Descripción del Producto
Who we are?
HangZhou XIHU (WEST LAKE) DIS. CARDANSHAFT CO;LTD has 15 years history.When the general manager Mr.Rony Du graduated from the university,he always concentrated his attention on the research and development,production and sales of the cardan shaft.Mr.Rony Du and his team started from scratch,from 1 lathe and a very small order,step by step to grow up.He often said to his team”We will only do 1 thing well——to make the perfect cardan shaft”.
General manager Mr.Rony Du
HangZhou XIHU (WEST LAKE) DIS. CARDANSHAFT CO.,LTD was founded in 2005.The registered capital is 8 million ,covers an area of 15 acres, has 30 existing staff. The company specializing in the production of SWC, SWP cross universal coupling and drum tooth coupling.The company with factory is located in the beautiful coast of Tai Lake –Hudai (HangZhou Economic Development Zone Hudai Industrial Park).
In order to become China’s leading cardan shaft one-stop solution expert supplier .XIHU (WEST LAKE) DIS. CARDANSHAFT independent research and development of SWC light, medium, short, heavy Designs cardan shaft have reached the leading domestic level.Products not only supporting domestic large and medium-sized customers, but also exported to the United States, India, Vietnam, Laos, Ukraine, Russia, Germany, Britain and other countries and areas.In the past 15 years, the company has accumulated a wealth of experience, learn from foreign advanced technology, and to absorb and use the universal axis has been improved several times, so that the structure is maturing, significantly improved performance.
XIHU (WEST LAKE) DIS. Office Building
XIHU (WEST LAKE) DIS. belief: “Continuous innovation, optimize the structure, perseverance” to create a high quality of outstanding cardan shaft manufacturer.We always adhere to the ISO9001 quality control system, from the details to start, standardize the production process, and to achieve processing equipment “specialization, numerical control” rapid increase in product quality.This Not only won the majority of customers reputation, but also access to peer recognition. We continue to strive to pursue: “for customers to create the greatest value, for the staff to build the best platform”, will be able to achieve customer and business mutually beneficial CHINAMFG situation.
Welcome to XIHU (WEST LAKE) DIS. CARDANSHAFT
Why choose us?
First,select raw material carefully
The cross is the core component of cardan shaft,so the selection of material is particularly critical.Raw materials of the cross for light Duty Size and Medium Duty Size,we choose the 20CrMnTi special gear steel bar from SHAGANG GROUP.Being forged in 2500 ton friction press to ensure internal metallurgical structure,inspecting the geometric dimensions of each part to meet the drawing requirements,then transfer to machining,the processes of milling, turning, quenching and grinding.
The inspector will screen blank yoke head.The porosity, cracks, slag, etc. do not meet the requirements of the casting foundry are all eliminated,then doing physical and chemical analysis, to see whether the ingredients meet the requirements, unqualified re-elimination.And then transferred to the quenching and tempering heat treatment, once again check the hardness to see if meet the requirements, qualified to be transferred to the machining process. We control from the source of the material to ensure the supply of raw materials qualified rate of 99%.
Second,advanced production equipment
XIHU (WEST LAKE) DIS. Company introduced four-axis linkage machining center made in ZheJiang , milling the keyway and flange bolt hole of the flange yoke, The once machine-shaping ensures that the symmetry of the keyway and the position of the bolt hole are less than 0.02mm,which greatly improves the installation accuracy of the flange,the 4 axis milling and drilling center holes of the cross are integrated,to ensure that the 4 shaft symmetry and verticality are less than 0.02mm,the process of the journal cross assembly service life can be increased by 30%, and the speed at 1000 rpm above the cardan shaft running smoothly and super life is crucial to the operation.
We use CNC machine to lathe flange yoke and welded yoke,CNC machine can not only ensure the accuracy of the flange connection with the mouth, but also improve the flange surface finish.
5 CHINAMFG automatic welding machine welding spline sleeve and tube,welded yoke and tube.With the welding CHINAMFG swing mechanism, automatic lifting mechanism, adjustment mechanism and welding CHINAMFG cooling system, welding machine can realize multi ring continuous welding, each coil current and voltage can be preset, arc starting and stopping control PLC procedures, reliable welding quality, the weld bead is smooth and beautiful, to control the welding process with fixed procedures, greatly reducing the uncertainty of human during welding, greatly improve the welding effect.
High speed cardan shaft needs to do dynamic balance test before leaving the factory.Unbalanced cardan shaft will produce excessive centrifugal force at high speed and reduce the service life of the bearing;the dynamic balance test can eliminate the uneven distribution of the casting weight and the mass distribution of the whole assembly;Through the experiment to achieve the design of the required balance quality, improve the universal shaft service life.In 2008 the company introduced 2 high-precision dynamic balance test bench, the maximum speed can reach 4000 rev / min, the balance of G0.8 accuracy, balance weight 2kg–1000kg.
In order to make the paint standardization, in 2009 the company bought 10 CHINAMFG of clean paint room , the surface treatment of cardan shaft is more standardized, paint fastness is more rugged, staff’s working conditions improved, exhaust of harmless treatment.
Third,Professional transport packaging
The packing of the export cardan shaft is all in the same way as the plywood wooden box, and then it is firmly secured with the iron sheet, so as to avoid the damage caused by the complicated situation in the long-distance transportation. Meet the standard requirements of plywood boxes into Europe and other countries, no matter where can successfully reach all the country’s ports.
The following table for SWC Medium-sized Universal Shaft Parameters.
Designs
Data and Sizes of SWC Series Universal Joint Couplings
| Tipo | Design Data Artículo |
SWC160 | SWC180 | SWC200 | SWC225 | SWC250 | SWC265 | SWC285 | SWC315 | SWC350 | SWC390 | SWC440 | SWC490 | SWC550 | SWC620 |
| A | L | 740 | 800 | 900 | 1000 | 1060 | 1120 | 1270 | 1390 | 1520 | 1530 | 1690 | 1850 | 2060 | 2280 |
| LV | 100 | 100 | 120 | 140 | 140 | 140 | 140 | 140 | 150 | 170 | 190 | 190 | 240 | 250 | |
| M(kg) | 65 | 83 | 115 | 152 | 219 | 260 | 311 | 432 | 610 | 804 | 1122 | 1468 | 2154 | 2830 | |
| B | L | 480 | 530 | 590 | 640 | 730 | 790 | 840 | 930 | 100 | 1571 | 1130 | 1340 | 1400 | 1520 |
| M(kg) | 44 | 60 | 85 | 110 | 160 | 180 | 226 | 320 | 440 | 590 | 820 | 1090 | 1560 | 2100 | |
| C | L | 380 | 420 | 480 | 500 | 560 | 600 | 640 | 720 | 782 | 860 | 1040 | 1080 | 1220 | 1360 |
| M(kg) | 35 | 48 | 66 | 90 | 130 | 160 | 189 | 270 | 355 | 510 | 780 | 970 | 1330 | 1865 | |
| D | L | 520 | 580 | 620 | 690 | 760 | 810 | 860 | 970 | 1030 | 1120 | 1230 | 1360 | 1550 | 1720 |
| M(kg) | 48 | 65 | 90 | 120 | 173 | 220 | 250 | 355 | 485 | 665 | 920 | 1240 | 1765 | 2390 | |
| E | L | 800 | 850 | 940 | 1050 | 1120 | 1180 | 1320 | 1440 | 1550 | 1710 | 1880 | 2050 | 2310 | 2540 |
| LV | 100 | 100 | 120 | 140 | 140 | 140 | 140 | 140 | 150 | 170 | 190 | 190 | 240 | 250 | |
| M(kg) | 70 | 92 | 126 | 165 | 238 | 280 | 340 | 472 | 660 | 886 | 1230 | 1625 | 2368 | 3135 | |
| Tn(kN·m) | 16 | 22.4 | 31.5 | 40 | 63 | 80 | 90 | 125 | 180 | 250 | 355 | 500 | 710 | 1000 | |
| TF(kN·m) | 8 | 11.2 | 16 | 20 | 31.5 | 40 | 45 | 63 | 90 | 125 | 180 | 250 | 355 | 500 | |
| Β(°) | 15 | 15 | 15 | 15 | 15 | 15 | 15 | 15 | 15 | 15 | 15 | 15 | 15 | 15 | |
| D | 160 | 180 | 200 | 225 | 250 | 265 | 285 | 315 | 350 | 390 | 440 | 490 | 550 | 620 | |
| Df | 160 | 180 | 200 | 225 | 250 | 265 | 285 | 315 | 350 | 3690 | 440 | 490 | 550 | 620 | |
| D1 | 137 | 155 | 170 | 196 | 218 | 233 | 245 | 280 | 310 | 345 | 390 | 435 | 492 | 555 | |
| D2(H9) | 100 | 105 | 120 | 135 | 150 | 160 | 170 | 185 | 210 | 235 | 255 | 275 | 320 | 380 | |
| D3 | 108 | 114 | 140 | 159 | 168 | 180 | 194 | 219 | 245 | 273 | 299 | 325 | 402 | 426 | |
| Lm | 95 | 105 | 110 | 125 | 140 | 150 | 160 | 180 | 195 | 215 | 260 | 270 | 305 | 340 | |
| K | 16 | 17 | 18 | 20 | 25 | 25 | 27 | 32 | 35 | 40 | 42 | 47 | 50 | 55 | |
| T | 4 | 5 | 5 | 5 | 6 | 6 | 7 | 8 | 8 | 8 | 10 | 12 | 12 | 12 | |
| N | 8 | 8 | 8 | 8 | 8 | 8 | 8 | 10 | 10 | 10 | 16 | 16 | 16 | 16 | |
| D | 15 | 17 | 17 | 17 | 19 | 19 | 21 | 23 | 23 | 25 | 28 | 31 | 31 | 38 | |
| B | 20 | 24 | 32 | 32 | 40 | 40 | 40 | 40 | 50 | 70 | 80 | 90 | 100 | 100 | |
| G | 6.0 | 7.0 | 9.0 | 9.0 | 12.5 | 12.5 | 12.5 | 15.0 | 16.0 | 18.0 | 20.0 | 22.5 | 22.5 | 25 | |
| MI(Kg) | 2.57 | 3 | 3.85 | 3.85 | 5.17 | 6 | 6.75 | 8.25 | 10.6 | 13 | 18.50 | 23.75 | 29.12 | 38.08 | |
| Size | M14 | M16 | M16 | M16 | M18 | M18 | M20 | M22 | M22 | M24 | M27 | M30 | M30 | M36 | |
| Tightening torque(Nm) | 180 | 270 | 270 | 270 | 372 | 372 | 526 | 710 | 710 | 906 | 1340 | 1820 | 1820 | 3170 |
1. Notations:
L=Standard length, or compressed length for designs with length compensation;
LV=Length compensation;
M=Weight;
Tn=Nominal torque(Yield torque 50% over Tn);
TF=Fatigue torque, I. E. Permissible torque as determined according to the fatigue strength
Under reversing loads;
β =Maximum deflection angle;
MI=weight per 100mm tube
2. Millimeters are used as measurement units except where noted;
3. Please consult us for customizations regarding length, length compensation and
Flange connections.
(DIN or SAT etc. )
Brief Introduction
Processing flow
Applications
Control de calidad
/* 10 de marzo de 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“”,).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
| Material: | Acero aleado |
|---|---|
| Carga: | Eje de transmisión |
| Rigidez y flexibilidad: | Rigidez / Eje rígido |
| Precisión dimensional del diámetro del muñón: | IT6-IT9 |
| Forma del eje: | Eje recto |
| Forma del eje: | Hollow Axis |
| Personalización: |
Disponible
| Solicitud personalizada |
|---|
Can PTO shafts be adapted for use in both agricultural and industrial settings?
Yes, PTO (Power Take-Off) shafts can be adapted for use in both agricultural and industrial settings. While PTO shafts are commonly associated with agricultural machinery, they are versatile components that can be utilized in various applications beyond the agricultural sector. With appropriate modifications and considerations, PTO shafts can effectively transfer power in industrial settings as well. Here’s a detailed explanation of how PTO shafts can be adapted for both agricultural and industrial use:
1. Standard PTO Shaft Design: PTO shafts have a standardized design that allows for compatibility and interchangeability across different equipment and machinery. This standardization enables PTO shafts to be used in various applications, including both agricultural and industrial settings. The basic components of a PTO shaft, such as the universal joints, splined shafts, and protective guards, remain consistent, regardless of the specific application. This consistency allows for easy adaptation and integration into different machinery and equipment.
2. Shaft Length and Sizing: PTO shafts can be customized in terms of length and sizing to suit specific requirements in both agricultural and industrial settings. The length of the shaft can be adjusted to accommodate different distances between the power source and the driven machinery. This flexibility allows for optimal power transmission and ensures compatibility with various equipment setups. Similarly, the sizing of the PTO shaft, including the diameter and splined shaft specifications, can be tailored to meet the torque and power requirements of different applications, whether in agriculture or industry.
3. Power Requirements: PTO shafts are designed to transfer power from a power source to driven machinery. In agricultural settings, the power source is typically a tractor or other agricultural vehicles, while in industrial settings, it can be an engine, motor, or power unit specific to the industry. PTO shafts can be adapted to handle different power requirements by considering factors such as torque capacity, rotational speed, and the specific demands of the machinery or equipment being driven. By selecting the appropriate PTO shaft based on the power requirements, the shaft can effectively transfer power in both agricultural and industrial applications.
4. Consideraciones de seguridad: Safety is a critical aspect of PTO shaft design and usage, regardless of the application. PTO shafts incorporate safety features such as protective guards and shields to prevent accidental contact with rotating components. These safety measures are essential in agricultural and industrial settings to minimize the risk of entanglement, injury, or damage. Adapting PTO shafts for industrial use may require additional safety considerations based on the specific hazards present in industrial environments. However, the core safety principles and features of PTO shafts can be applied and adapted to ensure safe operation in both settings.
5. Specialized Attachments: PTO shafts can be equipped with specialized attachments or adapters to accommodate different driven machinery or equipment. In agricultural settings, PTO shafts commonly connect to implements such as mowers, balers, or sprayers. In industrial settings, PTO shafts may be adapted to connect to various industrial machinery, including pumps, generators, compressors, or conveyors. These specialized attachments ensure compatibility and efficient power transfer between the PTO shaft and the driven equipment, allowing for seamless integration in both agricultural and industrial applications.
6. Environmental Considerations: PTO shafts can be adapted to address specific environmental conditions in both agricultural and industrial settings. For example, in agricultural applications, PTO shafts may need to withstand exposure to dirt, dust, moisture, and varying weather conditions. Industrial settings may have their unique environmental challenges, such as exposure to chemicals, high temperatures, or abrasive materials. By selecting PTO shaft materials, protective coatings, and seals suitable for the specific environment, the shafts can be adapted to ensure reliable and durable performance in various settings.
7. Compliance with Standards: PTO shafts, whether used in agricultural or industrial settings, need to comply with relevant safety standards and regulations. Manufacturers adhere to guidelines and requirements set by organizations such as the American Society of Agricultural and Biological Engineers (ASABE) or other regional safety authorities. Compliance ensures that PTO shafts meet safety criteria and performance standards applicable to both agricultural and industrial environments. Users can rely on standardized PTO shafts that have undergone testing and certification, offering assurance regarding their reliability and safety.
By considering the factors mentioned above, PTO shafts can be adapted to effectively transfer power in both agricultural and industrial settings. The versatile nature of PTO shafts, coupled with customization options, safety considerations, specialized attachments, and compliance with standards, allows for their successful integration into a wide range of machinery and equipment across various industries.
¿Existen limitaciones o desventajas asociadas a los ejes de toma de fuerza?
Si bien los ejes de toma de fuerza (TDF) ofrecen numerosas ventajas en cuanto a la transmisión de potencia y versatilidad, también presentan ciertas limitaciones y desventajas. Es importante tener en cuenta estos factores al utilizar ejes de TDF para garantizar un funcionamiento seguro y eficiente. A continuación, se ofrece una explicación detallada de algunas de las limitaciones y desventajas asociadas a los ejes de TDF:
1. Riesgos para la seguridad: Una de las principales preocupaciones con los ejes de toma de fuerza (TDF) es el riesgo potencial para la seguridad. Estos ejes giran a altas velocidades y pueden representar un riesgo significativo si no están debidamente protegidos o manipulados. El contacto accidental con un eje de TDF expuesto o con una protección insuficiente puede provocar lesiones graves, como atrapamiento, amputación o incluso la muerte. Es fundamental seguir las normas de seguridad, implementar la protección adecuada y garantizar que los operarios estén bien capacitados en prácticas de manipulación seguras para mitigar estos riesgos.
2. Mantenimiento y lubricación: Los ejes de la toma de fuerza (PTO) requieren mantenimiento y lubricación regulares para garantizar un rendimiento óptimo y una mayor durabilidad. Las piezas móviles, como las juntas universales y las estrías, deben inspeccionarse, limpiarse y lubricarse a intervalos recomendados. Descuidar el mantenimiento puede provocar un desgaste prematuro, una menor eficiencia y posibles fallos. Unas prácticas de mantenimiento adecuadas, que incluyan inspecciones periódicas y una lubricación oportuna, son esenciales para evitar estos problemas.
3. Alineación y ángulos: Los ejes de la toma de fuerza (TDF) dependen de una alineación y ángulos adecuados para garantizar una transferencia de potencia eficiente. Una desalineación o ángulos excesivos entre la fuente de energía y la maquinaria accionada pueden provocar un mayor desgaste y tensión en los componentes, lo que conlleva una falla prematura. Asegurar una alineación y un ajuste de ángulo correctos, mediante horquillas deslizantes ajustables u otros medios, es fundamental para evitar una tensión excesiva en el eje de la TDF y el equipo asociado.
4. Limitaciones de longitud: Los ejes de la toma de fuerza (TDF) tienen limitaciones en su longitud máxima y mínima debido a restricciones de ingeniería. El diseño telescópico permite cierto ajuste, pero existe un límite práctico en cuanto a cuánto puede extenderse o retraerse el eje. Si la distancia entre la fuente de energía y la maquinaria accionada supera la longitud máxima o es inferior a la mínima del eje de la TDF, podrían ser necesarias soluciones alternativas o modificaciones. En algunos casos, podrían requerirse componentes adicionales, como extensiones del eje de transmisión o cajas de engranajes, para salvar la distancia.
5. Compatibilidad: Si bien los fabricantes se esfuerzan por garantizar la compatibilidad, aún pueden surgir dificultades para encontrar el eje de toma de fuerza (TDF) adecuado para configuraciones de equipo específicas. Los equipos pueden tener requisitos únicos en cuanto a tamaños de estrías, valores de torque o métodos de conexión que podrían no estar disponibles o ser incompatibles con los ejes de TDF estándar. Para solucionar estos problemas de compatibilidad, podría ser necesario realizar modificaciones, lo que podría incrementar los costos o los plazos de entrega.
6. Ruido y vibraciones: Los ejes de toma de fuerza (TDF) en funcionamiento pueden generar ruido y vibraciones significativas, especialmente a altas velocidades. Esto puede resultar molesto para los operarios y requerir medidas adicionales para reducir el ruido o amortiguar las vibraciones. Las vibraciones excesivas también pueden afectar el rendimiento y la vida útil del eje de TDF y los equipos conectados. La instalación de amortiguadores de vibración o el uso de acoplamientos flexibles pueden ayudar a mitigar estos problemas.
7. Límites de potencia: Los ejes de toma de fuerza (TDF) tienen límites de potencia específicos según su diseño, materiales y componentes. Superar estos límites puede provocar desgaste prematuro, fallos en los componentes o incluso la rotura del eje. Es fundamental comprender y respetar las potencias recomendadas para los ejes de TDF a fin de garantizar un funcionamiento seguro y fiable. En algunos casos, puede ser necesario instalar un eje de TDF de mayor capacidad o incorporar componentes de transmisión de potencia adicionales para satisfacer mayores requerimientos de potencia.
8. Instalación y desmontaje complejos: La instalación y extracción de ejes de toma de fuerza (TDF) puede ser un proceso complejo, especialmente en espacios reducidos o al trabajar con maquinaria pesada. Puede requerir la alineación de estrías, el acoplamiento de piezas y el bloqueo de mecanismos. Las técnicas de instalación o extracción incorrectas pueden dañar el eje o el equipo asociado. Una capacitación adecuada, el manejo correcto del equipo y el cumplimiento de las instrucciones del fabricante son esenciales para simplificar y garantizar la instalación y extracción seguras de los ejes de TDF.
A pesar de estas limitaciones y desventajas, los ejes de toma de fuerza (TDF) siguen siendo componentes valiosos y ampliamente utilizados para la transmisión de potencia en diversas industrias. Al abordar estas consideraciones e implementar medidas de seguridad, prácticas de mantenimiento y procedimientos de alineación adecuados, se pueden mitigar eficazmente los posibles inconvenientes de los ejes de TDF, lo que permite un funcionamiento seguro y eficiente.
How do PTO shafts contribute to transferring power from tractors to implements?
PTO shafts (Power Take-Off shafts) play a critical role in transferring power from tractors to implements in agricultural and industrial settings. They provide a reliable and efficient means of power transmission, enabling tractors to drive various implements and perform a wide range of tasks. Here’s a detailed explanation of how PTO shafts contribute to transferring power from tractors to implements:
Fuente de energía: Tractors are equipped with powerful engines designed to generate substantial amounts of mechanical power. This power is harnessed to drive the tractor’s wheels and operate hydraulic systems, as well as to provide power for the attachment of implements through the PTO shaft. The PTO shaft typically connects to the rear or side of the tractor, where the power take-off mechanism is located. The power take-off derives power directly from the tractor’s engine or transmission, allowing for efficient power transfer to the PTO shaft.
PTO Shaft Design: PTO shafts are designed as driveline components that transmit rotational power and torque from the tractor’s power take-off to the implement. They consist of a hollow metal tube with universal joints at each end. The universal joints accommodate angular misalignments and allow the PTO shaft to transmit power even when the tractor and implement are not perfectly aligned. The PTO shaft is also equipped with a safety shield or guard to prevent accidental contact with the rotating shaft, ensuring operator safety during operation.
PTO Engagement: To transfer power from the tractor to the implement, the PTO shaft needs to be engaged. Tractors are equipped with a PTO clutch mechanism that allows operators to engage or disengage the PTO shaft as needed. When the PTO clutch is engaged, power flows from the tractor’s engine through the power take-off mechanism and into the PTO shaft. This rotational power is then transmitted through the PTO shaft to the implement, driving its working components.
Rotational Power Transmission: The rotational power generated by the tractor’s engine is transferred to the PTO shaft through the power take-off mechanism. The PTO shaft, being directly connected to the power take-off, rotates at the same speed as the engine. This rotational power is then transmitted from the PTO shaft to the implement’s driveline or gearbox. The implement’s driveline, in turn, distributes the power to the implement’s working components, such as blades, augers, or pumps, enabling them to carry out their respective functions.
Matching Speed and Power: PTO shafts are designed to match the rotational speed and power requirements of various implements. Tractors often feature multiple speed settings for the PTO, allowing operators to select the appropriate speed for the specific implement being used. Different implements may require different rotational speeds to operate optimally, and the PTO shaft allows for easy adjustment to match those requirements. Additionally, the power generated by the tractor’s engine is transmitted through the PTO shaft, providing the necessary torque to drive the implement’s working components effectively.
Versatility and Efficiency: PTO shafts offer significant versatility and efficiency in agricultural and industrial operations. They allow tractors to power a wide range of implements, including mowers, balers, tillers, sprayers, and grain augers, among others. By connecting implements directly to the tractor’s power source, operators can quickly switch between tasks without the need for separate power generators or engines. This versatility and efficiency streamline workflow, reduce costs, and increase overall productivity in agricultural and industrial settings.
Safety Considerations: While PTO shafts are essential for power transmission, they can pose safety risks if mishandled. The rotating shaft and universal joints can cause severe injuries if operators come into contact with them while in operation. That’s why PTO shafts are equipped with safety shields or guards to prevent accidental contact. Operators should always ensure that the safety shields are in place and secure before engaging the PTO shaft. Proper training, adherence to safety guidelines, and regular maintenance of PTO shafts and associated safety features are crucial to ensuring safe operation.
In summary, PTO shafts are vital components that enable the transfer of power from tractors to implements in agricultural and industrial applications. They provide a reliable and efficient means of power transmission, allowing tractors to drive various implements and perform a wide range of tasks. By engaging the PTO clutch and transmitting rotational power through the PTO shaft, tractors power the working components of implements, providing versatility, efficiency, and productivity in agricultural and industrial operations.
editor by CX 2024-02-13
