Product Description
Product Description
Place of Origin: | ZheJiang , China (Mainland) | Brand Name: | Kubota excavator coupling | Model Number: | JURID couplings |
Application 1: | Mini Excavators | Application 2: | Compact Loaders | Application 3: | Forlifts |
Application 4: | Construction machines using a hydraulic drive system | Coupling model A: | BoWex MONOLASTIC size 28 | Coupling model B: | BoWex MONOLASTIC size 32 |
Coupling model C: | BoWex MONOLASTIC size 50-140 | Coupling model D: | BoWex MONOLASTIC size 50-170 | Material: | Original material-GF-PA6 |
Availability: | In stock |
Packaging & Delivery
Packaging Details: | JURID couplings 1. spare parts, with carton package as usual for mini order 2. Main pump, wooden box 3. if need wooden pallets, the customer needs to pay for the wooden pallet charges |
Delivery Detail: | 1-7 working days after payment |
1. Material options for H series Couplings
H series coupling we produced is made of Hytrel. It has elasticity like that of rubber. It is excellent in absorbing vibrations and shocks. It also excels in resistance to heat, low temperature and oil.
Input and output can be connected and disconnected easily merely by moving axially. By using a unique claming mechanism, mounting in a spline shaft is possible. Hub and spline shafts are completely fixed by using a clamping hub of the mechanism. No fretting wear is caused.
2. Technical Data
COUPLING “H” SERIES TECHNICAL DATA | |||||||||
SIZE | 30H | 40H | 50H | 110H | 140H | 160H | |||
TECHNICAL DATA | |||||||||
DESCRIPTION | SYMBOL | UNIT | 500 | 600 | 800 | 1200 | 1600 | 2000 | |
Nominal Torque | Tkn | Nm | |||||||
Maximum Torque | Tkmax | Nm | 1400 | 1600 | 2000 | 2500 | 4000 | 4000 | |
Maximum Rotational speed | Nmax | Min-1 | 4000 | 4000 | 4000 | 4000 | 3600 | 3600 | |
COUPLING “A” SERIES TECHNICAL DATA | |||||||||
SIZE | 4A/4AS | 8A/8AS | 16A/16AS | 25A/25AS | 30A/30AS | 50A/50AS | 140A/140AS | ||
TECHNICAL DATA | |||||||||
DESCRIPTION | SYMBOL | UNIT | 50 | 100 | 200 | 315 | 500 | 700 | 1700 |
Nominal Torque | Tkn | Nm | |||||||
Maximum Torque | Tkmax | Nm | 125 | 280 | 560 | 875 | 1400 | 2100 | 8750 |
Maximum Rotational speed | Nmax | Min-1 | 7000 | 6500 | 6000 | 5000 | 4000 | 4000 | 3600 |
FAQ
Why chose us
A. 30 yease experience in the line of the market, produce high quality excavator spare parts
High quality at competitive price.
B. Factory manufacturer, factory price
C. One-stop shopping. We have Trading company based on our factory, supply with various spare parts for your need, with high quality at company price, one-stop shopping, save your time to searching the parts you need urgent.
D. Timely delivery
E. Various of transportation way: Sea, Air, Bus, Express, etc
F. Parts available in stock
Note:
A. In order to give you fast and accurate pricing information, we need some details about your engine/application and the part number of the part you want.
B. If you can not find the parts you want, please contact us
HangZhou Xiebang Machinery Co., Ltd
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Durometer Hardness in Rubber Coupling Materials
Durometer hardness is a measure of the material’s resistance to indentation or penetration by a specified indenter. In rubber couplings, durometer hardness is a critical characteristic that influences their performance. It is typically measured using a durometer instrument.
The durometer hardness scale commonly used for rubber materials is the Shore durometer scale, indicated by a letter followed by a numerical value (e.g., Shore A, Shore D). Lower durometer values indicate softer and more flexible rubber, while higher values indicate harder and less flexible rubber.
In relation to rubber couplings:
- Higher Durometer (Harder Rubber): Couplings made from harder rubber materials have better torque transmission capabilities and higher load-bearing capacity. However, they may offer less vibration isolation and misalignment compensation.
- Lower Durometer (Softer Rubber): Couplings made from softer rubber materials provide greater flexibility, vibration damping, and misalignment compensation. They are suitable for applications where vibration reduction is crucial.
The choice of durometer hardness depends on the specific requirements of the application, including torque levels, vibration, misalignment, and desired performance characteristics.
Signs of Wear or Deterioration in Rubber Couplings
Rubber couplings can show signs of wear and deterioration over time due to factors like torque, temperature, and environmental conditions. To identify potential issues, watch out for the following signs:
- Visible Cracks or Damage: Inspect the rubber element for visible cracks, tears, or physical damage. Such issues can weaken the coupling’s torque transmission and vibration damping capabilities.
- Reduced Flexibility: Stiff or less flexible rubber indicates material degradation, which can impact the coupling’s ability to accommodate misalignment and absorb vibrations.
- Increased Vibrations: Excessive machinery vibrations may suggest worn-out rubber couplings. Deterioration of the rubber diminishes its vibration dampening properties.
- Unusual Noises: Any unusual sounds like squeaking or knocking might point to improper rubber coupling function and the need for inspection.
- Altered Performance: Decline in machinery performance, such as reduced torque transmission or higher energy consumption, can indicate coupling wear.
Regular inspections, visual checks, vibration analysis, and performance monitoring can help detect wear and deterioration early. This enables timely replacement and avoids operational problems.
Factors to Consider When Selecting a Rubber Coupling
Choosing the right rubber coupling for a specific application involves considering various factors:
1. Torque Requirements: Evaluate the torque that needs to be transmitted between the input and output shafts. Select a coupling with a rubber element that can handle the required torque without exceeding its limits.
2. Misalignment Compensation: Determine the degree of misalignment (angular, axial, and radial) present in the system. Choose a rubber coupling with appropriate flexibility to accommodate the expected misalignment while maintaining efficient torque transmission.
3. Vibration Damping: Assess the level of vibrations and shocks in the application. Opt for a rubber coupling with effective vibration-damping properties to protect the machinery and enhance its reliability.
4. Service Environment: Consider the operating conditions, including temperature, humidity, exposure to chemicals, and potential contaminants. Select a rubber material that can withstand the environment without deteriorating.
5. Shaft Sizes: Ensure that the coupling’s bore sizes match the shaft diameters of the connected equipment. Proper shaft fitment is crucial for efficient torque transmission.
6. Maintenance Requirements: Evaluate the maintenance practices of the system. Some rubber couplings may require periodic inspection and replacement due to wear over time.
7. Cost and Budget: Factor in the budget constraints while choosing a suitable rubber coupling. Balancing performance and cost is essential for an optimal solution.
8. Application Type: Different industries and applications have unique requirements. Choose a coupling type (spider, jaw, tire, etc.) based on the specific needs of the application.
By carefully considering these factors, you can select a rubber coupling that provides efficient torque transmission, vibration isolation, and durability in your mechanical system.
editor by CX 2024-03-05