Product Description
GSJ 32×29 Aluminum alloy single diaphragm set screw coupling
Dimensions of GSJ 32×29 Aluminum alloy single diaphragm set screw coupling
| model parameter | common bore diameter d1,d2 | ΦD | L | LF | S | F | M | tightening screw torque (N.M) |
| GSJ-19×20 | 3,4,5,6.6.35,7,8,9,9.525.10 | Φ19 | 20 | 9.1 | 1.8 | 4.25 | M3 | 0.7 |
| GSJ-26×24 | 4,5,6,6.35,7,8,9,9.525,10,11,12 | Φ26 | 24 | 10.7 | 2.6 | 4.5 | M4 | 1.7 |
| GSJ-32×29 | 6,6.35,7,8,9,9.525,10,11,12,12.7,14,15,16 | Φ32 | 29 | 12.75 | 3.5 | 6.12 | M4 | 1.7 |
| GSJ-39×34.5 | 6,6.35,7,8,9,9.525,10.11.12,12.7,14.15,16,17,18 | Φ39 | 34.5 | 15 | 4.5 | 6.62 | M5 | 4 |
| GSJ-44×41 | 8,9,9.525,10,11,12,12.7,14,15,16,17,18,19,20,22 | Φ44 | 41 | 18.25 | 4.5 | 8.12 | M6 | 8.4 |
| GSJ-56×45 | 8,10,12,12.7,14,15,16,17,18,19,20,22,24,25,28,30,32 | Φ56 | 45 | 19.75 | 5.5 | 6.4 | M8 | 8.4 |
| GSJ-68×53 | 12,14,15,16,17,18,19,20.22,24,25,28,30,32,35,38 | Φ68 | 53 | 23.35 | 6.3 | 7.7 | M8 | 10.5 |
| Anodizing treatment | Rated torque (N.M)* |
allowable eccentricity (mm)* |
allowable deflection angle (°)* |
allowable axial deviation (mm)* |
maximum speed rpm |
static torsional stiffness (N.M/rad) |
moment of inertia (Kg.M2) |
Material of shaft sleeve | Material of shrapnel | surface treatment | weight (g) |
| GSJ-19×20 | 1 | 0.1 | 1° | ±0.09 | 10000 | 220 | 6.5×10-1 | High strength aluminum alloy | S U S 3 0 4 Spring steel | Anodizing treatment | 10 |
| GSJ-26×24 | 1.5 | 0.1 | 1° | ±0.14 | 10000 | 1125 | 1.8×10-6 | 23 | |||
| GSJ-32×29 | 2 | 0.1 | 1° | ±0.18 | 10000 | 2100 | 5.2×10-5 | 50 | |||
| GSJ-39×34.5 | 6 | 0.1 | 1° | ±0.23 | 10000 | 3900 | 2.0×10-6 | 80 | |||
| GSJ-44×41 | 9 | 0.1 | 1° | ±0.27 | 10000 | 4500 | 3.2×10-6 | 155 | |||
| GSJ-56×45 | 25 | 0.1 | 1° | ±0.36 | 10000 | 12900 | 1.2×10-4 | 217 | |||
| GSJ-68×53 | 60 | 0.1 | 1° | ±0.4 | 8000 | 25800 | 1.5×10-4 | 348 |
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Industries and Use Cases for Diaphragm Couplings
Diaphragm couplings find applications in various industries due to their flexibility, precision, and ability to handle misalignment. Here are some common industries that commonly use diaphragm couplings and their specific use cases:
- Industrial Machinery:
- Power transmission in pumps and compressors
- Motion control systems in robotics and automation
- Drive systems for conveyors and material handling equipment
- Motion control applications in packaging and printing machinery
- Oil and Gas:
- Gas compressors and turbine drives
- Extraction pumps and mud pumps
- Rotating equipment on offshore platforms
- Power transmission in drilling rigs
- Steel and Metal Processing:
- Rolling mills and metal forming equipment
- Continuous casting machines
- High-temperature furnace drives
- Steel shears and cutters
- Aerospace and Defense:
- Aircraft engine power transmission
- Missile and satellite systems
- Airborne radar and avionics equipment
- Military vehicle drivetrains
- Marine:
- Marine propulsion systems
- Shipboard pumps and compressors
- Power transmission in marine generators
- Steering systems for marine vessels
- Chemical and Process Industries:
- Chemical processing pumps and compressors
- Agitators and mixers
- Reaction vessels and reactors
- Chemical plant material handling systems
In the industrial machinery sector, diaphragm couplings are utilized for:
In the oil and gas industry, diaphragm couplings are commonly used in:
Diaphragm couplings play a vital role in the steel and metal processing industry, where they are used in:
In the aerospace and defense sector, diaphragm couplings are utilized in:
In the marine industry, diaphragm couplings are commonly found in:
In the chemical and process industries, diaphragm couplings are used in:
These examples represent just a few of the many industries where diaphragm couplings are utilized. Their ability to handle misalignment, dampen vibrations, and transmit torque reliably makes them an integral part of various mechanical systems in different sectors.
Potential Causes of Failure in Diaphragm Couplings and Prevention Methods
While diaphragm couplings are designed for reliability and durability, certain factors can contribute to their failure over time. Understanding the potential causes of failure and implementing preventive measures can help maximize the lifespan and performance of diaphragm couplings. Here are some common causes of failure and the corresponding prevention methods:
- 1. Misalignment:
- 2. Overloading:
- 3. Corrosion and Contamination:
- 4. Fatigue:
- 5. Improper Installation:
- 6. Excessive Vibrations:
- 7. Lack of Maintenance:
Misalignment between the shafts connected by the diaphragm coupling can lead to increased stresses on the diaphragm and other coupling components. Over time, this can cause fatigue, cracking, or failure of the diaphragm. To prevent misalignment-related failures, ensure that the shafts are properly aligned during installation and perform regular alignment checks during maintenance.
Subjecting the diaphragm coupling to torque levels beyond its rated capacity can lead to premature failure. Overloading can cause excessive deformation of the diaphragm, leading to fatigue and ultimately, failure. To avoid overloading, use diaphragm couplings with appropriate torque ratings for the specific application and ensure that the system operates within the recommended limits.
Exposure to corrosive environments or contaminants can degrade the material of the diaphragm and other coupling components, reducing their strength and integrity. To prevent corrosion-related failures, use diaphragm couplings made from corrosion-resistant materials in environments where exposure to chemicals or moisture is a concern. Regularly inspect and clean the coupling to remove any contaminants that may have accumulated.
Repeated cycles of loading and unloading can cause fatigue in the diaphragm material over time. Fatigue-related failures may manifest as cracks or fractures in the diaphragm. To mitigate fatigue, choose diaphragm couplings made from materials with high fatigue resistance. Regular inspections can also help detect early signs of fatigue-related issues.
Incorrect installation procedures, such as insufficient torque on fasteners or misaligned components, can lead to uneven stresses on the diaphragm coupling, accelerating wear and failure. To prevent improper installation-related failures, follow the manufacturer’s guidelines and use appropriate tools and procedures during installation.
Excessive vibrations in the system can lead to premature wear and failure of the diaphragm coupling. To reduce vibrations, ensure that the system is properly balanced and that any issues causing vibrations, such as misalignment or mechanical resonance, are addressed promptly.
Insufficient or irregular maintenance can lead to undetected issues and accelerated wear in the diaphragm coupling. Implement a comprehensive maintenance program that includes regular inspections, lubrication, and alignment checks to identify and address potential problems early.
By addressing these potential causes of failure and taking appropriate preventive measures, such as proper installation, regular maintenance, and using suitable materials, the reliability and lifespan of diaphragm couplings can be significantly improved in various industrial applications.
Can Diaphragm Couplings Accommodate Different Shaft Sizes and Handle High Torque Loads?
Yes, diaphragm couplings are designed to accommodate different shaft sizes and handle high torque loads efficiently. Here’s how they achieve these functionalities:
Accommodating Different Shaft Sizes:
Diaphragm couplings are available in various sizes and configurations, allowing them to accommodate different shaft diameters. The hubs of the coupling can be manufactured with different bore sizes to match the specific diameter of the connected shafts. This versatility makes diaphragm couplings suitable for a wide range of applications, where the shafts may have different sizes.
Handling High Torque Loads:
Despite their flexible design, diaphragm couplings are capable of handling high torque loads. The flexible diaphragm, typically made of high-strength metal, can transmit torque effectively between the shafts without significant power loss. The corrugations or convolutions in the diaphragm contribute to its torsional rigidity, ensuring efficient torque transmission even at high levels of power.
Moreover, the metal diaphragm’s ability to flex and absorb misalignment also helps in distributing the torque evenly, minimizing stress concentrations on the coupling and connected machinery. This feature allows diaphragm couplings to maintain their performance and reliability under demanding conditions with high torque requirements.
In summary, diaphragm couplings can accommodate different shaft sizes by offering a range of hub sizes and configurations. Additionally, they are capable of handling high torque loads efficiently due to the torsional rigidity of the flexible metal diaphragm and its ability to absorb misalignment, ensuring smooth and reliable torque transmission in various mechanical systems.
editor by CX 2024-03-14