Productbeschrijving
CNC Machining Advanced Resonable Price Drive Shaft Made by SS 304
| Materials | Carbon steel: 10#, 18#, 1018, 22#, 1571, 40Cr, 45#, 1045, 50#, 55#, 60#, 65Mn, 70#, 72B, 80#, 82B Alloy Structure Steel: B7, 20CrMo, 42Crmo, SCM415, SCM440, 4140 High-carbon chromium bearing steel: GCr15, 52100, SUJ2 Free-cutting steel: 12L14, 12L15 Stainless steel: 1Cr13, 2Cr13, 3Cr13, 4Cr13, 1Cr17, SUS410, SUS420, SUS430, SUS416, SUS440C, 17-4, 17-4PH, 130M, 200, 201, 202, 205, 303, 303Cu, 304, 316, 316L Aluminum grade: 6061, 6063 Brass: Hpb58-2.5 (C38000), Hpb59-1 (C37710), Hpb61-1 (C37100), Hpb62-0.8 (C35000), Hpb63-0.1 (C34900), Hpb63-3 (C34500), H60, H62, H63, H65 |
| Diameter | Ø0.3-Ø25 |
| Diameter tolerance | 0.002mm |
| Roundness | 0.0005mm |
| Roughness | Ra0.05 |
| Straightness | 0.005mm |
| Hardness: | HRC/HV |
| Length | 2mm-1000mm |
| Heat treatment | 1. Oil Quenching 2. High frequency quenching 3. Carburization 4. Vacuum Heat treatment 5. Mesh belt CZPT heat treatment |
| Surface treatment | 1. Plating nickel 2. Plating zinc 3. Plating passivation 4. Plating phosphating 5. Black coating 6. Anodized treatment |
| Pakket | Plastic bags inside and standard cartons outside. Shipment by pallets or according to customer’s packing specifications. |
| Warranty Policy | We confirm our qualities satisfy to 99.9%, and have 6-month quality warranty |
| After Sales Service | We will follow up the requst strictly for customers and will help customers solve problems after sale. |
Swiss High-Precision CNC Machining Process
Other Category From Cold Forging Process
Bedrijfsprofiel
HangZhou CZPT is an integrated manufacturing and trading enterprise with over 30 years of experience. We specialize in providing customized solutions for non-standard fasteners, CNC machined parts, stamping parts, and other metal products. With a sprawling facility covering an area of 5,500 square meters, we have 3 workshops including cold heading, stamping, and cnc machining.
At Hanyee Metal, we take pride in our commitment to delivering high-quality products and tailor-made solutions to meet our customers’ specific needs. Our team of skilled professionals ensures precision and CZPT in every aspect of the manufacturing process. Whether it’s fasteners for unique applications, intricately machined parts, or precision-stamped components, we have the capabilities to exceed your expectations.
Hanyee’s products exporting to more than 30 countries, especially in North American and European markets. Being the supplier for famous brands like : ITW, Ruen, Infenion, WMG,Fnox, ects. many years.
inspection
Exhibiting
Customer reception
Packaging and transportation
Customer feedback
Veelgestelde vragen
Q: Please send your price list for our reference.
A: We do not have standard price list because we produce according to customer design.
We can provide the quotation for your inquiries in a shortest possible time.
Q:Please quote the price for me
A: Our standard response time is 2 working hours, once you confirm the demand and drawing we shall provide the quote within 12 working hours.
Q:Can I get some sample?
A: Sure. We believe sample order is a good way to start our cooperation.
If it is a standard product, it would be for free but freight on your account.
If customized, we shall prepare the sample after receipt of development cost.
Q: Have FASTENERS 100% assembled well in stock?
A: Some of standard size is in stock. Most is OEM item out of stock.
Q: Could I use my own LOGO or design on goods?
A: Yes, Customized logo and design on mass production are available.
Q: What is the delivery time?
A: Our lead time for samples is 1 week; 15-30 days for mass production. It is usually according to the quantity and items.
Q:What payment do you accept?
A: We accept T/T, West Union,L/C,Trade Assurance in Alibaba.
Q: Can I trust you?
A: Absolutely! We are “Made In China” & “Alibaba” verified supplier.
Q: May I visit your factory?
A: You are welcome to visit us anytime. We can also pick you up from nearest airport and Train station.
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| Material: | Carbon Steel |
|---|---|
| Load: | Aandrijfas |
| Stiffness & Flexibility: | Flexible Shaft |
| Journal Diameter Dimensional Accuracy: | 0.005 |
| Axis Shape: | Straight Shaft |
| Shaft Shape: | Stepped Shaft |
| Samples: |
US$ 10/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Beschikbaar
| Customized Request |
|---|
Hoe zorgen aandrijfassen voor een efficiënte krachtoverdracht met behoud van balans?
Aandrijfassen maken gebruik van verschillende mechanismen om een efficiënte krachtoverdracht te garanderen en tegelijkertijd de balans te behouden. Efficiënte krachtoverdracht verwijst naar het vermogen van de aandrijfas om rotatiekracht van de bron (zoals een motor) over te brengen naar de aangedreven componenten (zoals wielen of machines) met minimaal energieverlies. Balanceren daarentegen houdt in dat trillingen worden geminimaliseerd en dat een ongelijkmatige massaverdeling die verstoringen tijdens de werking kan veroorzaken, wordt geëlimineerd. Hieronder volgt een uitleg over hoe aandrijfassen zowel een efficiënte krachtoverdracht als een goede balans bereiken:
1. Materiaalselectie:
De materiaalkeuze voor aandrijfassen is cruciaal voor het behoud van balans en een efficiënte krachtoverdracht. Aandrijfassen worden doorgaans gemaakt van materialen zoals staal of aluminiumlegeringen, die gekozen worden vanwege hun sterkte, stijfheid en duurzaamheid. Deze materialen hebben een uitstekende vormvastheid en zijn bestand tegen de koppelkrachten die tijdens gebruik optreden. Door hoogwaardige materialen te gebruiken, kunnen aandrijfassen vervorming, buiging en onevenwichtigheden minimaliseren die de krachtoverdracht kunnen belemmeren en trillingen kunnen veroorzaken.
2. Ontwerpoverwegingen:
Het ontwerp van de aandrijfas speelt een belangrijke rol in zowel de efficiëntie van de krachtoverbrenging als de balans. Aandrijfassen worden ontworpen met de juiste afmetingen, waaronder diameter en wanddikte, om de verwachte koppelbelastingen te kunnen verwerken zonder overmatige doorbuiging of trillingen. Bij het ontwerp wordt ook rekening gehouden met factoren zoals de lengte van de aandrijfas, het aantal en type koppelingen (zoals kruiskoppelingen of homokinetische koppelingen) en het gebruik van balanceergewichten. Door de aandrijfas zorgvuldig te ontwerpen, kunnen fabrikanten een optimale efficiëntie van de krachtoverbrenging bereiken en tegelijkertijd de kans op trillingen als gevolg van onbalans minimaliseren.
3. Evenwichtstechnieken:
Balancering is cruciaal voor aandrijfassen, omdat elke onbalans trillingen, lawaai en versnelde slijtage kan veroorzaken. Om de balans te behouden, ondergaan aandrijfassen tijdens het fabricageproces verschillende balanceertechnieken. Statische en dynamische balanceermethoden worden gebruikt om ervoor te zorgen dat de massaverdeling langs de aandrijfas uniform is. Bij statische balancering worden contragewichten op specifieke plaatsen toegevoegd om eventuele gewichtsonbalansen te compenseren. Dynamische balancering wordt uitgevoerd door de aandrijfas met hoge snelheid te laten draaien en eventuele trillingen te meten. Als er onbalansen worden gedetecteerd, worden extra aanpassingen gedaan om een gebalanceerde toestand te bereiken. Deze balanceertechnieken helpen trillingen te minimaliseren en zorgen voor een soepele werking van de aandrijfas.
4. Kruiskoppelingen en homokinetische koppelingen:
Aandrijfassen bevatten vaak kruiskoppelingen (U-koppelingen) of homokinetische koppelingen (CV-koppelingen) om uitlijningsfouten op te vangen en de balans tijdens gebruik te behouden. Kruiskoppelingen zijn flexibele koppelingen die hoekbewegingen tussen assen mogelijk maken. Ze worden doorgaans gebruikt in toepassingen waarbij de aandrijfas onder wisselende hoeken draait. Homokinetische koppelingen daarentegen zijn ontworpen om een constante rotatiesnelheid te handhaven en worden veel gebruikt in voertuigen met voorwielaandrijving. Door deze koppelingen toe te passen, kunnen aandrijfassen uitlijningsfouten compenseren, de belasting op de as verminderen en trillingen minimaliseren die een negatieve invloed kunnen hebben op de efficiëntie van de krachtoverbrenging en de balans.
5. Onderhoud en inspectie:
Regelmatig onderhoud en inspectie van aandrijfassen zijn essentieel voor een efficiënte krachtoverbrenging en balans. Periodieke controles op slijtage, schade of verkeerde uitlijning kunnen helpen bij het opsporen van problemen die de prestaties van de aandrijfas kunnen beïnvloeden. Smering van de gewrichten en het correct aanhalen van bevestigingsmiddelen zijn eveneens cruciaal voor een optimale werking. Door de aanbevolen onderhoudsprocedures te volgen, kunnen eventuele onevenwichtigheden of inefficiënties snel worden verholpen, waardoor een continue efficiënte krachtoverbrenging en balans worden gewaarborgd.
Samenvattend zorgen aandrijfassen voor een efficiënte krachtoverdracht met behoud van balans door zorgvuldige materiaalkeuze, doordachte ontwerpoverwegingen, balanceertechnieken en de toepassing van flexibele verbindingen. Door deze factoren te optimaliseren, kunnen aandrijfassen rotatiekracht soepel en betrouwbaar overbrengen, waardoor energieverlies en trillingen die de prestaties en levensduur kunnen beïnvloeden, tot een minimum worden beperkt.
How do drive shafts handle variations in load and vibration during operation?
Drive shafts are designed to handle variations in load and vibration during operation by employing various mechanisms and features. These mechanisms help ensure smooth power transmission, minimize vibrations, and maintain the structural integrity of the drive shaft. Here’s a detailed explanation of how drive shafts handle load and vibration variations:
1. Material Selection and Design:
Drive shafts are typically made from materials with high strength and stiffness, such as steel alloys or composite materials. The material selection and design take into account the anticipated loads and operating conditions of the application. By using appropriate materials and optimizing the design, drive shafts can withstand the expected variations in load without experiencing excessive deflection or deformation.
2. Torque Capacity:
Drive shafts are designed with a specific torque capacity that corresponds to the expected loads. The torque capacity takes into account factors such as the power output of the driving source and the torque requirements of the driven components. By selecting a drive shaft with sufficient torque capacity, variations in load can be accommodated without exceeding the drive shaft’s limits and risking failure or damage.
3. Dynamic Balancing:
During the manufacturing process, drive shafts can undergo dynamic balancing. Imbalances in the drive shaft can result in vibrations during operation. Through the balancing process, weights are strategically added or removed to ensure that the drive shaft spins evenly and minimizes vibrations. Dynamic balancing helps to mitigate the effects of load variations and reduces the potential for excessive vibrations in the drive shaft.
4. Dampers and Vibration Control:
Drive shafts can incorporate dampers or vibration control mechanisms to further minimize vibrations. These devices are typically designed to absorb or dissipate vibrations that may arise from load variations or other factors. Dampers can be in the form of torsional dampers, rubber isolators, or other vibration-absorbing elements strategically placed along the drive shaft. By managing and attenuating vibrations, drive shafts ensure smooth operation and enhance overall system performance.
5. CV Joints:
Constant Velocity (CV) joints are often used in drive shafts to accommodate variations in operating angles and to maintain a constant speed. CV joints allow the drive shaft to transmit power even when the driving and driven components are at different angles. By accommodating variations in operating angles, CV joints help minimize the impact of load variations and reduce potential vibrations that may arise from changes in the driveline geometry.
6. Lubrication and Maintenance:
Proper lubrication and regular maintenance are essential for drive shafts to handle load and vibration variations effectively. Lubrication helps reduce friction between moving parts, minimizing wear and heat generation. Regular maintenance, including inspection and lubrication of joints, ensures that the drive shaft remains in optimal condition, reducing the risk of failure or performance degradation due to load variations.
7. Structural Rigidity:
Drive shafts are designed to have sufficient structural rigidity to resist bending and torsional forces. This rigidity helps maintain the integrity of the drive shaft when subjected to load variations. By minimizing deflection and maintaining structural integrity, the drive shaft can effectively transmit power and handle variations in load without compromising performance or introducing excessive vibrations.
8. Control Systems and Feedback:
In some applications, drive shafts may be equipped with control systems that actively monitor and adjust parameters such as torque, speed, and vibration. These control systems use sensors and feedback mechanisms to detect variations in load or vibrations and make real-time adjustments to optimize performance. By actively managing load variations and vibrations, drive shafts can adapt to changing operating conditions and maintain smooth operation.
In summary, drive shafts handle variations in load and vibration during operation through careful material selection and design, torque capacity considerations, dynamic balancing, integration of dampers and vibration control mechanisms, utilization of CV joints, proper lubrication and maintenance, structural rigidity, and, in some cases, control systems and feedback mechanisms. By incorporating these features and mechanisms, drive shafts ensure reliable and efficient power transmission while minimizing the impact of load variations and vibrations on overall system performance.
How do drive shafts handle variations in length and torque requirements?
Drive shafts are designed to handle variations in length and torque requirements in order to efficiently transmit rotational power. Here’s an explanation of how drive shafts address these variations:
Length Variations:
Drive shafts are available in different lengths to accommodate varying distances between the engine or power source and the driven components. They can be custom-made or purchased in standardized lengths, depending on the specific application. In situations where the distance between the engine and the driven components is longer, multiple drive shafts with appropriate couplings or universal joints can be used to bridge the gap. These additional drive shafts effectively extend the overall length of the power transmission system.
Additionally, some drive shafts are designed with telescopic sections. These sections can be extended or retracted, allowing for adjustments in length to accommodate different vehicle configurations or dynamic movements. Telescopic drive shafts are commonly used in applications where the distance between the engine and the driven components may change, such as in certain types of trucks, buses, and off-road vehicles.
Torque Requirements:
Drive shafts are engineered to handle varying torque requirements based on the power output of the engine or power source and the demands of the driven components. The torque transmitted through the drive shaft depends on factors such as the engine power, load conditions, and the resistance encountered by the driven components.
Manufacturers consider torque requirements when selecting the appropriate materials and dimensions for drive shafts. Drive shafts are typically made from high-strength materials, such as steel or aluminum alloys, to withstand the torque loads without deformation or failure. The diameter, wall thickness, and design of the drive shaft are carefully calculated to ensure it can handle the expected torque without excessive deflection or vibration.
In applications with high torque demands, such as heavy-duty trucks, industrial machinery, or performance vehicles, drive shafts may have additional reinforcements. These reinforcements can include thicker walls, cross-sectional shapes optimized for strength, or composite materials with superior torque-handling capabilities.
Furthermore, drive shafts often incorporate flexible joints, such as universal joints or constant velocity (CV) joints. These joints allow for angular misalignment and compensate for variations in the operating angles between the engine, transmission, and driven components. They also help absorb vibrations and shocks, reducing stress on the drive shaft and enhancing its torque-handling capacity.
In summary, drive shafts handle variations in length and torque requirements through customizable lengths, telescopic sections, appropriate materials and dimensions, and the inclusion of flexible joints. By carefully considering these factors, drive shafts can efficiently and reliably transmit power while accommodating the specific needs of different applications.
editor by CX 2024-03-11
