| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
Flange connectors
81 - 100 / 227
| Cable length | 0.6 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 0.6 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 0.6 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 24 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 2 A |
| Wire cross section AWG | 24 AWG |
| Cable length | 0.6 m |
| Operating current max. | 2 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 0.6 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 0.6 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 24 AWG |
| Cable length | 2 m |
| Operating current max. | 4 A |
| Wire cross section AWG | 22 AWG |
| Cable length | 0.6 m |
| Operating current max. | 2 A |
| Wire cross section AWG | 24 AWG |
| Cable length | 2 m |
| Operating current max. | 2 A |
| Wire cross section AWG | 24 AWG |
| Cable length | 0.6 m |
| Operating current max. | 2 A |
| Wire cross section AWG | 24 AWG |
Flange connectors are an important component in industrial connection technology. They are used to securely connect pipelines, containers or apparatus. In doing so, they not only enable easy assembly and disassembly, but also ensure reliable sealing.
A flange connector usually consists of two flanges that are firmly connected with screws. A gasket is placed between the flanges to ensure a gas- or liquid-tight connection. Flanges can be made of different materials such as steel, stainless steel or even plastic, depending on the requirements for strength and chemical resistance.
The assembly of a flange connector is relatively simple. First, the two flanges are attached to the components to be connected. The bolts are then inserted through the matching holes in the flanges and tightened with nuts. Make sure that the screws are tightened evenly to achieve an even distribution of pressure on the seal. After tightening the screws, the connection is completed.
The advantage of flange connectors is their flexibility. They can be used in various industries, such as chemical, food or pharmaceutical. In addition, they are suitable for different pressure and temperature ranges. Flange connectors can also be used for large diameters, so that even large quantities of liquids or gases can be transported without any problems.
Another advantage of flange connectors is their ease of maintenance. In the event of a leak or repair, the flanges can be easily disassembled and reassembled without having to replace the entire pipeline. This saves time and costs.
To ensure a reliable seal, the choice of the right gasket is of great importance. Depending on the application and the media being transported, different sealing materials such as rubber, PTFE or metal can be used. It is also important to regularly check the seal for damage or wear and replace it if necessary.
Overall, flanged connectors are an efficient and reliable solution for connecting pipelines, vessels and apparatus. They allow easy assembly and disassembly, ensure a secure seal and are flexible in their application. With proper gasket selection and maintenance, flanged connectors can ensure a long-term and secure connection.
A flange connector usually consists of two flanges that are firmly connected with screws. A gasket is placed between the flanges to ensure a gas- or liquid-tight connection. Flanges can be made of different materials such as steel, stainless steel or even plastic, depending on the requirements for strength and chemical resistance.
The assembly of a flange connector is relatively simple. First, the two flanges are attached to the components to be connected. The bolts are then inserted through the matching holes in the flanges and tightened with nuts. Make sure that the screws are tightened evenly to achieve an even distribution of pressure on the seal. After tightening the screws, the connection is completed.
The advantage of flange connectors is their flexibility. They can be used in various industries, such as chemical, food or pharmaceutical. In addition, they are suitable for different pressure and temperature ranges. Flange connectors can also be used for large diameters, so that even large quantities of liquids or gases can be transported without any problems.
Another advantage of flange connectors is their ease of maintenance. In the event of a leak or repair, the flanges can be easily disassembled and reassembled without having to replace the entire pipeline. This saves time and costs.
To ensure a reliable seal, the choice of the right gasket is of great importance. Depending on the application and the media being transported, different sealing materials such as rubber, PTFE or metal can be used. It is also important to regularly check the seal for damage or wear and replace it if necessary.
Overall, flanged connectors are an efficient and reliable solution for connecting pipelines, vessels and apparatus. They allow easy assembly and disassembly, ensure a secure seal and are flexible in their application. With proper gasket selection and maintenance, flanged connectors can ensure a long-term and secure connection.
What is a flange connector and what is it used for?
A flange connector is a type of electrical connector used to connect cables or wires in electrical circuits. It consists of a male and a female connector part, which are connected to each other by flanges.
The flange connector is frequently used in industrial applications, particularly for connecting cables in control cabinets and control systems. It is used to establish a reliable electrical connection between different components, while at the same time enabling easy installation and maintenance.
The flange connector can be available in different sizes and designs, depending on the specific requirements of the application. It offers a secure and robust connection and can also be used in environments with high temperatures or aggressive chemicals.
The flange connector is frequently used in industrial applications, particularly for connecting cables in control cabinets and control systems. It is used to establish a reliable electrical connection between different components, while at the same time enabling easy installation and maintenance.
The flange connector can be available in different sizes and designs, depending on the specific requirements of the application. It offers a secure and robust connection and can also be used in environments with high temperatures or aggressive chemicals.
What different types of flange connectors are there?
There are several different types of flange connectors, including:
1. Bayonet flange connector: This type of connector has a bayonet lock that enables a quick and secure connection. They are often used in military applications and in the aerospace industry.
2. Round flange connector: These connectors have a round flange with a certain number of mounting holes. They are frequently used in industry, particularly in electrical engineering and mechanical engineering.
3. Rectangular flange connector: These connectors have a rectangular flange with mounting holes. They are frequently used in telecommunications, the automotive sector and industrial automation.
4. Square flange connectors: These connectors have a square flange with mounting holes. They are often used in electrical engineering and mechanical engineering.
5. Hexagonal flange connector: These connectors have a hexagonal flange with mounting holes. They are frequently used in hydraulics and pneumatics.
6. Plug connector with threaded flange: These connectors have a threaded flange that ensures a secure connection. They are often used in electrical engineering and mechanical engineering.
This list is not exhaustive, as there are other types of flange connectors that have been developed for specific applications.
1. Bayonet flange connector: This type of connector has a bayonet lock that enables a quick and secure connection. They are often used in military applications and in the aerospace industry.
2. Round flange connector: These connectors have a round flange with a certain number of mounting holes. They are frequently used in industry, particularly in electrical engineering and mechanical engineering.
3. Rectangular flange connector: These connectors have a rectangular flange with mounting holes. They are frequently used in telecommunications, the automotive sector and industrial automation.
4. Square flange connectors: These connectors have a square flange with mounting holes. They are often used in electrical engineering and mechanical engineering.
5. Hexagonal flange connector: These connectors have a hexagonal flange with mounting holes. They are frequently used in hydraulics and pneumatics.
6. Plug connector with threaded flange: These connectors have a threaded flange that ensures a secure connection. They are often used in electrical engineering and mechanical engineering.
This list is not exhaustive, as there are other types of flange connectors that have been developed for specific applications.
How does a flange connector work and what advantages does it offer over other connection methods?
A flange connector consists of a flange on one side and a mating flange on the other. The two flanges are bolted together, creating a secure and tight connection. The connection is sealed by a gasket that is placed between the flanges.
The flange connector offers several advantages over other connection methods:
1. High load capacity: Flange connectors are capable of withstanding high pressures and temperatures. They are often used in industrial plants where a reliable connection is required under extreme conditions.
2. Simple assembly: The flange connector enables quick and easy installation. The flanges are simply screwed together without the need for additional tools or special know-how.
3. Flexibility: Flange connectors can be manufactured in different sizes and materials to meet the specific requirements of an application. They can also be combined with different sealing materials to ensure optimum sealing.
4. Ease of maintenance: If necessary, flange connectors can be easily dismantled and reassembled to carry out maintenance or repair work. This enables efficient and cost-effective maintenance of the system.
5. Compatibility: Flange connectors are compatible with various standards and norms, which facilitates their use in different industries and applications.
Overall, flange connectors offer a reliable and efficient connection solution for numerous applications thanks to their robust design, simple installation and high load-bearing capacity.
The flange connector offers several advantages over other connection methods:
1. High load capacity: Flange connectors are capable of withstanding high pressures and temperatures. They are often used in industrial plants where a reliable connection is required under extreme conditions.
2. Simple assembly: The flange connector enables quick and easy installation. The flanges are simply screwed together without the need for additional tools or special know-how.
3. Flexibility: Flange connectors can be manufactured in different sizes and materials to meet the specific requirements of an application. They can also be combined with different sealing materials to ensure optimum sealing.
4. Ease of maintenance: If necessary, flange connectors can be easily dismantled and reassembled to carry out maintenance or repair work. This enables efficient and cost-effective maintenance of the system.
5. Compatibility: Flange connectors are compatible with various standards and norms, which facilitates their use in different industries and applications.
Overall, flange connectors offer a reliable and efficient connection solution for numerous applications thanks to their robust design, simple installation and high load-bearing capacity.
What materials are used for flange connectors and what attributes do they have?
Flange connectors are usually made from different materials, depending on the requirements of the application. Here are some commonly used materials and their attributes:
1. Stainless steel: Stainless steel is very popular due to its corrosion resistance and strength. It can also be used at high temperatures and offers high resistance to chemical and physical influences.
2. Carbon steel: Carbon steel is also very resistant and can be used at high temperatures. However, it is more susceptible to corrosion and therefore requires an additional coating or treatment to extend its service life.
3. Aluminum: Aluminum is often used for applications where weight reduction is important. It is lightweight, corrosion-resistant and has good electrical conductivity properties. However, it is not as strong as other materials and can deform at high temperatures.
4. Plastics: Plastics such as PVC, polyethylene or PTFE are used for applications where corrosion resistance and insulation are important. They are lightweight, inexpensive and can be produced in different colors. However, plastics are not as strong as metals and can melt or deform at high temperatures.
The choice of material depends on various factors, such as the application environment, pressure, temperature, corrosion resistance and mechanical requirements. It is important to select the right material according to the specific requirements to ensure optimum performance and durability of the flange connector.
1. Stainless steel: Stainless steel is very popular due to its corrosion resistance and strength. It can also be used at high temperatures and offers high resistance to chemical and physical influences.
2. Carbon steel: Carbon steel is also very resistant and can be used at high temperatures. However, it is more susceptible to corrosion and therefore requires an additional coating or treatment to extend its service life.
3. Aluminum: Aluminum is often used for applications where weight reduction is important. It is lightweight, corrosion-resistant and has good electrical conductivity properties. However, it is not as strong as other materials and can deform at high temperatures.
4. Plastics: Plastics such as PVC, polyethylene or PTFE are used for applications where corrosion resistance and insulation are important. They are lightweight, inexpensive and can be produced in different colors. However, plastics are not as strong as metals and can melt or deform at high temperatures.
The choice of material depends on various factors, such as the application environment, pressure, temperature, corrosion resistance and mechanical requirements. It is important to select the right material according to the specific requirements to ensure optimum performance and durability of the flange connector.
How is a flange connector installed and how is it maintained?
A flange connector is usually installed in the following way:
1. Preparation: Ensure that the flange connections are clean and free of dirt or other contaminants. Also check that the seals are in good condition and replace them if necessary.
2. Positioning: Align the two flange connections so that they fit together exactly. Make sure that the holes are correctly aligned.
3. Assembly: Place the gaskets between the flanges and ensure that they are positioned correctly. Connect the flanges together using the appropriate screws or rivets. Tighten the fastening elements evenly and in the correct sequence to ensure an even and tight connection.
4. Review: Check the connection for leaks by carrying out pressure or leak tests.
The maintenance of a flange connector usually involves the following steps:
1. Regular inspection: Regularly check the condition of the seals, screws and rivets to ensure that they are intact and in good condition. Replace damaged or worn parts in good time.
2. Cleaning: Clean the flange connections regularly to remove dirt, dust or other impurities. If necessary, use suitable cleaning agents or procedures.
3. Retraction: Check the fastening elements regularly and tighten them if necessary to ensure an even and tight connection.
4. Maintenance log: Keep a maintenance log to document all inspections, cleanings and retightenings. This enables better monitoring and planning of future maintenance work.
It is important to follow the manufacturer's specific instructions and, where applicable, industry-specific standards or regulations to ensure proper installation and maintenance of the flange connector.
1. Preparation: Ensure that the flange connections are clean and free of dirt or other contaminants. Also check that the seals are in good condition and replace them if necessary.
2. Positioning: Align the two flange connections so that they fit together exactly. Make sure that the holes are correctly aligned.
3. Assembly: Place the gaskets between the flanges and ensure that they are positioned correctly. Connect the flanges together using the appropriate screws or rivets. Tighten the fastening elements evenly and in the correct sequence to ensure an even and tight connection.
4. Review: Check the connection for leaks by carrying out pressure or leak tests.
The maintenance of a flange connector usually involves the following steps:
1. Regular inspection: Regularly check the condition of the seals, screws and rivets to ensure that they are intact and in good condition. Replace damaged or worn parts in good time.
2. Cleaning: Clean the flange connections regularly to remove dirt, dust or other impurities. If necessary, use suitable cleaning agents or procedures.
3. Retraction: Check the fastening elements regularly and tighten them if necessary to ensure an even and tight connection.
4. Maintenance log: Keep a maintenance log to document all inspections, cleanings and retightenings. This enables better monitoring and planning of future maintenance work.
It is important to follow the manufacturer's specific instructions and, where applicable, industry-specific standards or regulations to ensure proper installation and maintenance of the flange connector.
What safety measures must be observed when using flange connectors?
Various safety measures must be observed when using flange connectors:
1. Assembly: The flange connector should be installed in accordance with the manufacturer's instructions. Make sure that all components are correctly assembled and tightened.
2. Seal: It is important that a suitable gasket is fitted between the flanges to ensure a reliable seal. The seal should meet the specific requirements of the application.
3. Pressure test: Before commissioning, a pressure test should be carried out to ensure that the flange connector can withstand the required pressure. The maximum operating pressure should not be exceeded.
4. Temperature: The temperature resistance of the flange connector must be taken into account in order to avoid damage or loss of performance. It is important that the flange connector is suitable for the intended temperature environment.
5. Monitoring: A visual inspection of the flange connectors should be carried out regularly in order to detect damage or wear in good time. Defective parts should be replaced if necessary.
6. Handling: When transporting and handling the flange connectors, care should be taken to ensure that they are not dropped or handled roughly. This could damage them and impair their function.
7. Training: Persons working with flange connectors should be informed and trained about the correct handling and safety measures in order to avoid accidents or injuries.
1. Assembly: The flange connector should be installed in accordance with the manufacturer's instructions. Make sure that all components are correctly assembled and tightened.
2. Seal: It is important that a suitable gasket is fitted between the flanges to ensure a reliable seal. The seal should meet the specific requirements of the application.
3. Pressure test: Before commissioning, a pressure test should be carried out to ensure that the flange connector can withstand the required pressure. The maximum operating pressure should not be exceeded.
4. Temperature: The temperature resistance of the flange connector must be taken into account in order to avoid damage or loss of performance. It is important that the flange connector is suitable for the intended temperature environment.
5. Monitoring: A visual inspection of the flange connectors should be carried out regularly in order to detect damage or wear in good time. Defective parts should be replaced if necessary.
6. Handling: When transporting and handling the flange connectors, care should be taken to ensure that they are not dropped or handled roughly. This could damage them and impair their function.
7. Training: Persons working with flange connectors should be informed and trained about the correct handling and safety measures in order to avoid accidents or injuries.
What norms and standards apply to flange connectors and how are they tested and certified?
Various norms and standards apply to flange connectors, depending on the area of application and industry. Some of the most important standards are
1. DIN EN 1092-1: This standard specifies the requirements for flange connectors used in piping systems. It includes various pressure classes, materials and dimensions.
2. ANSI/ASME B16.5: This standard is used in the USA and defines the dimensions, pressure classes and materials of flanges and flange connectors.
3. API 6A: This standard is used in the oil and gas industry and specifies the requirements for flange connectors for use in drilling and production facilities.
4. ISO 7005: This standard specifies the dimensions and pressure classes of flanges for general applications.
Flange connectors are usually certified by independent testing institutes or certification bodies. Manufacturers must test their products in accordance with the relevant norms and standards and provide the necessary evidence. The tests can cover various aspects, such as:
- Pressure test: The connectors are subjected to a certain pressure to check their tightness and load-bearing capacity.
- Material testing: The materials used are tested for their mechanical attributes, corrosion resistance and other specific requirements.
- Dimensional check: The dimensions of the flange connectors are checked to ensure that they comply with the specifications.
- Temperature and pressure cycling tests: The connectors are exposed to extreme changes in temperature and pressure to test their resistance to such conditions.
If the products meet all the requirements, they receive certification or a test certificate confirming their conformity with the norms and standards. These certificates enable manufacturers to sell their products on the market and give customers the assurance that the flange connectors meet the required quality standards.
1. DIN EN 1092-1: This standard specifies the requirements for flange connectors used in piping systems. It includes various pressure classes, materials and dimensions.
2. ANSI/ASME B16.5: This standard is used in the USA and defines the dimensions, pressure classes and materials of flanges and flange connectors.
3. API 6A: This standard is used in the oil and gas industry and specifies the requirements for flange connectors for use in drilling and production facilities.
4. ISO 7005: This standard specifies the dimensions and pressure classes of flanges for general applications.
Flange connectors are usually certified by independent testing institutes or certification bodies. Manufacturers must test their products in accordance with the relevant norms and standards and provide the necessary evidence. The tests can cover various aspects, such as:
- Pressure test: The connectors are subjected to a certain pressure to check their tightness and load-bearing capacity.
- Material testing: The materials used are tested for their mechanical attributes, corrosion resistance and other specific requirements.
- Dimensional check: The dimensions of the flange connectors are checked to ensure that they comply with the specifications.
- Temperature and pressure cycling tests: The connectors are exposed to extreme changes in temperature and pressure to test their resistance to such conditions.
If the products meet all the requirements, they receive certification or a test certificate confirming their conformity with the norms and standards. These certificates enable manufacturers to sell their products on the market and give customers the assurance that the flange connectors meet the required quality standards.
What are the areas of application for flange connectors and which industries use them?
Flange connectors are used in various applications, especially in industries where a reliable and secure connection of electrical or electronic components is required. Here are some of the most common applications and industries in which flange connectors are used:
1. Industrial automation and control: Flange connectors are used in automation technology to establish electrical connections between various components such as sensors, actuators, switches and control units.
2. Telecommunications: In the telecommunications industry, flange connectors are used to connect cables and wires in communication systems such as telephone systems, mobile phone networks and fiber optic infrastructures.
3. Medical technology: Flange connectors are used in medical technology, particularly for connecting medical devices, sensors and instruments in hospitals and medical facilities.
4. Energy and power supply: Flange connectors are used in the energy and power supply industry to create safe electrical connections in high-voltage lines, switchgear and distribution networks.
5. Aerospace: In the aerospace industry, flange connectors are used in aircraft, satellites and spacecraft to make electrical connections between different systems and components.
6. Military technology: Flange connectors are also used in military technology to create robust and reliable electrical connections in military vehicles, weapons and communication systems.
This list is not exhaustive, as flange connectors can be used in many other applications where a safe and reliable electrical connection is required.
1. Industrial automation and control: Flange connectors are used in automation technology to establish electrical connections between various components such as sensors, actuators, switches and control units.
2. Telecommunications: In the telecommunications industry, flange connectors are used to connect cables and wires in communication systems such as telephone systems, mobile phone networks and fiber optic infrastructures.
3. Medical technology: Flange connectors are used in medical technology, particularly for connecting medical devices, sensors and instruments in hospitals and medical facilities.
4. Energy and power supply: Flange connectors are used in the energy and power supply industry to create safe electrical connections in high-voltage lines, switchgear and distribution networks.
5. Aerospace: In the aerospace industry, flange connectors are used in aircraft, satellites and spacecraft to make electrical connections between different systems and components.
6. Military technology: Flange connectors are also used in military technology to create robust and reliable electrical connections in military vehicles, weapons and communication systems.
This list is not exhaustive, as flange connectors can be used in many other applications where a safe and reliable electrical connection is required.