| Applications | Vehicles & Road Traffic |
| Dimension (depth) | 29 mm |
| Dimension (width) | 49 mm |
| Housing height | 26 mm |
Housing
1 - 6
| Applications | Vehicles & Road Traffic |
| Dimension (depth) | 17 mm |
| Dimension (width) | 87 mm |
| Housing height | 25 mm |
| Applications | Vehicles & Road Traffic |
| Dimension (depth) | 80 mm |
| Dimension (width) | 54 mm |
| Housing height | 21 mm |
| Applications | Vehicles & Road Traffic |
| Dimension (depth) | 91 mm |
| Dimension (width) | 125 mm |
| Housing height | 51 mm |
| Applications | Vehicles & Road Traffic |
| Dimension (depth) | 79 mm |
| Dimension (width) | 80 mm |
| Housing height | 30 mm |
| Applications | Vehicles & Road Traffic Electrical industry |
| Dimension (depth) | 40.3 mm |
| Dimension (width) | 89 mm |
| Housing height | 17.6 mm |
The enclosure of an electronic device can often be underestimated, but it plays a critical role in the performance and protection of the device. A good case should not only be aesthetically pleasing, but also robust, functional and durable.
An important aspect of an enclosure is its choice of materials. There are various materials that can be used for enclosures, such as plastic, metal and glass. Each material has its advantages and disadvantages. Plastic is lightweight and inexpensive, but may not be as strong as metal. Metal, on the other hand, is strong and durable, but also heavier and more expensive. Glass is another option that is known for its elegant look, but can also be more susceptible to scratches and breakage.
Another important factor for an enclosure is its construction. The housing must be designed to securely hold the components of the device and protect them from shock, vibration and other influences. It should also provide enough space for ventilation and cooling of the device to avoid overheating. The placement of ports, buttons and other controls should also be well thought out for easy and convenient operation.
Another important aspect is the sealing of the housing. Some devices must be protected from water, dust and other elements. There are special housings for this that are waterproof, dustproof or both. These housings are often equipped with special seals and closures to prevent the ingress of moisture and dust. Such housings are especially important for outdoor devices such as cell phones, cameras and smartwatches.
In addition to protecting the device, aesthetics also play a role. The case should complement the design of the device and look appealing. Manufacturers can use different colors, textures and finishes to make the case attractive. Some cases can also be personalized to suit the user's individual tastes.
In today's world, devices are getting smaller and more compact, which increases the challenge for enclosure manufacturers. They need to find innovative solutions to fit devices into smaller and thinner packages without sacrificing performance or protection. This often requires the use of new materials and technologies to enable thinner and lighter packages.
In summary, the housing of an electronic device is an important factor in its performance, protection and appearance. It must be robust, functional, durable and aesthetically pleasing. Material selection, construction, sealing, and aesthetics are all aspects that must be considered when designing an enclosure. As technology advances and devices become smaller, enclosure manufacturers are faced with new challenges to find innovative solutions.
An important aspect of an enclosure is its choice of materials. There are various materials that can be used for enclosures, such as plastic, metal and glass. Each material has its advantages and disadvantages. Plastic is lightweight and inexpensive, but may not be as strong as metal. Metal, on the other hand, is strong and durable, but also heavier and more expensive. Glass is another option that is known for its elegant look, but can also be more susceptible to scratches and breakage.
Another important factor for an enclosure is its construction. The housing must be designed to securely hold the components of the device and protect them from shock, vibration and other influences. It should also provide enough space for ventilation and cooling of the device to avoid overheating. The placement of ports, buttons and other controls should also be well thought out for easy and convenient operation.
Another important aspect is the sealing of the housing. Some devices must be protected from water, dust and other elements. There are special housings for this that are waterproof, dustproof or both. These housings are often equipped with special seals and closures to prevent the ingress of moisture and dust. Such housings are especially important for outdoor devices such as cell phones, cameras and smartwatches.
In addition to protecting the device, aesthetics also play a role. The case should complement the design of the device and look appealing. Manufacturers can use different colors, textures and finishes to make the case attractive. Some cases can also be personalized to suit the user's individual tastes.
In today's world, devices are getting smaller and more compact, which increases the challenge for enclosure manufacturers. They need to find innovative solutions to fit devices into smaller and thinner packages without sacrificing performance or protection. This often requires the use of new materials and technologies to enable thinner and lighter packages.
In summary, the housing of an electronic device is an important factor in its performance, protection and appearance. It must be robust, functional, durable and aesthetically pleasing. Material selection, construction, sealing, and aesthetics are all aspects that must be considered when designing an enclosure. As technology advances and devices become smaller, enclosure manufacturers are faced with new challenges to find innovative solutions.
What is a housing and what is its function?
An enclosure is an outer protective cover or packaging for electronic devices, machines or other objects. It is used to protect the internal components of the device from external influences such as dust, moisture, dirt, shocks or mechanical damage.
The housing can be made of various materials such as plastic, metal or glass and is usually designed in such a way that it does not impair the functionality of the device. It often has openings and cut-outs for buttons, connections, displays or ventilation slots to allow the device to be operated and ventilated.
In addition to protecting the internal components, an enclosure can also fulfill aesthetic or ergonomic functions. It can make the device more attractive, offer a pleasant feel or facilitate handling and operation.
Overall, the housing serves to protect the device from external influences and to ensure its functionality and the safety of the user.
The housing can be made of various materials such as plastic, metal or glass and is usually designed in such a way that it does not impair the functionality of the device. It often has openings and cut-outs for buttons, connections, displays or ventilation slots to allow the device to be operated and ventilated.
In addition to protecting the internal components, an enclosure can also fulfill aesthetic or ergonomic functions. It can make the device more attractive, offer a pleasant feel or facilitate handling and operation.
Overall, the housing serves to protect the device from external influences and to ensure its functionality and the safety of the user.
What materials are used for housings?
Various materials can be used for housings, depending on the area of application and desired appearance. Here are some common materials:
1. Plastic: Plastic housings are lightweight, inexpensive and can be produced in various shapes and colors. They are widely used in electronic devices such as cell phones, computers and household appliances.
2. Aluminum: Aluminum housings are robust, lightweight and offer good heat dissipation. They are often used in electronic devices such as laptops, tablets and audio devices.
3. Steel: Steel housings offer high strength and durability. They are often used in industrial applications such as machines and tools.
4. Glass: Glass enclosures are often used for design purposes as they offer a modern and elegant look. They are often used in smartphones and high-end electronic devices.
5. Wood: Wooden cabinets are often used for audio and musical instruments as they offer a natural and warm aesthetic. However, they require appropriate treatment to prevent moisture and environmental damage.
6. Metal alloys: Metal alloys such as stainless steel or titanium are often used for high-quality watches and jewelry, as they offer high strength, corrosion resistance and an elegant appearance.
It is important to note that the choice of housing material depends on the specific requirements of the product, such as impact resistance, heat dissipation or design aesthetics.
1. Plastic: Plastic housings are lightweight, inexpensive and can be produced in various shapes and colors. They are widely used in electronic devices such as cell phones, computers and household appliances.
2. Aluminum: Aluminum housings are robust, lightweight and offer good heat dissipation. They are often used in electronic devices such as laptops, tablets and audio devices.
3. Steel: Steel housings offer high strength and durability. They are often used in industrial applications such as machines and tools.
4. Glass: Glass enclosures are often used for design purposes as they offer a modern and elegant look. They are often used in smartphones and high-end electronic devices.
5. Wood: Wooden cabinets are often used for audio and musical instruments as they offer a natural and warm aesthetic. However, they require appropriate treatment to prevent moisture and environmental damage.
6. Metal alloys: Metal alloys such as stainless steel or titanium are often used for high-quality watches and jewelry, as they offer high strength, corrosion resistance and an elegant appearance.
It is important to note that the choice of housing material depends on the specific requirements of the product, such as impact resistance, heat dissipation or design aesthetics.
What attributes should a good housing have?
A good housing should have the following attributes:
1. Robustness: The housing should be stable and robust in order to effectively protect the contents. It should be impact- and scratch-resistant and also withstand adverse conditions such as dust, moisture or extreme temperatures.
2. Functionality: The case should have good functionality and facilitate access to the contents. This can be achieved with practical closures, handles, wheels or carrying straps. It should also offer enough space and compartments to organize and store the contents neatly.
3. Security: The housing should have adequate security measures to protect the contents from theft or unauthorized access. This can be achieved using robust latches, locks or security codes.
4. Lightweight: A good housing should be lightweight to facilitate transportation and handling. However, it should also be strong enough to adequately protect the contents.
5. Adaptability: The housing should be adaptable to the specific requirements and needs of the user. This can be achieved through interchangeable or customizable interior fittings, modular design or the ability to add accessories.
6. Aesthetics: Although not necessarily a functional attribute, the aesthetics of the housing play a role. A good case should be attractively designed and suit the user's personal taste. It can be available in different colors, shapes and materials.
7. Compatibility: The case should be compatible with the contents and provide sufficient space, holders or fixings to keep the contents safe and tidy. It should also offer compatibility with other devices or accessories if required.
8. Costs: A good housing should offer a reasonable price-performance ratio. It should provide the protection and functionality required for the specific use without being overly expensive.
These attributes can vary depending on the intended use of the enclosure, for example whether it is used to transport tools, electronic devices, medical instruments or other objects.
1. Robustness: The housing should be stable and robust in order to effectively protect the contents. It should be impact- and scratch-resistant and also withstand adverse conditions such as dust, moisture or extreme temperatures.
2. Functionality: The case should have good functionality and facilitate access to the contents. This can be achieved with practical closures, handles, wheels or carrying straps. It should also offer enough space and compartments to organize and store the contents neatly.
3. Security: The housing should have adequate security measures to protect the contents from theft or unauthorized access. This can be achieved using robust latches, locks or security codes.
4. Lightweight: A good housing should be lightweight to facilitate transportation and handling. However, it should also be strong enough to adequately protect the contents.
5. Adaptability: The housing should be adaptable to the specific requirements and needs of the user. This can be achieved through interchangeable or customizable interior fittings, modular design or the ability to add accessories.
6. Aesthetics: Although not necessarily a functional attribute, the aesthetics of the housing play a role. A good case should be attractively designed and suit the user's personal taste. It can be available in different colors, shapes and materials.
7. Compatibility: The case should be compatible with the contents and provide sufficient space, holders or fixings to keep the contents safe and tidy. It should also offer compatibility with other devices or accessories if required.
8. Costs: A good housing should offer a reasonable price-performance ratio. It should provide the protection and functionality required for the specific use without being overly expensive.
These attributes can vary depending on the intended use of the enclosure, for example whether it is used to transport tools, electronic devices, medical instruments or other objects.
How are enclosures manufactured in the industry?
Enclosures in the industry are usually manufactured in a multi-stage process. Here are the basic steps:
1. Design: First, the housing is designed, either by an internal design team or by external engineers. The requirements for the housing and the desired functions are taken into account.
2. Material selection: The material is selected depending on the requirements of the housing. This can be plastic, metal or a combination of both.
3. Mold making: If the housing is made of plastic, a mold is required. A mold maker creates a mold or a series of molds into which the liquid plastic material is poured to obtain the desired shape of the housing.
4. Material processing: If the housing is made of metal, the material is machined. This can include cutting, bending, punching or welding metal sheets to obtain the desired shape of the housing.
5. Manufacture: The housing is then produced using the mold created or by using tools and machines. This includes the casting or injection molding of plastic into the molds or the joining and welding of the metal parts.
6. Surface finishing: After the housing has been manufactured, a surface finish may be required to protect the housing or to achieve an aesthetically pleasing appearance. This can include painting, coating or anodizing the housing.
7. Quality control: Before dispatch, the enclosures are subjected to a quality check to ensure that they meet the required standards. This can include visual inspections, dimensional checks or functional tests.
8. Assembly: If necessary, the housings are assembled with other components or electronic parts to produce the final product.
It is important to note that the manufacturing process may vary depending on the specific requirements of the enclosure and the industry.
1. Design: First, the housing is designed, either by an internal design team or by external engineers. The requirements for the housing and the desired functions are taken into account.
2. Material selection: The material is selected depending on the requirements of the housing. This can be plastic, metal or a combination of both.
3. Mold making: If the housing is made of plastic, a mold is required. A mold maker creates a mold or a series of molds into which the liquid plastic material is poured to obtain the desired shape of the housing.
4. Material processing: If the housing is made of metal, the material is machined. This can include cutting, bending, punching or welding metal sheets to obtain the desired shape of the housing.
5. Manufacture: The housing is then produced using the mold created or by using tools and machines. This includes the casting or injection molding of plastic into the molds or the joining and welding of the metal parts.
6. Surface finishing: After the housing has been manufactured, a surface finish may be required to protect the housing or to achieve an aesthetically pleasing appearance. This can include painting, coating or anodizing the housing.
7. Quality control: Before dispatch, the enclosures are subjected to a quality check to ensure that they meet the required standards. This can include visual inspections, dimensional checks or functional tests.
8. Assembly: If necessary, the housings are assembled with other components or electronic parts to produce the final product.
It is important to note that the manufacturing process may vary depending on the specific requirements of the enclosure and the industry.
What different types of enclosures are there?
There are different types of enclosures depending on the intended use and requirements. Here are some examples:
1. Desktop housing: These are the typical enclosures used for desktop computers. They provide space for the motherboard, hard disk, power supply unit and other components. These cases are available in various sizes, such as mini-tower, mid-tower or full-tower.
2. Server housing: These enclosures are specially designed for use in servers. They generally offer more space for hard disks and often have better cooling to meet the high demands of server operation.
3. HTPC housing: These housings are specially developed for home theater PCs and are designed to fit into the living room ambience. They are usually smaller and often have a chic design.
4. Mini PC housing: These enclosures are particularly compact and are often used for small, space-saving PCs. They are ideal for office work or as media streaming devices.
5. Gaming case: These cases are specially designed for gaming PCs and often offer additional features such as better cooling, space for larger graphics cards and better cable management.
6. Rack mount enclosure: These enclosures are often used in data centers or professional server environments. They can be mounted in standard 19-inch racks and offer space for several servers.
7. Embedded housing: These enclosures are used to protect and mount small embedded systems, such as industrial PCs or IoT devices. They are often robust and impact-resistant.
These are just a few examples of different types of enclosures. Depending on the requirements and intended use, there are many other variants and special enclosures.
1. Desktop housing: These are the typical enclosures used for desktop computers. They provide space for the motherboard, hard disk, power supply unit and other components. These cases are available in various sizes, such as mini-tower, mid-tower or full-tower.
2. Server housing: These enclosures are specially designed for use in servers. They generally offer more space for hard disks and often have better cooling to meet the high demands of server operation.
3. HTPC housing: These housings are specially developed for home theater PCs and are designed to fit into the living room ambience. They are usually smaller and often have a chic design.
4. Mini PC housing: These enclosures are particularly compact and are often used for small, space-saving PCs. They are ideal for office work or as media streaming devices.
5. Gaming case: These cases are specially designed for gaming PCs and often offer additional features such as better cooling, space for larger graphics cards and better cable management.
6. Rack mount enclosure: These enclosures are often used in data centers or professional server environments. They can be mounted in standard 19-inch racks and offer space for several servers.
7. Embedded housing: These enclosures are used to protect and mount small embedded systems, such as industrial PCs or IoT devices. They are often robust and impact-resistant.
These are just a few examples of different types of enclosures. Depending on the requirements and intended use, there are many other variants and special enclosures.
What role does the housing play in electronic devices?
The housing plays several important roles in electronic devices:
1. Protection: The housing protects the internal components of the device from external influences such as dust, dirt, moisture, mechanical damage and electromagnetic interference. It ensures that the device works safely and reliably even under adverse conditions.
2. Heat dissipation: Electronic devices often generate heat, especially when they are used intensively. The housing serves to dissipate heat and prevent the internal components from overheating. It can be equipped with heat sinks, fans or other heat dissipation methods to ensure an optimum temperature.
3. Ergonomics: The housing influences the user-friendliness of the device. It can determine the size, shape and arrangement of the control elements to enable convenient and intuitive operation. A well-designed housing helps to ensure that the device is comfortable to use and meets the needs of the user.
4. Aesthetics: The housing plays an important role in the aesthetic design of the device. It influences the appearance, design and user perception of the device. An attractive housing can make the device more attractive and increase its marketability.
5. Assembly and protection of components: The housing provides a structural basis for mounting and protecting the electronic components. It enables the components to be properly arranged and fastened to ensure stable and reliable operation of the device.
Overall, the housing plays a decisive role in the functionality, safety, user-friendliness and aesthetics of electronic devices.
1. Protection: The housing protects the internal components of the device from external influences such as dust, dirt, moisture, mechanical damage and electromagnetic interference. It ensures that the device works safely and reliably even under adverse conditions.
2. Heat dissipation: Electronic devices often generate heat, especially when they are used intensively. The housing serves to dissipate heat and prevent the internal components from overheating. It can be equipped with heat sinks, fans or other heat dissipation methods to ensure an optimum temperature.
3. Ergonomics: The housing influences the user-friendliness of the device. It can determine the size, shape and arrangement of the control elements to enable convenient and intuitive operation. A well-designed housing helps to ensure that the device is comfortable to use and meets the needs of the user.
4. Aesthetics: The housing plays an important role in the aesthetic design of the device. It influences the appearance, design and user perception of the device. An attractive housing can make the device more attractive and increase its marketability.
5. Assembly and protection of components: The housing provides a structural basis for mounting and protecting the electronic components. It enables the components to be properly arranged and fastened to ensure stable and reliable operation of the device.
Overall, the housing plays a decisive role in the functionality, safety, user-friendliness and aesthetics of electronic devices.
How can an enclosure affect the performance or function of a device?
An enclosure can affect the performance or function of a device in various ways:
1. Heat dissipation: The housing can influence the heat dissipation of the device. If the housing is not sufficiently ventilated or is not made of a suitable material, this can cause the device to overheat and impair its performance.
2. Protection against external influences: The housing can protect the device from external influences such as dust, moisture or impact. A robust housing can extend the service life of the device and ensure that it functions properly.
3. Electromagnetic shielding: An enclosure can protect the device from electromagnetic interference by providing shielding against electromagnetic interference. This means that the performance of the device is not affected by external electromagnetic fields.
4. Ergonomics: The housing can affect the user-friendliness and operability of the device. A well-designed housing can improve comfort and handling and thus increase the performance of the device.
5. space and connections: The housing can limit the available space inside the device and thus influence the type and number of components that can be installed in the device. In addition, the housing can determine the connections and interfaces that are available for connecting to other devices or networks.
Overall, the housing of a device can have a significant impact on its performance and function. It is important to choose an enclosure that meets the requirements of the device and enables optimum performance.
1. Heat dissipation: The housing can influence the heat dissipation of the device. If the housing is not sufficiently ventilated or is not made of a suitable material, this can cause the device to overheat and impair its performance.
2. Protection against external influences: The housing can protect the device from external influences such as dust, moisture or impact. A robust housing can extend the service life of the device and ensure that it functions properly.
3. Electromagnetic shielding: An enclosure can protect the device from electromagnetic interference by providing shielding against electromagnetic interference. This means that the performance of the device is not affected by external electromagnetic fields.
4. Ergonomics: The housing can affect the user-friendliness and operability of the device. A well-designed housing can improve comfort and handling and thus increase the performance of the device.
5. space and connections: The housing can limit the available space inside the device and thus influence the type and number of components that can be installed in the device. In addition, the housing can determine the connections and interfaces that are available for connecting to other devices or networks.
Overall, the housing of a device can have a significant impact on its performance and function. It is important to choose an enclosure that meets the requirements of the device and enables optimum performance.
What are the current trends or innovations in enclosure design?
There are currently several trends and innovations in the field of housing design:
1. Minimalist design: Minimalism is a trend that is gaining ground in many areas of design. Enclosures are becoming slimmer and simpler, with clear lines and a reduced number of elements.
2. Compact housing: With the increasing popularity of Mini-ITX motherboards and powerful components in smaller form factors, compact enclosures are becoming more and more popular. They offer a space-saving solution and are often equipped with intelligent cable management and effective cooling.
3. Transparent housing: Enclosures with transparent side panels, often made of tempered glass, allow a view of the internal components and enable individual lighting and presentation of the hardware.
4. RGB lighting: The integration of RGB lighting is another trend in enclosure design. This allows users to customize the color and lighting of their enclosures to create a personal aesthetic.
5. Modular design: Some cases now offer a modular design in which components such as hard disk cages, fans or radiators can be easily replaced or positioned. This enables flexible adaptation to individual requirements and also facilitates the installation of components.
6. Fan control: Another innovation is the integration of intelligent fan controls, which make it possible to adjust the fan speed and cooling efficiency. Some enclosures are even equipped with fans that automatically adjust to the temperature.
7. Silence: Enclosures that have been specially developed for a low-noise operating environment are becoming increasingly important. These enclosures feature sound-absorbing materials, vibration damping and special fans to minimize noise.
8. Sustainability: A growing trend is the integration of sustainable materials and concepts in housing designs. These include recycled plastics, reusable or biodegradable packaging and energy-efficient construction methods.
These trends and innovations in case design help to ensure that computer cases are not only functional, but also aesthetically pleasing and meet the individual requirements of users.
1. Minimalist design: Minimalism is a trend that is gaining ground in many areas of design. Enclosures are becoming slimmer and simpler, with clear lines and a reduced number of elements.
2. Compact housing: With the increasing popularity of Mini-ITX motherboards and powerful components in smaller form factors, compact enclosures are becoming more and more popular. They offer a space-saving solution and are often equipped with intelligent cable management and effective cooling.
3. Transparent housing: Enclosures with transparent side panels, often made of tempered glass, allow a view of the internal components and enable individual lighting and presentation of the hardware.
4. RGB lighting: The integration of RGB lighting is another trend in enclosure design. This allows users to customize the color and lighting of their enclosures to create a personal aesthetic.
5. Modular design: Some cases now offer a modular design in which components such as hard disk cages, fans or radiators can be easily replaced or positioned. This enables flexible adaptation to individual requirements and also facilitates the installation of components.
6. Fan control: Another innovation is the integration of intelligent fan controls, which make it possible to adjust the fan speed and cooling efficiency. Some enclosures are even equipped with fans that automatically adjust to the temperature.
7. Silence: Enclosures that have been specially developed for a low-noise operating environment are becoming increasingly important. These enclosures feature sound-absorbing materials, vibration damping and special fans to minimize noise.
8. Sustainability: A growing trend is the integration of sustainable materials and concepts in housing designs. These include recycled plastics, reusable or biodegradable packaging and energy-efficient construction methods.
These trends and innovations in case design help to ensure that computer cases are not only functional, but also aesthetically pleasing and meet the individual requirements of users.