| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
Actuation buttons
1 - 14
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | NPN |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
| Switching current, max. | 0.2 A |
| Switching function | No contact |
| Switching output | PNP |
Actuation button: The inconspicuous heroes of everyday life
It is impossible to imagine our daily lives without actuation buttons, even if they often go unnoticed. These small, inconspicuous switches are built into numerous electronic devices and equipment and allow us to operate them easily and conveniently. Although often taken for granted, they play a crucial role in activating and controlling a wide variety of functions.
An actuating pushbutton consists of a housing, a switch mechanism and a pushbutton cap. The housing protects the switch mechanism from external influences, ensuring its durability and reliability. The switch mechanism itself consists of contacts, springs and a mechanism that triggers an electrical signal when the button is pressed. The touch cap offers the user a pleasant feel and facilitates operation.
Actuation switches are used in a wide variety of applications. In industry, for example, they are used to control machines and systems. Here, they often serve as emergency stop switches to ensure employee safety in the event of an emergency. In the automotive industry, actuation buttons are used in dashboards, steering wheels and door panels. They allow the driver to control various functions such as switching on the windshield wipers or opening the trunk at the touch of a button.
Actuating buttons are also widely used in the home. They can be found in remote controls, household appliances such as coffee machines or vacuum cleaners, but also in modern smart home systems. Here, they enable simple and convenient operation and contribute to the automation of everyday life.
The development of actuation probes has made great progress in recent years. Thanks to new technologies, today they can be made in different shapes, sizes and colors. Great improvements have also been made in terms of service life and actuating force. Modern actuation buttons are often equipped with LED lighting to provide visual feedback to the user.
Another trend in actuation buttons is the integration of touch-sensitive sensors. These allow touch-free operation for added convenience and hygiene. In public buildings or hospitals, touch-sensitive actuation buttons can reduce the spread of pathogens.
Although actuation buttons often go unnoticed, they are nevertheless indispensable components of our everyday lives. They make it easier for us to operate equipment and systems and contribute to safety and comfort. The continuous development of these small, inconspicuous heroes ensures that they will continue to play an important role in our lives in the future. So we should quietly pay more attention to them for once and appreciate their importance.
It is impossible to imagine our daily lives without actuation buttons, even if they often go unnoticed. These small, inconspicuous switches are built into numerous electronic devices and equipment and allow us to operate them easily and conveniently. Although often taken for granted, they play a crucial role in activating and controlling a wide variety of functions.
An actuating pushbutton consists of a housing, a switch mechanism and a pushbutton cap. The housing protects the switch mechanism from external influences, ensuring its durability and reliability. The switch mechanism itself consists of contacts, springs and a mechanism that triggers an electrical signal when the button is pressed. The touch cap offers the user a pleasant feel and facilitates operation.
Actuation switches are used in a wide variety of applications. In industry, for example, they are used to control machines and systems. Here, they often serve as emergency stop switches to ensure employee safety in the event of an emergency. In the automotive industry, actuation buttons are used in dashboards, steering wheels and door panels. They allow the driver to control various functions such as switching on the windshield wipers or opening the trunk at the touch of a button.
Actuating buttons are also widely used in the home. They can be found in remote controls, household appliances such as coffee machines or vacuum cleaners, but also in modern smart home systems. Here, they enable simple and convenient operation and contribute to the automation of everyday life.
The development of actuation probes has made great progress in recent years. Thanks to new technologies, today they can be made in different shapes, sizes and colors. Great improvements have also been made in terms of service life and actuating force. Modern actuation buttons are often equipped with LED lighting to provide visual feedback to the user.
Another trend in actuation buttons is the integration of touch-sensitive sensors. These allow touch-free operation for added convenience and hygiene. In public buildings or hospitals, touch-sensitive actuation buttons can reduce the spread of pathogens.
Although actuation buttons often go unnoticed, they are nevertheless indispensable components of our everyday lives. They make it easier for us to operate equipment and systems and contribute to safety and comfort. The continuous development of these small, inconspicuous heroes ensures that they will continue to play an important role in our lives in the future. So we should quietly pay more attention to them for once and appreciate their importance.
What is an actuation button and what is it used for?
An actuating button is a device used to make or break an electrical contact. It is often used in electronic circuits or devices to trigger an action when pressed or actuated.
An actuation button normally consists of a mechanical switch that is activated by pressing or actuating it. When the button is pressed, it closes the electrical contact and allows the current to flow. When the button is released, it opens the contact and interrupts the current flow.
Actuation buttons are used in various applications, e.g. in industrial machinery, electronic devices, household appliances, vehicles and many other areas. They are used to trigger certain functions or actions, such as switching devices on and off, opening or closing doors, starting or stopping machines, activating alarms, etc.
Actuation buttons can have different shapes, sizes and colors to indicate different functions or actions. They can be designed as simple pushbuttons, toggle switches, slide switches, rocker switches or rotary knobs.
An actuation button normally consists of a mechanical switch that is activated by pressing or actuating it. When the button is pressed, it closes the electrical contact and allows the current to flow. When the button is released, it opens the contact and interrupts the current flow.
Actuation buttons are used in various applications, e.g. in industrial machinery, electronic devices, household appliances, vehicles and many other areas. They are used to trigger certain functions or actions, such as switching devices on and off, opening or closing doors, starting or stopping machines, activating alarms, etc.
Actuation buttons can have different shapes, sizes and colors to indicate different functions or actions. They can be designed as simple pushbuttons, toggle switches, slide switches, rocker switches or rotary knobs.
How does an actuation button work and what types are there?
An actuation button is an electronic component that is used to open or close an electrical circuit when it is actuated. It is often also referred to as a pushbutton or switch.
There are various types of push-buttons, which differ in terms of their function and design:
1. Pushbutton: This is the most common type of pushbutton. It consists of a housing and a button that can be pressed to open or close the circuit. Pushbuttons can normally be in two states: either open or closed.
2. Toggle switch: This is an actuation button that can be tilted to one of two positions to open or close the circuit. Toggle switches often have a lever or rocker shape.
3. Slide switch: This is an operating button that can be pushed to one of two or more positions to open or close the circuit accordingly. Slide switches often have a slide or a lever.
4. Rotary switch: This is an operating button that can be turned to open or close the circuit. Rotary switches often have knurling or a handle to make turning easier.
5. Touch switch: This is an actuation button that only remains closed as long as it is actuated. As soon as the pressure on the button is released, the circuit opens again automatically.
Actuation buttons are used in many electronic devices, such as remote controls, computer keyboards, electrical switches and many other applications.
There are various types of push-buttons, which differ in terms of their function and design:
1. Pushbutton: This is the most common type of pushbutton. It consists of a housing and a button that can be pressed to open or close the circuit. Pushbuttons can normally be in two states: either open or closed.
2. Toggle switch: This is an actuation button that can be tilted to one of two positions to open or close the circuit. Toggle switches often have a lever or rocker shape.
3. Slide switch: This is an operating button that can be pushed to one of two or more positions to open or close the circuit accordingly. Slide switches often have a slide or a lever.
4. Rotary switch: This is an operating button that can be turned to open or close the circuit. Rotary switches often have knurling or a handle to make turning easier.
5. Touch switch: This is an actuation button that only remains closed as long as it is actuated. As soon as the pressure on the button is released, the circuit opens again automatically.
Actuation buttons are used in many electronic devices, such as remote controls, computer keyboards, electrical switches and many other applications.
What attributes should an actuating button have in order to be used optimally?
An actuation button should have the following attributes in order to be used optimally:
1. Robustness: The push-button should be made of high-quality materials that guarantee a long service life. It should also be able to withstand shocks, vibrations and other stresses.
2. Reliability: The push-button should provide reliable switching performance to enable error-free switching. It should also be protected against unintentional operation.
3. Ergonomics: The button should have an ergonomic shape that enables simple and convenient operation. It should also be easily recognizable and easy to find in order to avoid operating errors.
4. Actuating force: The push-button should have an appropriate actuating force to prevent accidental switching. At the same time, however, it should not require too much force to enable easy operation.
5. Protection type: The push-button should have a sufficient degree of protection to be protected against dust, moisture and other environmental influences. This is particularly important if the push-button is used in harsh or industrial environments.
6. Signalization: The push-button should have clear and easily visible signaling to inform the user of the switching status. This can be done using an LED display or haptic feedback, for example.
7. Mounting options: The push-button should offer various mounting options to allow easy and flexible installation in different environments. These include, for example, fixing holes or clips for fastening.
8. Compatibility: The push-button should be compatible with the corresponding electronic circuits and systems to enable problem-free integration. This can be achieved, for example, through standardized connections or protocols.
These attributes can vary depending on the area of application and individual requirements. It is important to consider the specific requirements in order to select the optimum actuating button.
1. Robustness: The push-button should be made of high-quality materials that guarantee a long service life. It should also be able to withstand shocks, vibrations and other stresses.
2. Reliability: The push-button should provide reliable switching performance to enable error-free switching. It should also be protected against unintentional operation.
3. Ergonomics: The button should have an ergonomic shape that enables simple and convenient operation. It should also be easily recognizable and easy to find in order to avoid operating errors.
4. Actuating force: The push-button should have an appropriate actuating force to prevent accidental switching. At the same time, however, it should not require too much force to enable easy operation.
5. Protection type: The push-button should have a sufficient degree of protection to be protected against dust, moisture and other environmental influences. This is particularly important if the push-button is used in harsh or industrial environments.
6. Signalization: The push-button should have clear and easily visible signaling to inform the user of the switching status. This can be done using an LED display or haptic feedback, for example.
7. Mounting options: The push-button should offer various mounting options to allow easy and flexible installation in different environments. These include, for example, fixing holes or clips for fastening.
8. Compatibility: The push-button should be compatible with the corresponding electronic circuits and systems to enable problem-free integration. This can be achieved, for example, through standardized connections or protocols.
These attributes can vary depending on the area of application and individual requirements. It is important to consider the specific requirements in order to select the optimum actuating button.
Which industries or applications benefit most from pushbuttons?
Actuation buttons are used in various industries and applications. Here are some examples:
1. Industry: Actuation buttons are frequently used in industry to control machines and systems. They are used to activate processes, for example to start and stop machines or to trigger emergency stop functions.
2. Automotive industry: In cars, pushbuttons are used for various functions, such as operating windows, doors, windshield wipers, lights and other electronic systems.
3. Medical technology: Actuation buttons are used in medical devices and instruments to enable functions such as switching on and off, regulating intensity or speed or selecting programs.
4. Electronics: Pushbuttons are used in electronic devices such as televisions, computers, cell phones and household appliances. They are used to operate and control various functions.
5. Security technology: Actuation buttons are used in safety systems for emergency or alarm functions. They are used, for example, to trigger a panic alarm or to activate emergency exits.
6. Building and building services: Push-buttons are used in buildings to control functions such as lighting, heating, ventilation and air conditioning.
7. toy industry: Actuation buttons are used in toys to enable various play and interaction functions.
These are just a few examples, and the use of pushbuttons can vary depending on requirements and industries.
1. Industry: Actuation buttons are frequently used in industry to control machines and systems. They are used to activate processes, for example to start and stop machines or to trigger emergency stop functions.
2. Automotive industry: In cars, pushbuttons are used for various functions, such as operating windows, doors, windshield wipers, lights and other electronic systems.
3. Medical technology: Actuation buttons are used in medical devices and instruments to enable functions such as switching on and off, regulating intensity or speed or selecting programs.
4. Electronics: Pushbuttons are used in electronic devices such as televisions, computers, cell phones and household appliances. They are used to operate and control various functions.
5. Security technology: Actuation buttons are used in safety systems for emergency or alarm functions. They are used, for example, to trigger a panic alarm or to activate emergency exits.
6. Building and building services: Push-buttons are used in buildings to control functions such as lighting, heating, ventilation and air conditioning.
7. toy industry: Actuation buttons are used in toys to enable various play and interaction functions.
These are just a few examples, and the use of pushbuttons can vary depending on requirements and industries.
How does an actuation button differ from other types of switches or buttons?
An actuator button differs from other types of switches or buttons due to its function and design.
1. How it works: An actuation button is activated by pressing or actuating it and returns to its initial position when released. This means that it only remains in one state as long as it is pressed. Other types of switches or buttons can maintain a permanent state when pressed.
2. Design: Push-buttons often have a round or square shape and are relatively flat. They can be single or double-pole and often have a colored cap or label to indicate their function. Other types of switches or buttons can have different shapes, sizes and designs depending on their use.
3. Intended use: Actuation buttons are often used as pushbuttons in electronic devices, control panels or operating elements to trigger a specific function, such as switching a device on and off or starting an action. Other types of switches or buttons can be used for different applications, such as toggle switches, slide switches, combination switches, etc.
To summarize, an actuator button differs from other types of switches or buttons in the way it works, its design and its intended use.
1. How it works: An actuation button is activated by pressing or actuating it and returns to its initial position when released. This means that it only remains in one state as long as it is pressed. Other types of switches or buttons can maintain a permanent state when pressed.
2. Design: Push-buttons often have a round or square shape and are relatively flat. They can be single or double-pole and often have a colored cap or label to indicate their function. Other types of switches or buttons can have different shapes, sizes and designs depending on their use.
3. Intended use: Actuation buttons are often used as pushbuttons in electronic devices, control panels or operating elements to trigger a specific function, such as switching a device on and off or starting an action. Other types of switches or buttons can be used for different applications, such as toggle switches, slide switches, combination switches, etc.
To summarize, an actuator button differs from other types of switches or buttons in the way it works, its design and its intended use.
What safety aspects need to be considered when using push-buttons?
Several safety aspects must be observed when using actuation buttons:
1. Mechanical stability: The actuation buttons must be robust and stable to ensure long-lasting and safe use. They should not be easily broken or damaged.
2. Ergonomics: The buttons should be ergonomically designed to enable simple and safe operation. They should be easily accessible and clearly labeled to avoid confusion.
3. Protection against incorrect operation: Actuation buttons should be designed in such a way that they cannot be triggered accidentally or unintentionally. This can be achieved by using suitable covers or protective caps.
4. Protection against unintentional activation: If the actuation buttons are used to activate machines or other devices, they should be designed to prevent unintentional activation. This can be achieved by additional safety mechanisms such as key switches or safety interlocks.
5. Electrical safety: Actuation buttons must comply with the applicable electrical safety standards in order to avoid electrical hazards. For example, they should have adequate protection against short circuits or overloads.
6. Labeling and instructions: Actuation buttons should be clearly labeled to make their function and operation clear. In addition, instructions on safe use should be attached, for example on the use of protective equipment or compliance with safety regulations.
It is important that all relevant safety aspects are taken into account when using pushbuttons in order to avoid accidents or injuries. It may be advisable to consult specialists or security experts to ensure that all necessary security measures are taken.
1. Mechanical stability: The actuation buttons must be robust and stable to ensure long-lasting and safe use. They should not be easily broken or damaged.
2. Ergonomics: The buttons should be ergonomically designed to enable simple and safe operation. They should be easily accessible and clearly labeled to avoid confusion.
3. Protection against incorrect operation: Actuation buttons should be designed in such a way that they cannot be triggered accidentally or unintentionally. This can be achieved by using suitable covers or protective caps.
4. Protection against unintentional activation: If the actuation buttons are used to activate machines or other devices, they should be designed to prevent unintentional activation. This can be achieved by additional safety mechanisms such as key switches or safety interlocks.
5. Electrical safety: Actuation buttons must comply with the applicable electrical safety standards in order to avoid electrical hazards. For example, they should have adequate protection against short circuits or overloads.
6. Labeling and instructions: Actuation buttons should be clearly labeled to make their function and operation clear. In addition, instructions on safe use should be attached, for example on the use of protective equipment or compliance with safety regulations.
It is important that all relevant safety aspects are taken into account when using pushbuttons in order to avoid accidents or injuries. It may be advisable to consult specialists or security experts to ensure that all necessary security measures are taken.
What innovative technologies or developments are there in the field of pushbuttons?
There are several innovative technologies and developments in the field of pushbuttons:
1. Capacitive buttons: Instead of a physical pressure contact, capacitive switches use electrical capacitance changes that occur when the switch is touched. This technology enables non-contact switches and offers an aesthetic design as well as a longer service life.
2. Haptic feedback: Some actuation buttons are equipped with haptic feedback, which gives the user tactile feedback to confirm actuation. This can be achieved through vibrations or electronic mechanisms such as piezo actuators.
3. Optical buttons: Optical buttons detect actuation by light or infrared beams. When the button is pressed, the light or infrared radiation is interrupted, which is recognized as an actuation. This technology offers non-contact actuation and can be beneficial in dusty or dirty environments.
4. Wireless or Bluetooth buttons: Wireless or Bluetooth buttons can be used to operate devices without a physical connection. This enables flexible positioning of the push-button and can be used in home automation or medical devices, for example.
5. Push-button with touchscreen: Push-buttons with a touchscreen offer a user-friendly interface on which various functions or symbols can be displayed. The corresponding functions can be activated by touching the touchscreen. This technology is often used in smartphones, tablets and other electronic devices.
6. Push-button with power generation: Innovative push-buttons can generate energy from the actuation itself. For example, piezoelectric materials can be integrated into the button, which generate electrical energy when the button is pressed. This energy can then be used to supply other electronic components.
7. Push-button with motion detection: Some push-buttons are equipped with motion sensors that detect actuation when the push-button is moved. This can be used in gaming controllers or remote controls, for example, to recognize movements as input.
These are just a few examples of innovative technologies and developments in the field of pushbuttons. The industry is constantly evolving and further innovations are expected to come onto the market in the future.
1. Capacitive buttons: Instead of a physical pressure contact, capacitive switches use electrical capacitance changes that occur when the switch is touched. This technology enables non-contact switches and offers an aesthetic design as well as a longer service life.
2. Haptic feedback: Some actuation buttons are equipped with haptic feedback, which gives the user tactile feedback to confirm actuation. This can be achieved through vibrations or electronic mechanisms such as piezo actuators.
3. Optical buttons: Optical buttons detect actuation by light or infrared beams. When the button is pressed, the light or infrared radiation is interrupted, which is recognized as an actuation. This technology offers non-contact actuation and can be beneficial in dusty or dirty environments.
4. Wireless or Bluetooth buttons: Wireless or Bluetooth buttons can be used to operate devices without a physical connection. This enables flexible positioning of the push-button and can be used in home automation or medical devices, for example.
5. Push-button with touchscreen: Push-buttons with a touchscreen offer a user-friendly interface on which various functions or symbols can be displayed. The corresponding functions can be activated by touching the touchscreen. This technology is often used in smartphones, tablets and other electronic devices.
6. Push-button with power generation: Innovative push-buttons can generate energy from the actuation itself. For example, piezoelectric materials can be integrated into the button, which generate electrical energy when the button is pressed. This energy can then be used to supply other electronic components.
7. Push-button with motion detection: Some push-buttons are equipped with motion sensors that detect actuation when the push-button is moved. This can be used in gaming controllers or remote controls, for example, to recognize movements as input.
These are just a few examples of innovative technologies and developments in the field of pushbuttons. The industry is constantly evolving and further innovations are expected to come onto the market in the future.
How can actuation buttons be used in automated processes or machines?
Actuation buttons can be used in various ways in automated processes or machines:
1. Start/stop function: Actuation buttons can be used to start and stop the process or the machine. Pressing the button starts the process and pressing it again stops it.
2. Emergency stop function: Actuation buttons can be used as emergency stop switches. In an emergency, the button can be pressed to stop the entire process or the machine immediately and avoid potential hazards.
3. Safety function: Actuation buttons can be used in safety-critical areas to control access to certain areas or functions. For example, the button can be used to open a safety gate or activate an access point.
4. Signal transmitter: Actuation buttons can be used to signal certain actions or statuses. By pressing the button, a signal can be sent to a higher-level system, which then triggers a specific reaction.
5. Selection function: Actuation buttons can be used to select certain options or activate functions. A specific setting or mode can be selected by pressing the button.
6. Troubleshooting: Actuation buttons can also be used for diagnostic or maintenance purposes. By pressing the button, certain error codes or information can be called up to identify and rectify problems.
It is important that pushbuttons are installed and used in accordance with safety standards and guidelines to ensure the safety of people and equipment.
1. Start/stop function: Actuation buttons can be used to start and stop the process or the machine. Pressing the button starts the process and pressing it again stops it.
2. Emergency stop function: Actuation buttons can be used as emergency stop switches. In an emergency, the button can be pressed to stop the entire process or the machine immediately and avoid potential hazards.
3. Safety function: Actuation buttons can be used in safety-critical areas to control access to certain areas or functions. For example, the button can be used to open a safety gate or activate an access point.
4. Signal transmitter: Actuation buttons can be used to signal certain actions or statuses. By pressing the button, a signal can be sent to a higher-level system, which then triggers a specific reaction.
5. Selection function: Actuation buttons can be used to select certain options or activate functions. A specific setting or mode can be selected by pressing the button.
6. Troubleshooting: Actuation buttons can also be used for diagnostic or maintenance purposes. By pressing the button, certain error codes or information can be called up to identify and rectify problems.
It is important that pushbuttons are installed and used in accordance with safety standards and guidelines to ensure the safety of people and equipment.