JWB03 | 426-4N.m | φ24, φ28, φ28, φ38 | Input Options 3: | |
SWB04 | JWB04 | 795-8N.m | φ28, φ38, φ38, φ42 | With Input Shaft | |
SWB05 | JWB05 | 535-16N.m | φ38, φ48, φ55 | Input Options 4: | |
SWB06 | JWB06 | 1002-40N.m | φ42, φ55, φ70 | With Input Flange |
Starshine Drive
Certificate
Our Team
Quality Control
Packing
Delivery
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Type: | Ceramic, Glass, Logistic |
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Certification: | CE, ISO, CQC,SGS,TUV |
Structure: | Horizontal |
Control System: | Manual Adjustment |
Glass Washing Machine Type: | Transmission Parts |
Glass Edging Machine Type: | Transmission Parts |
Samples: |
US$ 300/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
|
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Can variator motors be used in both fixed and variable speed applications?
Yes, variator motors can be used in both fixed and variable speed applications. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed motors, are designed to provide flexibility in adjusting the motor’s speed according to the specific requirements of the application. This versatility allows them to be used in a wide range of applications, whether the desired speed is fixed or variable.
Here are some key points to consider regarding the use of variator motors in fixed and variable speed applications:
- Fixed Speed Applications: In fixed speed applications, where a constant speed is required throughout the operation, variator motors can still be used effectively. The motor can be set at the desired fixed speed during installation or through the control system. The advantage of using variator motors in fixed speed applications is that they often offer high efficiency and reliable performance, which can contribute to energy savings and reduced maintenance needs.
- Variable Speed Applications: Variator motors are particularly well-suited for variable speed applications, where the speed requirements may change based on different operational conditions or process demands. These motors allow for precise control over the motor’s speed, enabling optimization of the application’s performance. By adjusting the speed according to the specific requirements, variator motors can improve energy efficiency, enhance process control, reduce wear and tear on mechanical components, and enable better synchronization with other system elements.
- Speed Adjustment Range: Variator motors offer a wide range of adjustable speeds, allowing them to accommodate both fixed and variable speed applications. The speed adjustment range can vary depending on the specific model and type of variator motor. Some motors may have a limited range, while others can provide a broad range of speeds, spanning from low RPMs to high RPMs. When selecting a variator motor for a specific application, it’s essential to consider the required speed range and ensure that the motor can operate within those speed limits.
- Control Options: Variator motors often come with various control options that allow for easy adjustment of the motor’s speed. These control options can include manual control through potentiometers or dials, digital control through interface panels or keypads, or even programmable control through communication protocols such as Modbus or Ethernet. These control options facilitate the use of variator motors in both fixed and variable speed applications, as they provide flexibility in setting and changing the desired speed.
- Application Versatility: Variator motors are versatile and find applications in various industries and sectors. They can be used in applications such as conveyors, pumps, fans, compressors, mixers, machine tools, HVAC systems, robotics, and more. This versatility demonstrates how variator motors can be utilized effectively in both fixed and variable speed applications across different industries.
Overall, the use of variator motors offers flexibility and adaptability to meet the speed requirements of different applications, whether fixed or variable. By selecting the appropriate motor model, determining the desired speed range, and utilizing the available control options, variator motors can provide efficient and reliable performance in a wide range of applications.
Are there cost considerations when choosing variator motors for industrial use?
Yes, there are several cost considerations that come into play when choosing variator motors for industrial use. Here’s a detailed explanation:
When selecting variator motors for industrial applications, it’s important to evaluate not only the initial purchase cost but also the overall cost of ownership throughout the motor’s lifespan. Here are some key cost considerations to keep in mind:
- Motor Cost: The initial purchase cost of the variator motor is an important consideration. The cost can vary depending on factors such as motor power rating, brand, quality, and additional features. It’s essential to compare prices from different suppliers and manufacturers to ensure a competitive and reasonable cost for the motor.
- Efficiency: The energy efficiency of the variator motor can have a significant impact on long-term operating costs. More efficient motors consume less energy, resulting in reduced electricity bills. It’s advisable to choose high-efficiency motors that meet or exceed the minimum efficiency standards set by regulatory bodies, such as the International Electrotechnical Commission (IEC) or the National Electrical Manufacturers Association (NEMA). Although high-efficiency motors may have a higher initial cost, the energy savings over the motor’s lifespan can offset the additional investment.
- Maintenance and Service: Consider the maintenance requirements and associated costs of variator motors. Motors that require regular maintenance, such as lubrication, bearing replacements, or brush inspections, may have higher maintenance costs compared to maintenance-free or sealed motor designs. It’s important to factor in the anticipated maintenance needs and costs when evaluating the overall cost of ownership.
- Durability and Reliability: Variator motors that are built to withstand harsh operating conditions and have a long service life can offer cost advantages in the long run. Although more durable and reliable motors may have a higher upfront cost, they can minimize the need for premature motor replacements, reduce downtime, and lower maintenance and repair expenses. It’s crucial to assess the motor’s quality, reputation, and warranty provisions to gauge its expected durability and reliability.
- Control and Automation: Variator motors often come with various control options and compatibility with automation systems. While these features can enhance operational efficiency and control, they may have associated costs. Consider the cost of control devices, such as variable frequency drives (VFDs), sensors, and monitoring equipment. Additionally, if integrating the motor into an existing automation system, ensure compatibility and account for any necessary upgrades or modifications.
- Application-Specific Requirements: Some industrial applications may have specific motor requirements that can impact costs. For example, if the motor needs to operate in extreme temperatures, hazardous environments, or corrosive atmospheres, special motor designs or materials may be necessary, which can increase costs. It’s important to evaluate any application-specific requirements and associated costs when selecting variator motors.
- Future Expandability: Consider the scalability and expandability of the motor system. If there are possibilities of future capacity expansions or modifications to the industrial process, choosing a motor that can accommodate such changes can prevent the need for a costly motor replacement in the future.
By carefully considering these cost factors, industrial users can make informed decisions when selecting variator motors that strike a balance between upfront costs and long-term operational expenses. It’s advisable to consult with motor suppliers, engineers, and industry experts to assess the specific cost considerations relevant to the industrial application and ensure the optimal motor choice.
In which industries are variator motors commonly used for different applications?
Variator motors, with their adjustable speed control capabilities, find applications in various industries where precise speed control, energy efficiency, and adaptability to changing operational requirements are essential. Here are some industries where variator motors are commonly used for different applications:
- Industrial Manufacturing: Variator motors are extensively utilized in industrial manufacturing processes. They can be found in machinery and equipment such as conveyors, mixers, extruders, and packaging machines. The ability to adjust the speed of these motors allows for efficient material handling, mixing, blending, and product packaging.
- Material Handling and Logistics: In the material handling and logistics industry, variator motors are commonly employed in conveyor systems. These motors enable precise control of product movement, allowing for smooth and efficient transfer of goods in manufacturing plants, warehouses, airports, and distribution centers.
- Pumping and Water Treatment: Variator motors are utilized in pumping systems for water treatment, wastewater management, and irrigation. The adjustable speed control feature enables the optimization of pumping rates based on demand, resulting in energy savings and improved system efficiency.
- HVAC (Heating, Ventilation, and Air Conditioning): Variator motors play a crucial role in HVAC systems, particularly in fans and blowers. By adjusting the motor speed, these systems can modulate the airflow and temperature control, ensuring optimal comfort and energy efficiency in commercial buildings, residential complexes, and industrial facilities.
- Automotive Industry: Variator motors are used in various applications within the automotive industry. They can be found in vehicle cooling systems, power steering systems, and engine control units. The ability to adjust the motor speed allows for efficient cooling, precise steering assistance, and optimal engine performance.
- Renewable Energy: Variator motors are employed in renewable energy systems such as wind turbines and solar tracking systems. In wind turbines, variator motors enable the adjustment of blade pitch for optimal power generation. In solar tracking systems, they control the movement of solar panels to maximize exposure to sunlight throughout the day.
- Food and Beverage: Variator motors find applications in the food and beverage industry, particularly in mixing, blending, and processing equipment. They enable precise control of speed and agitation, ensuring consistent product quality and efficient production processes.
These are just a few examples of industries where variator motors are commonly used. Their versatility and ability to provide adjustable speed control make them suitable for a wide range of applications across different sectors.
editor by CX 2024-05-16
China Professional Mechanical Variators with Flange Mounted with Best Sales
Product Description
JWB-X SERIES SPEED VARIATOR
Characteristics
JWB-X With great reliability developed over 30 years of service, the JWB-X series is a valid alternative to electronic drives and is easy to use and maintain.
The JWB-X type in cast iron includes a wide range of models with flange, feet, with input shaft or in motorized version, are available in size number 04 and 05 ,input power is 1.1kw, 1.5kw,2.2kw,3kw,4kw.
The low-cost, light weight JWB-X B versions in aluminium,are available in size number 01, 02 and 03,04, input power is 0.18kw,0.25kw,0.37kw,0.55kw , 0.75kw,1.1kw and 1.5kw.
All type Certifications Available: ISO,CE,CQC,TUV,CCC certificate.
JWB-X type
- Sizes: 04,05
- Motor Power from 1.1 kW to 4 kW (Incldue 1.1kW,1.5kW,2.2kW,3kW,4kW)
- Cases in RAL 5571 blue cast iron
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190-950r/min; 100-500r/min;80-400r/min;60-300r/min;40-200r/min;
30-150r/min;28-140r/min; 20-100r/min; 15-75r/min;4.7-23.5r/min;2-10r/min;
Output Torque value max 535Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control handwheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
JWB-X B type
- Sizes: 01,02,03 and 04
- Motor Power up to 1.5 kW or less
(Incldue 0.18kW,0.25kW,0.37kW,0.55kW,0.75kW,1.1kW,1.5kW)
- Cases in die-cast aluminium alloy
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190r/min-950r/min; 100r/min-500r/min;80r/min-400r/min;60r/min-300r/min;
40r/min-200r/min;28r/min-140r/min;25-125r/min; 18-90r/min; 15r/min-75r/min;
13-65r/min; 9-45r/min; 8-40r/min; 6.5-32.5r/min;4.7r/min-23.5r/min;2r/min-10r/min.
- Output Torque value max 795 Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control hand wheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
SPEED VARIATOR | Output Speed Range: | ||||
SWB SERIES | 2rpm-950rpm | ||||
Applicable Motor Power: | |||||
0.18kW-7.5kW | |||||
Input Options 1: | |||||
Type | Old Type | Output Torque | Output Shaft Dia. | With Inline AC Motor | |
SWB01 | JWB01 | 2.6-1.6N.m | φ11 | Input Options 2: | |
SWB02 | JWB02 | 258-1.8N.m | φ14, φ24, φ28, φ32 | With IEC Motor | |
SWB03 | JWB03 | 426-4N.m | φ24, φ28, φ28, φ38 | Input Options 3: | |
SWB04 | JWB04 | 795-8N.m | φ28, φ38, φ38, φ42 | With Input Shaft | |
SWB05 | JWB05 | 535-16N.m | φ38, φ48, φ55 | Input Options 4: | |
SWB06 | JWB06 | 1002-40N.m | φ42, φ55, φ70 | With Input Flange |
Starshine Drive
Certificate
Our Team
Quality Control
Packing
Delivery
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Type: | Ceramic, Glass, Logistic |
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Certification: | CE, ISO, CQC,SGS,TUV |
Structure: | Horizontal |
Control System: | Manual Adjustment |
Glass Washing Machine Type: | Transmission Parts |
Glass Edging Machine Type: | Transmission Parts |
Samples: |
US$ 300/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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Are variator motors suitable for applications requiring precise speed control?
Yes, variator motors are generally suitable for applications requiring precise speed control. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed motors, are designed to provide adjustable speed control over a wide range. They allow the user to vary the motor’s speed according to the specific requirements of the application. This flexibility makes them well-suited for applications that demand precise speed control.
Here are some reasons why variator motors are suitable for applications requiring precise speed control:
- Speed Adjustment Range: Variator motors offer a wide range of adjustable speeds, allowing for precise control over the motor’s rotational speed. Depending on the specific model and type of variator motor, the speed adjustment range can vary from a few RPM (Revolutions Per Minute) to thousands of RPM. This versatility enables the motor to operate at different speeds, accommodating varying process or load requirements.
- Smooth Speed Transitions: Variator motors can provide smooth and gradual speed transitions. They offer precise speed control without sudden jolts or jerks during acceleration or deceleration. This feature is especially important in applications where precise speed control is critical for maintaining product quality, preventing damage to sensitive equipment, or ensuring smooth operation of processes.
- Speed Accuracy and Stability: Variator motors can achieve high speed accuracy and stability. They can maintain the desired speed setting within tight tolerances, minimizing deviations and fluctuations. This level of control is essential in applications that require precise synchronization, coordination with other system components, or adherence to specific speed profiles.
- Control Options: Variator motors often come with various control options, allowing for precise speed adjustments. These options can include manual control through potentiometers or dials, digital control through interface panels or keypads, or even programmable control through communication protocols such as Modbus or Ethernet. The availability of different control options enhances the motor’s suitability for applications requiring precise speed control.
- Response Time: Variator motors can typically achieve fast response times when adjusting the speed. They can quickly respond to speed commands or changes in the control signal, allowing for precise and immediate adjustments. This responsiveness is beneficial in applications where rapid speed changes or dynamic response is required to meet changing operational conditions.
- Closed-Loop Control Capability: Some variator motors are equipped with closed-loop control capabilities. Closed-loop control involves using feedback sensors, such as encoders or tachometers, to continuously monitor the motor’s actual speed and compare it to the desired speed. The control system adjusts the motor’s speed based on this feedback, ensuring precise speed control and compensating for any variations or disturbances.
- Application Versatility: Variator motors are versatile and can be used in a wide range of applications requiring precise speed control. They find applications in industries such as manufacturing, automation, robotics, HVAC (heating, ventilation, and air conditioning), conveyors, pumps, fans, and many others.
However, it’s important to note that the suitability of variator motors for precise speed control may vary depending on factors such as the specific motor model, control system, and the desired level of precision. It’s recommended to consult the motor manufacturer or an expert in motor control to determine the best solution for a particular application.
How do variator motors contribute to energy efficiency in manufacturing processes?
Variator motors play a significant role in improving energy efficiency in manufacturing processes. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed drives, offer the ability to adjust the motor’s speed and torque according to the requirements of the manufacturing process. This flexibility provides several ways in which variator motors contribute to energy efficiency:
- Optimized Process Control: By varying the motor’s speed, variator motors allow manufacturers to precisely match the motor’s output to the process requirements. This optimization eliminates the need for constant full-speed operation, which can result in unnecessary energy consumption. Instead, the motor can run at reduced speeds during periods of lower demand, resulting in energy savings.
- Reduced Mechanical Losses: Traditional motors operating at fixed speeds often use mechanical devices, such as throttling valves or dampers, to control the process flow or pressure. These devices introduce additional mechanical losses that consume energy. With variator motors, the motor speed can be adjusted directly, eliminating the need for such mechanical control devices and reducing energy losses associated with them.
- Efficient Motor Operation: Variator motors are designed to operate efficiently over a broad range of speeds. Unlike fixed-speed motors that may experience reduced efficiency at lower speeds, variator motors can maintain high efficiency even at reduced speeds. This efficiency is achieved through advanced motor designs, improved motor control algorithms, and the use of technologies like permanent magnet motors or synchronous reluctance motors.
- Power Factor Correction: Variator motors can incorporate power factor correction (PFC) techniques to improve the power factor of the motor. Power factor is a measure of how effectively the motor utilizes the supplied electrical power. By improving the power factor, variator motors reduce the reactive power drawn from the power grid, resulting in lower electricity bills and reduced strain on the electrical distribution system.
- Energy Recovery: Some variator motors can feature regenerative capabilities, allowing them to recover and feed excess energy back into the power grid or reuse it within the manufacturing process. For example, in applications where the motor decelerates or operates as a generator, the energy generated can be fed back into the grid or used to power other equipment, further enhancing energy efficiency.
- Process Optimization: Variator motors offer the advantage of precise control over motor speed and torque. This control can be utilized to optimize manufacturing processes, such as matching the motor speed to the optimal speed for material handling, mixing, or other process requirements. By fine-tuning the motor operation, variator motors enable improved process efficiency, reduced material waste, and energy savings.
By leveraging the flexibility and control offered by variator motors, manufacturers can achieve substantial energy savings in their production processes. The specific energy-saving potential will depend on the application, process requirements, and the extent to which the motor’s speed and torque can be optimized. It’s important to consult with motor manufacturers, engineers, and energy experts to assess the suitability and potential energy savings of variator motors in specific manufacturing applications.
What is a variator motor, and how does it differ from traditional motors?
A variator motor, also known as a variable speed motor, is a type of motor that allows for adjustable speed control. Unlike traditional motors that operate at a fixed speed, variator motors provide the ability to vary the rotational speed to meet specific application requirements. Here are some key points differentiating variator motors from traditional motors:
- Speed Control: The primary difference between variator motors and traditional motors is the ability to control the speed. Traditional motors typically operate at a fixed speed determined by the motor’s design and the frequency of the power supply. In contrast, variator motors feature mechanisms that allow for adjustable speed control, enabling users to increase or decrease the rotational speed as needed.
- Operating Principle: Variator motors achieve variable speed control through various mechanisms. One common approach is the use of adjustable transmission systems, such as variable frequency drives (VFDs) or mechanical gearboxes. These systems allow for changes in the motor’s output speed by adjusting the input power frequency or gear ratio. Other variator motors may employ electronic or hydraulic control systems to modulate the motor’s speed based on input signals or user commands.
- Application Flexibility: The ability to adjust the speed makes variator motors highly versatile and suitable for a wide range of applications. They can be employed in situations where precise speed control, energy efficiency, or the ability to adapt to changing operational requirements is critical. Variator motors find applications in industrial machinery, conveyors, pumps, fans, and other systems where speed modulation is beneficial.
- Energy Efficiency: Variator motors often exhibit higher energy efficiency compared to traditional motors, especially when operating at reduced speeds. By adjusting the motor’s speed to match the required output, variator motors can minimize energy wastage associated with running at fixed speeds. This energy-saving capability can lead to reduced operating costs and improved overall system efficiency.
- Cost and Complexity: Variator motors, due to their speed control capabilities, can be more complex and costly compared to traditional motors. The additional components required for speed modulation, such as variable frequency drives or control systems, can increase the overall system complexity and initial investment. However, the benefits of adjustable speed control and energy efficiency often outweigh the higher upfront costs in many applications.
In summary, a variator motor allows for adjustable speed control, enabling users to change the rotational speed to meet specific application requirements. With their ability to modulate speed, variator motors offer greater flexibility, energy efficiency, and application versatility compared to traditional motors.
editor by CX 2024-05-16
China Standard Udl0.37 Speed Variator Motor Variator with Foot with Best Sales
Product Description
The design of UDL series planet cone-disk stepless speed variator compromises the advanced technology both at home and abroad.
Speed variator introduction:
1) High precision of speed regulating for speed variator,UD gear box: up to 0.5-1 round
2) Large speed-changing range: the speed ratio ranges from 1:1.4 to 1:7 freely
3) High intensity and long serving time
4) Convenient to regulate speed
5) Continuously workable, bidirectional working direction,smooth running,
stable, and quiet
6) Fully sealed and suitable to any environment
7) Compact structure, small size
8) High quality aluminum alloy die-cast, elegant shape, light weight and non-rusting
9) Good adaptability: can be combined with all kinds of reducers to achieve low
stepless speed changing
10) Input power: 0.18-7.5kW
Power | Model | I | n2(r/min) | M2(NM) |
0.18kw | UDL0.18 | 1.6-8.2 | 880-170 | 1.5~3 |
0.37kw | UDL0.37 | 1.4-7 | 1000-200 | 3~6 |
0.55kw | UDL0.55 | 1.4-7 | 1000-200 | 4~8 |
0.75kw | UDL0.75 | 1.4-7 | 1000-200 | 6~12 |
1.1kw | UD1.1 | 1.4-7 | 1000-200 | 9~18 |
1.5kw | UD1.5 | 1.4-7 | 1000-200 | 12~24 |
2.2kw | UD2.2 | 1.4-7 | 1000-200 | 18~36 |
3kw | UD3 | 1.4-7 | 1000-200 | 24~48 |
4kw | UD4 | 1.4-7 | 1000-200 | 32-64 |
UDL series planet cone-disk stepless speed variators are widely used for all kinds of automatic production lines,pipelines and assembly
lines which need speed-regulation.It’s a good companion for your proction. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery, Car |
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Function: | Distribution Power, Clutch, Change Drive Torque, Change Drive Direction, Speed Changing, Speed Reduction, Speed Increase |
Layout: | Cycloidal |
Samples: |
US$ 77/Piece
1 Piece(Min.Order) | Order Sample |
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Customization: |
Available
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Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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Payment Method: |
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Initial Payment Full Payment |
Currency: | US$ |
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Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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What safety considerations are associated with the installation and operation of variator motors?
When installing and operating variator motors, several safety considerations should be taken into account. Here’s a detailed explanation:
Variator motors, like any other electrical or mechanical equipment, require proper installation, operation, and maintenance to ensure safe and reliable performance. Here are some key safety considerations associated with the installation and operation of variator motors:
- Electrical Safety: Variator motors are powered by electricity, so it’s crucial to follow electrical safety guidelines during installation and operation. This includes ensuring proper grounding of the motor and adhering to local electrical codes and regulations. It’s important to have a qualified electrician handle the electrical connections and ensure that the motor is properly wired and protected from electrical hazards.
- Mechanical Safety: Variator motors often have moving parts and may be connected to mechanical systems. During installation, it’s necessary to ensure that the motor is securely mounted and aligned with the driven equipment. Adequate guarding should be provided to prevent accidental contact with moving parts, such as belts, pulleys, or couplings. Properly sized and rated couplings, belts, and other mechanical components should be used to ensure safe and reliable operation.
- Overload Protection: Variator motors should be protected against overloading. Overloading can cause overheating, reduced motor life, and potential safety hazards. It’s important to select a motor with the appropriate power rating for the application and ensure that it’s not subjected to excessive loads. Additional overload protection devices, such as thermal protectors or overload relays, may be necessary to safeguard the motor and prevent damage or hazards.
- Heat Dissipation: Variator motors can generate heat during operation, especially at higher speeds or under heavy loads. Sufficient ventilation and cooling should be provided to dissipate the heat effectively. Adequate clearance around the motor and proper ventilation in the motor enclosure or installation area can help prevent overheating and ensure safe operation. It’s important to follow the manufacturer’s recommendations regarding cooling and ventilation requirements.
- Environmental Considerations: The installation and operation of variator motors should consider the environmental conditions in which they will be used. For example, if the motor will be exposed to moisture, dust, or corrosive substances, appropriate measures should be taken to protect the motor against these elements. This may include using sealed motor enclosures or installing the motor in a suitable protective housing. Additionally, if the motor will be used in hazardous locations, such as areas with flammable gases or dust, it must comply with the applicable safety standards and requirements.
- Proper Maintenance: Regular maintenance is essential for the safe and reliable operation of variator motors. This includes periodic inspection, cleaning, and lubrication of the motor and its components. It’s important to follow the manufacturer’s maintenance guidelines and schedule to ensure that the motor remains in good working condition. Any signs of wear, damage, or abnormal operating conditions should be addressed promptly to prevent safety risks.
- Training and Awareness: Proper training and awareness of the operators and maintenance personnel are crucial for safe operation and maintenance of variator motors. Operators should be knowledgeable about the motor’s operation, control features, and emergency procedures. Maintenance personnel should be trained to perform maintenance tasks safely and be aware of potential hazards associated with the motor. Regular safety training and refresher courses can help promote a safe working environment.
It’s important to note that the specific safety considerations may vary depending on the motor model, application, and local regulations. Therefore, it’s recommended to consult the manufacturer’s documentation and guidelines, as well as relevant safety standards, to ensure that all necessary safety precautions are followed during the installation and operation of variator motors.
Are there cost considerations when choosing variator motors for industrial use?
Yes, there are several cost considerations that come into play when choosing variator motors for industrial use. Here’s a detailed explanation:
When selecting variator motors for industrial applications, it’s important to evaluate not only the initial purchase cost but also the overall cost of ownership throughout the motor’s lifespan. Here are some key cost considerations to keep in mind:
- Motor Cost: The initial purchase cost of the variator motor is an important consideration. The cost can vary depending on factors such as motor power rating, brand, quality, and additional features. It’s essential to compare prices from different suppliers and manufacturers to ensure a competitive and reasonable cost for the motor.
- Efficiency: The energy efficiency of the variator motor can have a significant impact on long-term operating costs. More efficient motors consume less energy, resulting in reduced electricity bills. It’s advisable to choose high-efficiency motors that meet or exceed the minimum efficiency standards set by regulatory bodies, such as the International Electrotechnical Commission (IEC) or the National Electrical Manufacturers Association (NEMA). Although high-efficiency motors may have a higher initial cost, the energy savings over the motor’s lifespan can offset the additional investment.
- Maintenance and Service: Consider the maintenance requirements and associated costs of variator motors. Motors that require regular maintenance, such as lubrication, bearing replacements, or brush inspections, may have higher maintenance costs compared to maintenance-free or sealed motor designs. It’s important to factor in the anticipated maintenance needs and costs when evaluating the overall cost of ownership.
- Durability and Reliability: Variator motors that are built to withstand harsh operating conditions and have a long service life can offer cost advantages in the long run. Although more durable and reliable motors may have a higher upfront cost, they can minimize the need for premature motor replacements, reduce downtime, and lower maintenance and repair expenses. It’s crucial to assess the motor’s quality, reputation, and warranty provisions to gauge its expected durability and reliability.
- Control and Automation: Variator motors often come with various control options and compatibility with automation systems. While these features can enhance operational efficiency and control, they may have associated costs. Consider the cost of control devices, such as variable frequency drives (VFDs), sensors, and monitoring equipment. Additionally, if integrating the motor into an existing automation system, ensure compatibility and account for any necessary upgrades or modifications.
- Application-Specific Requirements: Some industrial applications may have specific motor requirements that can impact costs. For example, if the motor needs to operate in extreme temperatures, hazardous environments, or corrosive atmospheres, special motor designs or materials may be necessary, which can increase costs. It’s important to evaluate any application-specific requirements and associated costs when selecting variator motors.
- Future Expandability: Consider the scalability and expandability of the motor system. If there are possibilities of future capacity expansions or modifications to the industrial process, choosing a motor that can accommodate such changes can prevent the need for a costly motor replacement in the future.
By carefully considering these cost factors, industrial users can make informed decisions when selecting variator motors that strike a balance between upfront costs and long-term operational expenses. It’s advisable to consult with motor suppliers, engineers, and industry experts to assess the specific cost considerations relevant to the industrial application and ensure the optimal motor choice.
Can you explain the principle behind the variable speed control in variator motors?
The variable speed control in variator motors is achieved through various mechanisms depending on the specific type of variator motor. Here, we’ll explore a few common principles behind variable speed control:
- Adjustable Transmission Systems: Many variator motors utilize adjustable transmission systems to achieve variable speed control. One common example is the use of variable frequency drives (VFDs) in electric motors. VFDs facilitate speed control by adjusting the frequency of the electrical power supplied to the motor. By modifying the frequency, the VFD can change the rotational speed of the motor. Another example is the use of mechanical gearboxes with different gear ratios. By selecting different gears, the input speed can be converted to various output speeds, allowing for speed control.
- Electronic Control Systems: Some variator motors employ electronic control systems to achieve variable speed control. These control systems typically consist of microprocessors, sensors, and feedback mechanisms. The motor speed is adjusted based on input signals or commands received by the control system. The control system then modulates the power supplied to the motor to achieve the desired speed. This approach is often used in applications where precise speed control and automation are required.
- Hydraulic Control Systems: In hydraulic variator motors, speed control is achieved through hydraulic control systems. These systems use hydraulic pumps, valves, and actuators to adjust the motor speed. By controlling the flow rate and pressure of the hydraulic fluid, the speed of the motor can be modulated. Hydraulic variator motors are commonly used in applications where high torque and ruggedness are required, such as heavy machinery and construction equipment.
Regardless of the specific mechanism used, the principle behind variable speed control in variator motors involves adjusting the input power, transmission, or control system to modify the rotational speed of the motor. This flexibility in controlling the speed allows for precise matching of the motor’s output to the requirements of the application, resulting in improved efficiency, reduced energy consumption, and enhanced performance.
editor by CX 2024-05-16
China OEM Manual Governor Foot Mounting Speed Variator with Good quality
Product Description
JWB-X SERIES SPEED VARIATOR
Characteristics
JWB-X With great reliability developed over 30 years of service, the JWB-X series is a valid alternative to electronic drives and is easy to use and maintain.
The JWB-X type in cast iron includes a wide range of models with flange, feet, with input shaft or in motorized version, are available in size number 04 and 05 ,input power is 1.1kw, 1.5kw,2.2kw,3kw,4kw.
The low-cost, light weight JWB-X B versions in aluminium,are available in size number 01, 02 and 03,04, input power is 0.18kw,0.25kw,0.37kw,0.55kw , 0.75kw,1.1kw and 1.5kw.
All type Certifications Available: ISO,CE,CQC,TUV,CCC certificate.
JWB-X type
- Sizes: 04,05
- Motor Power from 1.1 kW to 4 kW (Incldue 1.1kW,1.5kW,2.2kW,3kW,4kW)
- Cases in RAL 5571 blue cast iron
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190-950r/min; 100-500r/min;80-400r/min;60-300r/min;40-200r/min;
30-150r/min;28-140r/min; 20-100r/min; 15-75r/min;4.7-23.5r/min;2-10r/min;
Output Torque value max 535Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control handwheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
JWB-X B type
- Sizes: 01,02,03 and 04
- Motor Power up to 1.5 kW or less
(Incldue 0.18kW,0.25kW,0.37kW,0.55kW,0.75kW,1.1kW,1.5kW)
- Cases in die-cast aluminium alloy
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190r/min-950r/min; 100r/min-500r/min;80r/min-400r/min;60r/min-300r/min;
40r/min-200r/min;28r/min-140r/min;25-125r/min; 18-90r/min; 15r/min-75r/min;
13-65r/min; 9-45r/min; 8-40r/min; 6.5-32.5r/min;4.7r/min-23.5r/min;2r/min-10r/min.
- Output Torque value max 795 Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control hand wheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
SPEED VARIATOR | Output Speed Range: | ||||
SWB SERIES | 2rpm-950rpm | ||||
Applicable Motor Power: | |||||
0.18kW-7.5kW | |||||
Input Options 1: | |||||
Type | Old Type | Output Torque | Output Shaft Dia. | With Inline AC Motor | |
SWB01 | JWB01 | 2.6-1.6N.m | φ11 | Input Options 2: | |
SWB02 | JWB02 | 258-1.8N.m | φ14, φ24, φ28, φ32 | With IEC Motor | |
SWB03 | JWB03 | 426-4N.m | φ24, φ28, φ28, φ38 | Input Options 3: | |
SWB04 | JWB04 | 795-8N.m | φ28, φ38, φ38, φ42 | With Input Shaft | |
SWB05 | JWB05 | 535-16N.m | φ38, φ48, φ55 | Input Options 4: | |
SWB06 | JWB06 | 1002-40N.m | φ42, φ55, φ70 | With Input Flange |
Starshine Drive
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Our Team
Quality Control
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/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Warranty: | 12 Months |
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Type: | Ceramic, Glass, Logistic |
Certification: | CE, ISO, CQC,SGS,TUV |
Structure: | Horizontal |
Control System: | Manual Adjustment |
Glass Washing Machine Type: | Transmission Parts |
Samples: |
US$ 300/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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Are variator motors suitable for applications requiring precise speed control?
Yes, variator motors are generally suitable for applications requiring precise speed control. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed motors, are designed to provide adjustable speed control over a wide range. They allow the user to vary the motor’s speed according to the specific requirements of the application. This flexibility makes them well-suited for applications that demand precise speed control.
Here are some reasons why variator motors are suitable for applications requiring precise speed control:
- Speed Adjustment Range: Variator motors offer a wide range of adjustable speeds, allowing for precise control over the motor’s rotational speed. Depending on the specific model and type of variator motor, the speed adjustment range can vary from a few RPM (Revolutions Per Minute) to thousands of RPM. This versatility enables the motor to operate at different speeds, accommodating varying process or load requirements.
- Smooth Speed Transitions: Variator motors can provide smooth and gradual speed transitions. They offer precise speed control without sudden jolts or jerks during acceleration or deceleration. This feature is especially important in applications where precise speed control is critical for maintaining product quality, preventing damage to sensitive equipment, or ensuring smooth operation of processes.
- Speed Accuracy and Stability: Variator motors can achieve high speed accuracy and stability. They can maintain the desired speed setting within tight tolerances, minimizing deviations and fluctuations. This level of control is essential in applications that require precise synchronization, coordination with other system components, or adherence to specific speed profiles.
- Control Options: Variator motors often come with various control options, allowing for precise speed adjustments. These options can include manual control through potentiometers or dials, digital control through interface panels or keypads, or even programmable control through communication protocols such as Modbus or Ethernet. The availability of different control options enhances the motor’s suitability for applications requiring precise speed control.
- Response Time: Variator motors can typically achieve fast response times when adjusting the speed. They can quickly respond to speed commands or changes in the control signal, allowing for precise and immediate adjustments. This responsiveness is beneficial in applications where rapid speed changes or dynamic response is required to meet changing operational conditions.
- Closed-Loop Control Capability: Some variator motors are equipped with closed-loop control capabilities. Closed-loop control involves using feedback sensors, such as encoders or tachometers, to continuously monitor the motor’s actual speed and compare it to the desired speed. The control system adjusts the motor’s speed based on this feedback, ensuring precise speed control and compensating for any variations or disturbances.
- Application Versatility: Variator motors are versatile and can be used in a wide range of applications requiring precise speed control. They find applications in industries such as manufacturing, automation, robotics, HVAC (heating, ventilation, and air conditioning), conveyors, pumps, fans, and many others.
However, it’s important to note that the suitability of variator motors for precise speed control may vary depending on factors such as the specific motor model, control system, and the desired level of precision. It’s recommended to consult the motor manufacturer or an expert in motor control to determine the best solution for a particular application.
What resources are available for further learning about the principles and applications of variator motors?
There are several resources available for further learning about the principles and applications of variator motors. Here’s a detailed explanation:
1. Books and Publications: Numerous books and publications cover the principles, design, and applications of variator motors. Some recommended titles include “Variable Speed AC Drives with Inverter Output Filters” by Jaroslaw Guzinski and Haitham Abu-Rub, “Electric Motors and Drives: Fundamentals, Types, and Applications” by Austin Hughes and Bill Drury, and “Variable Frequency Drives: Installation and Troubleshooting” by Glen A. Mazur. These resources provide in-depth knowledge on variator motor technology, control strategies, and practical implementation.
2. Online Courses and Tutorials: Online learning platforms like Udemy, Coursera, and edX offer courses and tutorials on electric motors, motor control, and power electronics. These courses cover variator motor principles, operation, and applications, providing a structured learning experience with video lectures, quizzes, and assignments. Some courses are specifically focused on variable frequency drives (VFDs) and their applications.
3. Technical Documentation and Application Notes: Manufacturers of variator motors and associated equipment often provide technical documentation, application notes, and white papers that delve into the principles and applications of variator motors. These resources can be found on the manufacturers’ websites and offer valuable insights into motor selection, installation, and operation.
4. Professional Journals and Research Papers: Academic and professional journals in the fields of electrical engineering, power electronics, and industrial automation publish research papers and articles on variator motors. IEEE Transactions on Industrial Electronics, IEEE Industry Applications Magazine, and International Journal of Electrical Power & Energy Systems are some examples of publications that cover topics related to variator motors. Access to these resources may require subscriptions or membership in relevant professional organizations.
5. Webinars and Online Presentations: Webinars and online presentations hosted by motor manufacturers, industry associations, or technology companies can provide valuable insights into the principles and applications of variator motors. These events often feature subject matter experts who share their knowledge, discuss case studies, and answer questions from participants. Recordings of past webinars are sometimes made available for on-demand viewing.
6. Industry Forums and Discussion Groups: Online forums and discussion groups focused on electrical engineering, motor control, or industrial automation can be valuable resources for learning about variator motors. Platforms like Electrical Engineering Stack Exchange, Control.com, and LinkedIn groups dedicated to motor control offer opportunities to ask questions, engage in discussions, and learn from the experiences of industry professionals.
7. Manufacturer Training Programs: Some variator motor manufacturers offer training programs and workshops that cover the principles, operation, and applications of their products. These programs may include hands-on exercises, demonstrations, and technical support. Contacting the manufacturers directly or checking their websites can provide information on available training opportunities.
When exploring these resources, it’s important to consider the credibility of the source, relevance to specific applications, and the date of publication to ensure the information aligns with the latest advancements in variator motor technology.
By utilizing these resources, individuals can deepen their understanding of variator motors and enhance their knowledge of the principles and applications associated with this technology.
Are there specific types of variator motors designed for certain tasks or environments?
Yes, there are specific types of variator motors that are designed to suit certain tasks or operate effectively in specific environments. Here are some examples:
- Variable Frequency Drives (VFDs): VFDs are a type of variator motor designed for electric motors. They are widely used in various industrial applications and are particularly suited for tasks that require precise speed control. VFDs allow for adjustable speed by varying the frequency of the electrical power supplied to the motor. They are commonly utilized in applications such as pumps, fans, conveyors, and machine tools.
- Hydraulic Variator Motors: Hydraulic variator motors are designed for applications that require high torque and ruggedness. They are commonly used in heavy machinery, construction equipment, and industrial processes where hydraulic power is readily available. Hydraulic variators control the motor speed by adjusting the flow rate and pressure of the hydraulic fluid, allowing for variable speed operation in demanding environments.
- Variable Transmission Systems: Some variator motors are designed with variable transmission systems, such as mechanical gearboxes. These motors are suitable for applications that require adjustable speed through gear ratio changes. They are commonly used in automotive applications, industrial machinery, and equipment that benefit from mechanical speed control mechanisms.
- Electronically Controlled Variator Motors: Certain variator motors incorporate advanced electronic control systems to achieve variable speed control. These motors are often used in automation and robotics applications, where precise and programmable speed control is essential. The electronic control systems allow for integration with other control systems and enable sophisticated control algorithms to optimize performance.
- Explosion-proof Variator Motors: In hazardous environments where the presence of flammable gases or dust is a concern, explosion-proof variator motors are designed to meet strict safety standards. These motors are constructed with special enclosures, seals, and components that prevent the ignition of hazardous substances. They are commonly used in industries such as oil and gas, chemical processing, and mining.
These are just a few examples of specific types of variator motors designed for particular tasks or environments. It’s important to select the appropriate variator motor that meets the requirements of the specific application, taking into consideration factors such as speed range, load characteristics, environmental conditions, safety considerations, and regulatory compliance.
editor by CX 2024-05-16
China factory Udl Series Stepless Gearbox Speed Variator with Motor and Bevel Gear Speed Reducer Ranrey Worm Speed Reducer Gear vacuum pump connector
Product Description
You can choose the 1 type that you need form these product introction.
If you have any question,please contact me.
HangZhou CHINAMFG Machinery Co.,ltd is a company specialized in research, manufacture and service of speed gearbox. Ever since establishment, we have been persisting in technical innovation, advancing the techonology to our products while maintaining our strict quality controls. It is the reason that our products branding ”Xihu (West Lake) Dis.n” have enjoyed such successful global sales.
At present, our company mainly supplies 5 series products as RV worm gearbox, UDL series speed variator,PC series helical gear unit,G3 helical geared motor and SRC helical gearbox. The products are widely applied in the mechanical equipment field such as food and beverage,cement,package,chemical and dyeing, rubber and plastic, CNC machine tool,etc.
Our products have been processed ISO 9001 Quality System Certification and exported to Italy,Spain,Britain,Poland,Turkey.The USA and other European countries,earn the good reputation with our outstanding quality and service.
Customers first,customers satisfaction, excellent after sale service and incessant innovation are our tenet and motto. We will go all out to provide all the customers with high quality and service. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery, Car |
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Hardness: | Hardened Tooth Surface |
Installation: | Vertical and Horizontal |
Samples: |
US$ 69.9/Piece
1 Piece(Min.Order) | Order Sample |
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Customization: |
Available
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.shipping-cost-tm .tm-status-off{background: none;padding:0;color: #1470cc}
Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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Payment Method: |
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Initial Payment Full Payment |
Currency: | US$ |
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Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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What safety considerations are associated with the installation and operation of variator motors?
When installing and operating variator motors, several safety considerations should be taken into account. Here’s a detailed explanation:
Variator motors, like any other electrical or mechanical equipment, require proper installation, operation, and maintenance to ensure safe and reliable performance. Here are some key safety considerations associated with the installation and operation of variator motors:
- Electrical Safety: Variator motors are powered by electricity, so it’s crucial to follow electrical safety guidelines during installation and operation. This includes ensuring proper grounding of the motor and adhering to local electrical codes and regulations. It’s important to have a qualified electrician handle the electrical connections and ensure that the motor is properly wired and protected from electrical hazards.
- Mechanical Safety: Variator motors often have moving parts and may be connected to mechanical systems. During installation, it’s necessary to ensure that the motor is securely mounted and aligned with the driven equipment. Adequate guarding should be provided to prevent accidental contact with moving parts, such as belts, pulleys, or couplings. Properly sized and rated couplings, belts, and other mechanical components should be used to ensure safe and reliable operation.
- Overload Protection: Variator motors should be protected against overloading. Overloading can cause overheating, reduced motor life, and potential safety hazards. It’s important to select a motor with the appropriate power rating for the application and ensure that it’s not subjected to excessive loads. Additional overload protection devices, such as thermal protectors or overload relays, may be necessary to safeguard the motor and prevent damage or hazards.
- Heat Dissipation: Variator motors can generate heat during operation, especially at higher speeds or under heavy loads. Sufficient ventilation and cooling should be provided to dissipate the heat effectively. Adequate clearance around the motor and proper ventilation in the motor enclosure or installation area can help prevent overheating and ensure safe operation. It’s important to follow the manufacturer’s recommendations regarding cooling and ventilation requirements.
- Environmental Considerations: The installation and operation of variator motors should consider the environmental conditions in which they will be used. For example, if the motor will be exposed to moisture, dust, or corrosive substances, appropriate measures should be taken to protect the motor against these elements. This may include using sealed motor enclosures or installing the motor in a suitable protective housing. Additionally, if the motor will be used in hazardous locations, such as areas with flammable gases or dust, it must comply with the applicable safety standards and requirements.
- Proper Maintenance: Regular maintenance is essential for the safe and reliable operation of variator motors. This includes periodic inspection, cleaning, and lubrication of the motor and its components. It’s important to follow the manufacturer’s maintenance guidelines and schedule to ensure that the motor remains in good working condition. Any signs of wear, damage, or abnormal operating conditions should be addressed promptly to prevent safety risks.
- Training and Awareness: Proper training and awareness of the operators and maintenance personnel are crucial for safe operation and maintenance of variator motors. Operators should be knowledgeable about the motor’s operation, control features, and emergency procedures. Maintenance personnel should be trained to perform maintenance tasks safely and be aware of potential hazards associated with the motor. Regular safety training and refresher courses can help promote a safe working environment.
It’s important to note that the specific safety considerations may vary depending on the motor model, application, and local regulations. Therefore, it’s recommended to consult the manufacturer’s documentation and guidelines, as well as relevant safety standards, to ensure that all necessary safety precautions are followed during the installation and operation of variator motors.
What resources are available for further learning about the principles and applications of variator motors?
There are several resources available for further learning about the principles and applications of variator motors. Here’s a detailed explanation:
1. Books and Publications: Numerous books and publications cover the principles, design, and applications of variator motors. Some recommended titles include “Variable Speed AC Drives with Inverter Output Filters” by Jaroslaw Guzinski and Haitham Abu-Rub, “Electric Motors and Drives: Fundamentals, Types, and Applications” by Austin Hughes and Bill Drury, and “Variable Frequency Drives: Installation and Troubleshooting” by Glen A. Mazur. These resources provide in-depth knowledge on variator motor technology, control strategies, and practical implementation.
2. Online Courses and Tutorials: Online learning platforms like Udemy, Coursera, and edX offer courses and tutorials on electric motors, motor control, and power electronics. These courses cover variator motor principles, operation, and applications, providing a structured learning experience with video lectures, quizzes, and assignments. Some courses are specifically focused on variable frequency drives (VFDs) and their applications.
3. Technical Documentation and Application Notes: Manufacturers of variator motors and associated equipment often provide technical documentation, application notes, and white papers that delve into the principles and applications of variator motors. These resources can be found on the manufacturers’ websites and offer valuable insights into motor selection, installation, and operation.
4. Professional Journals and Research Papers: Academic and professional journals in the fields of electrical engineering, power electronics, and industrial automation publish research papers and articles on variator motors. IEEE Transactions on Industrial Electronics, IEEE Industry Applications Magazine, and International Journal of Electrical Power & Energy Systems are some examples of publications that cover topics related to variator motors. Access to these resources may require subscriptions or membership in relevant professional organizations.
5. Webinars and Online Presentations: Webinars and online presentations hosted by motor manufacturers, industry associations, or technology companies can provide valuable insights into the principles and applications of variator motors. These events often feature subject matter experts who share their knowledge, discuss case studies, and answer questions from participants. Recordings of past webinars are sometimes made available for on-demand viewing.
6. Industry Forums and Discussion Groups: Online forums and discussion groups focused on electrical engineering, motor control, or industrial automation can be valuable resources for learning about variator motors. Platforms like Electrical Engineering Stack Exchange, Control.com, and LinkedIn groups dedicated to motor control offer opportunities to ask questions, engage in discussions, and learn from the experiences of industry professionals.
7. Manufacturer Training Programs: Some variator motor manufacturers offer training programs and workshops that cover the principles, operation, and applications of their products. These programs may include hands-on exercises, demonstrations, and technical support. Contacting the manufacturers directly or checking their websites can provide information on available training opportunities.
When exploring these resources, it’s important to consider the credibility of the source, relevance to specific applications, and the date of publication to ensure the information aligns with the latest advancements in variator motor technology.
By utilizing these resources, individuals can deepen their understanding of variator motors and enhance their knowledge of the principles and applications associated with this technology.
In which industries are variator motors commonly used for different applications?
Variator motors, with their adjustable speed control capabilities, find applications in various industries where precise speed control, energy efficiency, and adaptability to changing operational requirements are essential. Here are some industries where variator motors are commonly used for different applications:
- Industrial Manufacturing: Variator motors are extensively utilized in industrial manufacturing processes. They can be found in machinery and equipment such as conveyors, mixers, extruders, and packaging machines. The ability to adjust the speed of these motors allows for efficient material handling, mixing, blending, and product packaging.
- Material Handling and Logistics: In the material handling and logistics industry, variator motors are commonly employed in conveyor systems. These motors enable precise control of product movement, allowing for smooth and efficient transfer of goods in manufacturing plants, warehouses, airports, and distribution centers.
- Pumping and Water Treatment: Variator motors are utilized in pumping systems for water treatment, wastewater management, and irrigation. The adjustable speed control feature enables the optimization of pumping rates based on demand, resulting in energy savings and improved system efficiency.
- HVAC (Heating, Ventilation, and Air Conditioning): Variator motors play a crucial role in HVAC systems, particularly in fans and blowers. By adjusting the motor speed, these systems can modulate the airflow and temperature control, ensuring optimal comfort and energy efficiency in commercial buildings, residential complexes, and industrial facilities.
- Automotive Industry: Variator motors are used in various applications within the automotive industry. They can be found in vehicle cooling systems, power steering systems, and engine control units. The ability to adjust the motor speed allows for efficient cooling, precise steering assistance, and optimal engine performance.
- Renewable Energy: Variator motors are employed in renewable energy systems such as wind turbines and solar tracking systems. In wind turbines, variator motors enable the adjustment of blade pitch for optimal power generation. In solar tracking systems, they control the movement of solar panels to maximize exposure to sunlight throughout the day.
- Food and Beverage: Variator motors find applications in the food and beverage industry, particularly in mixing, blending, and processing equipment. They enable precise control of speed and agitation, ensuring consistent product quality and efficient production processes.
These are just a few examples of industries where variator motors are commonly used. Their versatility and ability to provide adjustable speed control make them suitable for a wide range of applications across different sectors.
editor by CX 2024-05-15
China OEM Foot Mounted CHINAMFG Shaft Helical-Worm Geared Motor vacuum pump ac
Product Description
Starshine Drive S Series Helical-Worm Geared Motor
Features:
- High efficiency: 75%-80%;
- High technology: the helical gear and a worm gear combined with an integrated transmission to improve the torque and efficiency.
- High precision: the gear is made of high-quality alloy steel forging, carbonitriding and hardening treatment, grinding process to ensure high precision and stable running
- High interchangeability: highly modular, serial design, strong versatility and interchangeability.
Technical parameters
Type | Old Type | Output Torque | Output Shaft Dia. |
SHS37 | S37 | 90N.m | φ20 |
SHS47 | S47 | 170N.m | φ25 |
SHS57 | S57 | 300N.m | φ30 |
SHS67 | S67 | 520N.m | φ35 |
SHS77 | S77 | 1270N.m | φ45 |
SHS87 | S87 | 2280N.m | φ60 |
SHS97 | S97 | 4000N.m | φ70 |
About CHINAMFG Drive
ZheJiang CHINAMFG Drive Co.,Ltd(Starshine) have a strong technical force with over 350 employees at present, including over 30 engineering technicians, 30 quality inspectors, covering an area of 80000 square CHINAMFG and kinds of advanced processing machines and testing equipments. We have a good foundation for the industry application development and service of high-end speed reducers & variators owning to the provincial engineering technology research center,the lab of gear speed reducers, and the base of modern R&D.
Our products are widely used in ceramic industry, glass industry, woodworking machinery , high voltage switch, food & beverage, packaging & printing, Storage & logistics, hoisting & transportation facilities…etc , and CHINAMFG technically provide the professional product & service for the medium and high-end customers, and our gearboxes are best-selling in domestic, and even in abroad , such as in Europe, North America, South America, Middle East, South Asia, Southeast Asia, Africa…etc.
In the future , CHINAMFG will hold the creed of “serving customer, diligence & simplicity, self-criticism, innovation, honesty, teamwork”, and the concept of “quality creates value” to focus on the customers’ requirements and provide them the competitive transmission solution and create value for them constantly, and make a high-end equipment manufacturing industry and create a preferred brand of replacing import products and upgrading continuously for the end users.
Team
Quality Control
Quality:Insist on Improvement,Strive for CHINAMFG With the development of equipment manufacturing indurstry,customer never satirsfy with the current quality of our products,on the contrary,wcreate the value of quality.
Quality policy:to enhance the overall level in the field of power transmission
Quality View:Continuous Improvement , pursuit of CHINAMFG
Quality Philosophy:Quality creates value
3. Incoming Quality Control
To establish the AQL acceptable level of incoming material control, to provide the material for the whole inspection, sampling, immunity. On the acceptance of qualified products to warehousing, substandard goods to take return, check, rework, rework inspection; responsible for tracking bad, to monitor the supplier to take corrective measures to prevent recurrence.
4. Process Quality Control
The manufacturing site of the first examination, inspection and final inspection, sampling according to the requirements of some projects, judging the quality change trend; found abnormal phenomenon of manufacturing, and supervise the production department to improve, eliminate the abnormal phenomenon or state
5. FQC(Final QC)
After the manufacturing department will complete the product, stand in the customer’s position on the finished product quality verification, in order to ensure the quality of customer expectations and needs.
6. OQC(Outgoing QC)
After the product sample inspection to determine the qualified, allowing storage, but when the finished product from the warehouse before the formal delivery of the goods, there is a check, this is called the shipment inspection.Check content:In the warehouse storage and transfer status to confirm, while confirming the delivery of the product is a product inspection to determine the qualified products.
Packing
Delivery
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Machinery |
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Function: | Distribution Power, Change Drive Torque, Change Drive Direction, Speed Changing, Speed Reduction |
Layout: | Helical Worm Gear |
Samples: |
US$ 139.3/Piece
1 Piece(Min.Order) | Order Sample |
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Customization: |
Available
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Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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Payment Method: |
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Initial Payment Full Payment |
Currency: | US$ |
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Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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How does the size and power rating of variator motors impact their performance?
The size and power rating of variator motors have a significant impact on their performance. Here’s a detailed explanation of how these factors influence motor performance:
- Torque Output: The size and power rating of a variator motor directly affect its torque output. Generally, larger and higher-rated motors can deliver higher torque levels, allowing them to handle heavier or more demanding loads. A motor with higher torque capability can provide better acceleration, overcome resistance, and maintain stable operation under varying load conditions.
- Speed Range: The size and power rating of the motor also influence its speed range. Motors with higher power ratings can typically achieve a broader speed range, allowing for more flexibility in matching the motor’s speed to the application’s requirements. Smaller motors may have a more limited speed range, which can impact their suitability for certain applications that require a wide range of speeds.
- Overload Capacity: Larger and higher-rated variator motors generally have a higher overload capacity. They can handle temporary increases in load or momentary peak demands without experiencing significant performance degradation or overheating. This makes them suitable for applications with intermittent or cyclical loads, where occasional high torque requirements may arise.
- Efficiency: The size and power rating of a motor can impact its efficiency. In general, larger motors tend to have higher efficiencies, especially when operating near their rated capacity. Higher efficiency means less energy loss as heat and improved overall energy utilization. It’s important to select a motor with an appropriate power rating to ensure efficient operation while avoiding oversized motors that may operate at low efficiency levels.
- Physical Dimensions: The size of a variator motor directly affects its physical dimensions and weight. Larger motors typically have larger physical footprints and may be heavier. The physical dimensions of the motor can impact its installation requirements, space availability, and integration into the overall system design. It’s important to consider the available space and mounting requirements when selecting a motor of a suitable size.
- Heat Dissipation: The size and power rating of a motor influence its heat dissipation capabilities. Higher-rated motors generally generate more heat during operation, and larger motors have a larger surface area for heat dissipation. Adequate heat dissipation is crucial to prevent overheating and ensure the motor’s long-term reliability. It’s important to consider the motor’s cooling requirements, such as ventilation or cooling mechanisms, to maintain optimal operating temperatures.
- Cost: The size and power rating of a variator motor can impact its cost. Generally, larger and higher-rated motors tend to be more expensive than smaller ones due to the increased materials, manufacturing complexity, and performance capabilities. It’s important to balance the motor’s size, power rating, and associated cost with the specific requirements and budget of the application.
In summary, the size and power rating of variator motors significantly influence their performance in terms of torque output, speed range, overload capacity, efficiency, physical dimensions, heat dissipation, and cost. It’s crucial to carefully consider these factors when selecting a motor to ensure it meets the requirements of the application and delivers optimal performance and reliability.
How do variator motors contribute to energy efficiency in manufacturing processes?
Variator motors play a significant role in improving energy efficiency in manufacturing processes. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed drives, offer the ability to adjust the motor’s speed and torque according to the requirements of the manufacturing process. This flexibility provides several ways in which variator motors contribute to energy efficiency:
- Optimized Process Control: By varying the motor’s speed, variator motors allow manufacturers to precisely match the motor’s output to the process requirements. This optimization eliminates the need for constant full-speed operation, which can result in unnecessary energy consumption. Instead, the motor can run at reduced speeds during periods of lower demand, resulting in energy savings.
- Reduced Mechanical Losses: Traditional motors operating at fixed speeds often use mechanical devices, such as throttling valves or dampers, to control the process flow or pressure. These devices introduce additional mechanical losses that consume energy. With variator motors, the motor speed can be adjusted directly, eliminating the need for such mechanical control devices and reducing energy losses associated with them.
- Efficient Motor Operation: Variator motors are designed to operate efficiently over a broad range of speeds. Unlike fixed-speed motors that may experience reduced efficiency at lower speeds, variator motors can maintain high efficiency even at reduced speeds. This efficiency is achieved through advanced motor designs, improved motor control algorithms, and the use of technologies like permanent magnet motors or synchronous reluctance motors.
- Power Factor Correction: Variator motors can incorporate power factor correction (PFC) techniques to improve the power factor of the motor. Power factor is a measure of how effectively the motor utilizes the supplied electrical power. By improving the power factor, variator motors reduce the reactive power drawn from the power grid, resulting in lower electricity bills and reduced strain on the electrical distribution system.
- Energy Recovery: Some variator motors can feature regenerative capabilities, allowing them to recover and feed excess energy back into the power grid or reuse it within the manufacturing process. For example, in applications where the motor decelerates or operates as a generator, the energy generated can be fed back into the grid or used to power other equipment, further enhancing energy efficiency.
- Process Optimization: Variator motors offer the advantage of precise control over motor speed and torque. This control can be utilized to optimize manufacturing processes, such as matching the motor speed to the optimal speed for material handling, mixing, or other process requirements. By fine-tuning the motor operation, variator motors enable improved process efficiency, reduced material waste, and energy savings.
By leveraging the flexibility and control offered by variator motors, manufacturers can achieve substantial energy savings in their production processes. The specific energy-saving potential will depend on the application, process requirements, and the extent to which the motor’s speed and torque can be optimized. It’s important to consult with motor manufacturers, engineers, and energy experts to assess the suitability and potential energy savings of variator motors in specific manufacturing applications.
Are there specific types of variator motors designed for certain tasks or environments?
Yes, there are specific types of variator motors that are designed to suit certain tasks or operate effectively in specific environments. Here are some examples:
- Variable Frequency Drives (VFDs): VFDs are a type of variator motor designed for electric motors. They are widely used in various industrial applications and are particularly suited for tasks that require precise speed control. VFDs allow for adjustable speed by varying the frequency of the electrical power supplied to the motor. They are commonly utilized in applications such as pumps, fans, conveyors, and machine tools.
- Hydraulic Variator Motors: Hydraulic variator motors are designed for applications that require high torque and ruggedness. They are commonly used in heavy machinery, construction equipment, and industrial processes where hydraulic power is readily available. Hydraulic variators control the motor speed by adjusting the flow rate and pressure of the hydraulic fluid, allowing for variable speed operation in demanding environments.
- Variable Transmission Systems: Some variator motors are designed with variable transmission systems, such as mechanical gearboxes. These motors are suitable for applications that require adjustable speed through gear ratio changes. They are commonly used in automotive applications, industrial machinery, and equipment that benefit from mechanical speed control mechanisms.
- Electronically Controlled Variator Motors: Certain variator motors incorporate advanced electronic control systems to achieve variable speed control. These motors are often used in automation and robotics applications, where precise and programmable speed control is essential. The electronic control systems allow for integration with other control systems and enable sophisticated control algorithms to optimize performance.
- Explosion-proof Variator Motors: In hazardous environments where the presence of flammable gases or dust is a concern, explosion-proof variator motors are designed to meet strict safety standards. These motors are constructed with special enclosures, seals, and components that prevent the ignition of hazardous substances. They are commonly used in industries such as oil and gas, chemical processing, and mining.
These are just a few examples of specific types of variator motors designed for particular tasks or environments. It’s important to select the appropriate variator motor that meets the requirements of the specific application, taking into consideration factors such as speed range, load characteristics, environmental conditions, safety considerations, and regulatory compliance.
editor by CX 2024-05-15
China Professional Udl Series Stepless Speed Variator Geared Reducer Gearbox vacuum pump connector
Product Description
You can choose the 1 type that you need form these product introction.
If you have any question,please contact me.
HangZhou CHINAMFG Machinery Co.,ltd is a company specialized in research, manufacture and service of speed gearbox. Ever since establishment, we have been persisting in technical innovation, advancing the techonology to our products while maintaining our strict quality controls. It is the reason that our products branding ”Xihu (West Lake) Dis.n” have enjoyed such successful global sales.
At present, our company mainly supplies 5 series products as RV worm gearbox, UDL series speed variator,PC series helical gear unit,G3 helical geared motor and SRC helical gearbox. The products are widely applied in the mechanical equipment field such as food and beverage,cement,package,chemical and dyeing, rubber and plastic, CNC machine tool,etc.
Our products have been processed ISO 9001 Quality System Certification and exported to Italy,Spain,Britain,Poland,Turkey.The USA and other European countries,earn the good reputation with our outstanding quality and service.
Customers first,customers satisfaction, excellent after sale service and incessant innovation are our tenet and motto. We will go all out to provide all the customers with high quality and service. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery, Car |
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Hardness: | Hardened Tooth Surface |
Installation: | Vertical and Horizontal |
Samples: |
US$ 78/Piece
1 Piece(Min.Order) | Order Sample |
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Customization: |
Available
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Currency: | US$ |
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Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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How does the size and power rating of variator motors impact their performance?
The size and power rating of variator motors have a significant impact on their performance. Here’s a detailed explanation of how these factors influence motor performance:
- Torque Output: The size and power rating of a variator motor directly affect its torque output. Generally, larger and higher-rated motors can deliver higher torque levels, allowing them to handle heavier or more demanding loads. A motor with higher torque capability can provide better acceleration, overcome resistance, and maintain stable operation under varying load conditions.
- Speed Range: The size and power rating of the motor also influence its speed range. Motors with higher power ratings can typically achieve a broader speed range, allowing for more flexibility in matching the motor’s speed to the application’s requirements. Smaller motors may have a more limited speed range, which can impact their suitability for certain applications that require a wide range of speeds.
- Overload Capacity: Larger and higher-rated variator motors generally have a higher overload capacity. They can handle temporary increases in load or momentary peak demands without experiencing significant performance degradation or overheating. This makes them suitable for applications with intermittent or cyclical loads, where occasional high torque requirements may arise.
- Efficiency: The size and power rating of a motor can impact its efficiency. In general, larger motors tend to have higher efficiencies, especially when operating near their rated capacity. Higher efficiency means less energy loss as heat and improved overall energy utilization. It’s important to select a motor with an appropriate power rating to ensure efficient operation while avoiding oversized motors that may operate at low efficiency levels.
- Physical Dimensions: The size of a variator motor directly affects its physical dimensions and weight. Larger motors typically have larger physical footprints and may be heavier. The physical dimensions of the motor can impact its installation requirements, space availability, and integration into the overall system design. It’s important to consider the available space and mounting requirements when selecting a motor of a suitable size.
- Heat Dissipation: The size and power rating of a motor influence its heat dissipation capabilities. Higher-rated motors generally generate more heat during operation, and larger motors have a larger surface area for heat dissipation. Adequate heat dissipation is crucial to prevent overheating and ensure the motor’s long-term reliability. It’s important to consider the motor’s cooling requirements, such as ventilation or cooling mechanisms, to maintain optimal operating temperatures.
- Cost: The size and power rating of a variator motor can impact its cost. Generally, larger and higher-rated motors tend to be more expensive than smaller ones due to the increased materials, manufacturing complexity, and performance capabilities. It’s important to balance the motor’s size, power rating, and associated cost with the specific requirements and budget of the application.
In summary, the size and power rating of variator motors significantly influence their performance in terms of torque output, speed range, overload capacity, efficiency, physical dimensions, heat dissipation, and cost. It’s crucial to carefully consider these factors when selecting a motor to ensure it meets the requirements of the application and delivers optimal performance and reliability.
How do variator motors contribute to energy efficiency in manufacturing processes?
Variator motors play a significant role in improving energy efficiency in manufacturing processes. Here’s a detailed explanation:
Variator motors, also known as variable speed motors or adjustable speed drives, offer the ability to adjust the motor’s speed and torque according to the requirements of the manufacturing process. This flexibility provides several ways in which variator motors contribute to energy efficiency:
- Optimized Process Control: By varying the motor’s speed, variator motors allow manufacturers to precisely match the motor’s output to the process requirements. This optimization eliminates the need for constant full-speed operation, which can result in unnecessary energy consumption. Instead, the motor can run at reduced speeds during periods of lower demand, resulting in energy savings.
- Reduced Mechanical Losses: Traditional motors operating at fixed speeds often use mechanical devices, such as throttling valves or dampers, to control the process flow or pressure. These devices introduce additional mechanical losses that consume energy. With variator motors, the motor speed can be adjusted directly, eliminating the need for such mechanical control devices and reducing energy losses associated with them.
- Efficient Motor Operation: Variator motors are designed to operate efficiently over a broad range of speeds. Unlike fixed-speed motors that may experience reduced efficiency at lower speeds, variator motors can maintain high efficiency even at reduced speeds. This efficiency is achieved through advanced motor designs, improved motor control algorithms, and the use of technologies like permanent magnet motors or synchronous reluctance motors.
- Power Factor Correction: Variator motors can incorporate power factor correction (PFC) techniques to improve the power factor of the motor. Power factor is a measure of how effectively the motor utilizes the supplied electrical power. By improving the power factor, variator motors reduce the reactive power drawn from the power grid, resulting in lower electricity bills and reduced strain on the electrical distribution system.
- Energy Recovery: Some variator motors can feature regenerative capabilities, allowing them to recover and feed excess energy back into the power grid or reuse it within the manufacturing process. For example, in applications where the motor decelerates or operates as a generator, the energy generated can be fed back into the grid or used to power other equipment, further enhancing energy efficiency.
- Process Optimization: Variator motors offer the advantage of precise control over motor speed and torque. This control can be utilized to optimize manufacturing processes, such as matching the motor speed to the optimal speed for material handling, mixing, or other process requirements. By fine-tuning the motor operation, variator motors enable improved process efficiency, reduced material waste, and energy savings.
By leveraging the flexibility and control offered by variator motors, manufacturers can achieve substantial energy savings in their production processes. The specific energy-saving potential will depend on the application, process requirements, and the extent to which the motor’s speed and torque can be optimized. It’s important to consult with motor manufacturers, engineers, and energy experts to assess the suitability and potential energy savings of variator motors in specific manufacturing applications.
What is a variator motor, and how does it differ from traditional motors?
A variator motor, also known as a variable speed motor, is a type of motor that allows for adjustable speed control. Unlike traditional motors that operate at a fixed speed, variator motors provide the ability to vary the rotational speed to meet specific application requirements. Here are some key points differentiating variator motors from traditional motors:
- Speed Control: The primary difference between variator motors and traditional motors is the ability to control the speed. Traditional motors typically operate at a fixed speed determined by the motor’s design and the frequency of the power supply. In contrast, variator motors feature mechanisms that allow for adjustable speed control, enabling users to increase or decrease the rotational speed as needed.
- Operating Principle: Variator motors achieve variable speed control through various mechanisms. One common approach is the use of adjustable transmission systems, such as variable frequency drives (VFDs) or mechanical gearboxes. These systems allow for changes in the motor’s output speed by adjusting the input power frequency or gear ratio. Other variator motors may employ electronic or hydraulic control systems to modulate the motor’s speed based on input signals or user commands.
- Application Flexibility: The ability to adjust the speed makes variator motors highly versatile and suitable for a wide range of applications. They can be employed in situations where precise speed control, energy efficiency, or the ability to adapt to changing operational requirements is critical. Variator motors find applications in industrial machinery, conveyors, pumps, fans, and other systems where speed modulation is beneficial.
- Energy Efficiency: Variator motors often exhibit higher energy efficiency compared to traditional motors, especially when operating at reduced speeds. By adjusting the motor’s speed to match the required output, variator motors can minimize energy wastage associated with running at fixed speeds. This energy-saving capability can lead to reduced operating costs and improved overall system efficiency.
- Cost and Complexity: Variator motors, due to their speed control capabilities, can be more complex and costly compared to traditional motors. The additional components required for speed modulation, such as variable frequency drives or control systems, can increase the overall system complexity and initial investment. However, the benefits of adjustable speed control and energy efficiency often outweigh the higher upfront costs in many applications.
In summary, a variator motor allows for adjustable speed control, enabling users to change the rotational speed to meet specific application requirements. With their ability to modulate speed, variator motors offer greater flexibility, energy efficiency, and application versatility compared to traditional motors.
editor by CX 2024-05-15
China Hot selling Mechanical Variators with Flange Mounted vacuum pump ac
Product Description
JWB-X SERIES SPEED VARIATOR
Characteristics
JWB-X With great reliability developed over 30 years of service, the JWB-X series is a valid alternative to electronic drives and is easy to use and maintain.
The JWB-X type in cast iron includes a wide range of models with flange, feet, with input shaft or in motorized version, are available in size number 04 and 05 ,input power is 1.1kw, 1.5kw,2.2kw,3kw,4kw.
The low-cost, light weight JWB-X B versions in aluminium,are available in size number 01, 02 and 03,04, input power is 0.18kw,0.25kw,0.37kw,0.55kw , 0.75kw,1.1kw and 1.5kw.
All type Certifications Available: ISO,CE,CQC,TUV,CCC certificate.
JWB-X type
- Sizes: 04,05
- Motor Power from 1.1 kW to 4 kW (Incldue 1.1kW,1.5kW,2.2kW,3kW,4kW)
- Cases in RAL 5571 blue cast iron
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190-950r/min; 100-500r/min;80-400r/min;60-300r/min;40-200r/min;
30-150r/min;28-140r/min; 20-100r/min; 15-75r/min;4.7-23.5r/min;2-10r/min;
Output Torque value max 535Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control handwheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
JWB-X B type
- Sizes: 01,02,03 and 04
- Motor Power up to 1.5 kW or less
(Incldue 0.18kW,0.25kW,0.37kW,0.55kW,0.75kW,1.1kW,1.5kW)
- Cases in die-cast aluminium alloy
- Shafts: case hardened and tempered steel.
- Internal components: heat-treated steel
- Output speed with 4 pole(1400r/min) motors:
190r/min-950r/min; 100r/min-500r/min;80r/min-400r/min;60r/min-300r/min;
40r/min-200r/min;28r/min-140r/min;25-125r/min; 18-90r/min; 15r/min-75r/min;
13-65r/min; 9-45r/min; 8-40r/min; 6.5-32.5r/min;4.7r/min-23.5r/min;2r/min-10r/min.
- Output Torque value max 795 Nm
- Silent, vibration-free running
- Bidirectional rotation
- Control hand wheel positionable on either side
- Slipping speed to max load at 5%
- Painted with blue epoxy-polyester powder
SPEED VARIATOR | Output Speed Range: | ||||
SWB SERIES | 2rpm-950rpm | ||||
Applicable Motor Power: | |||||
0.18kW-7.5kW | |||||
Input Options 1: | |||||
Type | Old Type | Output Torque | Output Shaft Dia. | With Inline AC Motor | |
SWB01 | JWB01 | 2.6-1.6N.m | φ11 | Input Options 2: | |
SWB02 | JWB02 | 258-1.8N.m | φ14, φ24, φ28, φ32 | With IEC Motor | |
SWB03 | JWB03 | 426-4N.m | φ24, φ28, φ28, φ38 | Input Options 3: | |
SWB04 | JWB04 | 795-8N.m | φ28, φ38, φ38, φ42 | With Input Shaft | |
SWB05 | JWB05 | 535-16N.m | φ38, φ48, φ55 | Input Options 4: | |
SWB06 | JWB06 | 1002-40N.m | φ42, φ55, φ70 | With Input Flange |
Starshine Drive
Certificate
Our Team
Quality Control
Packing
Delivery
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Type: | Ceramic, Glass, Logistic |
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Certification: | CE, ISO, CQC,SGS,TUV |
Structure: | Horizontal |
Control System: | Manual Adjustment |
Glass Washing Machine Type: | Transmission Parts |
Glass Edging Machine Type: | Transmission Parts |
Samples: |
US$ 300/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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What safety considerations are associated with the installation and operation of variator motors?
When installing and operating variator motors, several safety considerations should be taken into account. Here’s a detailed explanation:
Variator motors, like any other electrical or mechanical equipment, require proper installation, operation, and maintenance to ensure safe and reliable performance. Here are some key safety considerations associated with the installation and operation of variator motors:
- Electrical Safety: Variator motors are powered by electricity, so it’s crucial to follow electrical safety guidelines during installation and operation. This includes ensuring proper grounding of the motor and adhering to local electrical codes and regulations. It’s important to have a qualified electrician handle the electrical connections and ensure that the motor is properly wired and protected from electrical hazards.
- Mechanical Safety: Variator motors often have moving parts and may be connected to mechanical systems. During installation, it’s necessary to ensure that the motor is securely mounted and aligned with the driven equipment. Adequate guarding should be provided to prevent accidental contact with moving parts, such as belts, pulleys, or couplings. Properly sized and rated couplings, belts, and other mechanical components should be used to ensure safe and reliable operation.
- Overload Protection: Variator motors should be protected against overloading. Overloading can cause overheating, reduced motor life, and potential safety hazards. It’s important to select a motor with the appropriate power rating for the application and ensure that it’s not subjected to excessive loads. Additional overload protection devices, such as thermal protectors or overload relays, may be necessary to safeguard the motor and prevent damage or hazards.
- Heat Dissipation: Variator motors can generate heat during operation, especially at higher speeds or under heavy loads. Sufficient ventilation and cooling should be provided to dissipate the heat effectively. Adequate clearance around the motor and proper ventilation in the motor enclosure or installation area can help prevent overheating and ensure safe operation. It’s important to follow the manufacturer’s recommendations regarding cooling and ventilation requirements.
- Environmental Considerations: The installation and operation of variator motors should consider the environmental conditions in which they will be used. For example, if the motor will be exposed to moisture, dust, or corrosive substances, appropriate measures should be taken to protect the motor against these elements. This may include using sealed motor enclosures or installing the motor in a suitable protective housing. Additionally, if the motor will be used in hazardous locations, such as areas with flammable gases or dust, it must comply with the applicable safety standards and requirements.
- Proper Maintenance: Regular maintenance is essential for the safe and reliable operation of variator motors. This includes periodic inspection, cleaning, and lubrication of the motor and its components. It’s important to follow the manufacturer’s maintenance guidelines and schedule to ensure that the motor remains in good working condition. Any signs of wear, damage, or abnormal operating conditions should be addressed promptly to prevent safety risks.
- Training and Awareness: Proper training and awareness of the operators and maintenance personnel are crucial for safe operation and maintenance of variator motors. Operators should be knowledgeable about the motor’s operation, control features, and emergency procedures. Maintenance personnel should be trained to perform maintenance tasks safely and be aware of potential hazards associated with the motor. Regular safety training and refresher courses can help promote a safe working environment.
It’s important to note that the specific safety considerations may vary depending on the motor model, application, and local regulations. Therefore, it’s recommended to consult the manufacturer’s documentation and guidelines, as well as relevant safety standards, to ensure that all necessary safety precautions are followed during the installation and operation of variator motors.
Are there cost considerations when choosing variator motors for industrial use?
Yes, there are several cost considerations that come into play when choosing variator motors for industrial use. Here’s a detailed explanation:
When selecting variator motors for industrial applications, it’s important to evaluate not only the initial purchase cost but also the overall cost of ownership throughout the motor’s lifespan. Here are some key cost considerations to keep in mind:
- Motor Cost: The initial purchase cost of the variator motor is an important consideration. The cost can vary depending on factors such as motor power rating, brand, quality, and additional features. It’s essential to compare prices from different suppliers and manufacturers to ensure a competitive and reasonable cost for the motor.
- Efficiency: The energy efficiency of the variator motor can have a significant impact on long-term operating costs. More efficient motors consume less energy, resulting in reduced electricity bills. It’s advisable to choose high-efficiency motors that meet or exceed the minimum efficiency standards set by regulatory bodies, such as the International Electrotechnical Commission (IEC) or the National Electrical Manufacturers Association (NEMA). Although high-efficiency motors may have a higher initial cost, the energy savings over the motor’s lifespan can offset the additional investment.
- Maintenance and Service: Consider the maintenance requirements and associated costs of variator motors. Motors that require regular maintenance, such as lubrication, bearing replacements, or brush inspections, may have higher maintenance costs compared to maintenance-free or sealed motor designs. It’s important to factor in the anticipated maintenance needs and costs when evaluating the overall cost of ownership.
- Durability and Reliability: Variator motors that are built to withstand harsh operating conditions and have a long service life can offer cost advantages in the long run. Although more durable and reliable motors may have a higher upfront cost, they can minimize the need for premature motor replacements, reduce downtime, and lower maintenance and repair expenses. It’s crucial to assess the motor’s quality, reputation, and warranty provisions to gauge its expected durability and reliability.
- Control and Automation: Variator motors often come with various control options and compatibility with automation systems. While these features can enhance operational efficiency and control, they may have associated costs. Consider the cost of control devices, such as variable frequency drives (VFDs), sensors, and monitoring equipment. Additionally, if integrating the motor into an existing automation system, ensure compatibility and account for any necessary upgrades or modifications.
- Application-Specific Requirements: Some industrial applications may have specific motor requirements that can impact costs. For example, if the motor needs to operate in extreme temperatures, hazardous environments, or corrosive atmospheres, special motor designs or materials may be necessary, which can increase costs. It’s important to evaluate any application-specific requirements and associated costs when selecting variator motors.
- Future Expandability: Consider the scalability and expandability of the motor system. If there are possibilities of future capacity expansions or modifications to the industrial process, choosing a motor that can accommodate such changes can prevent the need for a costly motor replacement in the future.
By carefully considering these cost factors, industrial users can make informed decisions when selecting variator motors that strike a balance between upfront costs and long-term operational expenses. It’s advisable to consult with motor suppliers, engineers, and industry experts to assess the specific cost considerations relevant to the industrial application and ensure the optimal motor choice.
How does the efficiency of variator motors compare to other types of motors?
The efficiency of variator motors can vary depending on the specific design, application, and operating conditions. However, in general, variator motors can offer comparable or even higher efficiency compared to other types of motors. Here are some key points to consider:
- Variable Speed Operation: Variator motors excel in variable speed operations where the motor speed can be adjusted to match the load and process requirements. By running the motor at a speed that precisely meets the demand, variator motors can significantly reduce energy losses associated with running at fixed speeds. This level of control contributes to high overall system efficiency.
- Energy Savings through Speed Control: The ability to adjust the motor speed in variator motors allows for energy savings. By operating the motor at lower speeds when full speed is not required, variator motors can achieve energy efficiency gains. This is particularly relevant in applications with varying loads or processes that do not constantly require maximum speed.
- Improved Power Factor: Variator motors with adjustable speed control, such as those incorporating variable frequency drives (VFDs), can improve the power factor of the motor system. Power factor is a measure of how effectively electrical power is being used. By optimizing the motor speed and voltage, VFDs can improve the power factor, resulting in reduced reactive power consumption and improved energy efficiency.
- Motor Design and Technology: The efficiency of variator motors can also be influenced by the motor design and the use of advanced technologies. Manufacturers are continually improving motor designs, incorporating high-quality materials, precision manufacturing techniques, and efficient cooling systems to enhance motor efficiency. Additionally, advancements in motor technologies, such as the use of permanent magnet materials and improved motor control algorithms, contribute to higher overall efficiency.
- Comparison with Other Motor Types: When compared to traditional fixed-speed motors, variator motors generally offer higher efficiency due to their ability to adjust speed according to the load. In applications where variable speed control is required, variator motors can outperform fixed-speed motors in terms of energy savings, precise control, and overall system efficiency.
It’s important to note that the efficiency of variator motors can also depend on factors such as motor size, load characteristics, maintenance practices, and system design. Therefore, it’s advisable to consider specific motor specifications, consult with manufacturers, and conduct energy efficiency assessments to determine the most suitable motor type for a given application.
editor by CX 2024-05-15