CN205491590U - A digital equipment protection device for helping heat dissipation - Google Patents

Abstract

The utility model relates to a digital equipment protection device for helping heat dissipation, a unit (3) with high heat conductivity coefficient is arranged between a digital equipment protection device body (2) and a digital equipment (1); the digital equipment protection device body (2) is mutually combined with the unit (3) with high heat conductivity coefficient, and the unit (3) with high heat conductivity coefficient is provided with an internal absorption heat conduction area (32), an external heat dissipation area (31) and an opening part (33) for internal and external conversion; an external heat insulation area (21) is arranged at the external hand-held part of the digital equipment protection device body (2), and corresponds to a digital equipment heating area; an inner heat insulation area (22) is arranged at the non-hand-held part. The utility model discloses transmit the heat source of digital equipment to outside high heat conduction material through inside high heat conduction material and strengthen the heat dissipation to transmit through thermal convection and heat radiation, among the effectual conduction of heat energy and the radiation ambient air, improve the radiating efficiency.

Description

A digital equipment protection device for helping heat dissipation

technical field

The utility model relates to a product protection device, in particular to a digital equipment protection device for helping heat dissipation.

Background technique

At present, most of the heat dissipation technologies that exist today exist and are used in digital devices to disperse the high heat generated by components such as CPUs and computing devices during operation. The heat source is dispersed to a larger area by contacting the device with a material with a high heat transfer coefficient. , to avoid the phenomenon of thermal crash or burning caused by excessive local heating, such as: CPU + graphite patch, image computing chip + nano-carbon material patch and other combinations.

This widely used technology exists and is applied inside the digital device, and there is no air flow inside the device, so the application of heat convection with the air cannot be achieved, and although this application disperses the heat source to various parts of the digital device, it will make the digital device The temperature of the surface of the device rises, resulting in a decrease in user experience, a decrease in the performance of the digital device, an increase in energy consumption, and even safety concerns (burning, failure).

Although a digital device protection device made of metal can be used, the communication signal of the digital device will be affected and shielded due to the large covering area, and the protection device made of metal is too large, which will affect the signal more obviously .

Moreover, the metal material has higher heat dissipation performance than the protection device made of general plastic material, but it will make the digital device evenly heat up, causing users to have doubts about safety and affecting the user experience.

Utility model content

The utility model designs a digital equipment protection device that helps heat dissipation, and the thorny problems it solves are: (1) the heat dissipation effect of the digital device itself is limited, and is limited by appearance factors and size; (2) a large area is made of metal materials (3) Although the protection device made of metal material has better heat dissipation performance than the protection device made of general plastic material, it will make the whole digital device evenly hot. Make users have doubts about safety and affect the perception of use.

In order to solve the above-mentioned technical problems, the utility model adopts the following scheme:

A digital device protection device for helping heat dissipation, comprising a digital device protection device body (2), characterized in that a unit (3) with a high thermal conductivity is arranged between the digital device protection device body (2) and the digital device (1) ); the digital equipment protection device body (2) is combined with the unit (3) with high thermal conductivity, and the unit (3) with high thermal conductivity is provided with an internal heat-absorbing heat conduction unit in contact with the digital equipment (1). area (32), external heat dissipation area (31) and an opening part (33) for internal and external conversion; the external handheld part of the digital equipment protection device body (2) is provided with an external heat insulation area (21), which corresponds to a digital equipment Heating area; an inner heat insulation area (22) is provided at the non-handheld part.

Further, a heat dissipation port is opened on the body (2) of the digital equipment protection device for the heat dissipation of the unit (3) with high thermal conductivity.

Further, the area below or above the internal heat insulation area (22) corresponds to the external heat dissipation area (31), and the area below or above the internal heat absorption and heat conduction area (32) corresponds to the external heat insulation area (21).

Further, the materials of the external heat dissipation area (31) and the internal absorption heat conduction area (32) are high thermal conductivity materials.

Further, the material of the outer heat insulation area (21) and the inner heat insulation area (22) is plastic.

Compared with common protective devices, the protective device for digital equipment that helps to dissipate heat has the following beneficial effects:

(1) The utility model conducts the heat source of the digital device through the internal high thermal conductivity material to the external high thermal conductivity material to enhance heat dissipation, and through heat convection and heat radiation, the heat energy is effectively conducted and radiated to the ambient air, Improve cooling efficiency.

(2) The utility model achieves the characteristics of not affecting the signal of the product through the heat insulation material (plastic material), and through the way of adding a high thermal conductivity material, the signal maintenance and heat dissipation performance coexist; further, it can be designed through the digital device itself According to the location of the antenna and signal generation, corresponding avoidance can be made, and then different heat dissipation schemes can be made according to the digital equipment to be protected.

(3) The utility model achieves the characteristics of isolating the heating area of the protected digital equipment through the heat insulation material (plastic material), so that the user will not directly touch the heating area, avoiding the safety concerns caused by the user touching the heat source, and through The way of adding high thermal conductivity material makes the heat insulation performance and heat dissipation performance coexist. Further, through clever design, the heat dissipation area can be placed in an area that users will not touch when using digital devices normally, so that heat insulation can also be achieved at the same time. Conducting the heat source to the enhanced heat dissipation area has the effect of coexistence of heat insulation, heat dissipation, protection, and communication stability.

Description of drawings

Figure 1: The schematic diagram of the back side of the protection device for digital equipment that helps heat dissipation of the utility model;

Figure 2: The front schematic diagram of the protection device for digital equipment that helps to dissipate heat in the utility model;

Figure 3: Schematic diagram of the structure of the first embodiment of the digital equipment protection device of the utility model that helps to dissipate heat;

Figure 4: Structural schematic diagram of the second embodiment of the digital equipment protection device of the utility model to help heat dissipation;

Figure 5: Schematic diagram of the structure of the third embodiment of the digital equipment protection device of the utility model that helps heat dissipation;

Explanation of reference signs:

31—external heat dissipation area; 2—digital equipment protection device body; 21—external heat insulation area; 22—inner heat insulation area; 3—unit with high thermal conductivity; 32—inner absorption heat conduction area; 33—internal and external conversion opening parts.

detailed description

Below in conjunction with Fig. 1 to Fig. 5, the utility model is further described:

As shown in Figures 1 to 3, a digital equipment protection device that helps to dissipate heat includes a digital equipment protection device body 2, and a unit 3 with a high thermal conductivity is provided between the digital equipment protection device body 2 and the digital equipment; The front side of the equipment protection device body 2 in contact with the unit 3 with high thermal conductivity is provided with an inner heat insulation area 22 and an inner absorption heat conduction area 32, and the back side of the digital equipment protection device body 2 that is not in contact with the digital equipment is provided with an outer surface area. The heat dissipation area 31 and the external heat insulation area 21, the internal absorption and heat conduction area 32 correspond to the heating area of digital equipment, and the external heat insulation area 21 corresponds to the user contact area; on the body 2 of the digital equipment protection device, there is a cooling port for internal and external conversion. The opening member 33 allows the heat of the unit 3 having a high thermal conductivity to be taken out.

Below or above the inner heat insulation area 22 corresponds to the external heat dissipation area 31 , and below or above the internal heat absorption and heat conduction area 32 corresponds to the external heat insulation area 21 .

The materials of the external heat dissipation area 31 and the internal absorption heat conduction area 32 are high thermal conductivity materials.

The inner heat insulation area 22 and the outer heat insulation area 21 are made of plastic.

As shown in Fig. 3, the utility model is the first embodiment of the protection device for digital equipment that helps to dissipate heat. The unit 3 with high thermal conductivity includes an internal heat-absorbing area 32 , an external heat-dissipating area 31 , and an opening part 33 for internal and external conversion. The internal heat-absorbing and heat-conducting area 32 is connected to the external heat-dissipating area 31 through the opening part 33 for internal and external conversion. The inner absorption and heat conduction area 32 is sandwiched between the digital device 1 and the outer heat insulation area 21 . There is a cooling port on the body 2 of the digital device protection device, the opening part 33 for internal and external conversion is located in the cooling port, part of the external cooling area 31 is located in the air, and the other part is in contact with the digital device 1 . The inner heat insulation area 22 is located in the cavity formed by the two parts of the outer heat dissipation area 31 . Finally, the inner heat-absorbing and heat-conducting area 32 is in contact with the digital device 1 , while the outer heat-dissipating area 31 is exposed to the air.

As shown in Figure 4, the utility model is the second embodiment of the protection device for digital equipment that helps to dissipate heat. Compared with the embodiment in Fig. 3, the biggest difference of the second embodiment is that: the external heat dissipation area 31 is all located in the air, and the internal heat insulation area 22 is located in the cavity between the external heat dissipation area 31 and the digital device 1 .

As shown in Fig. 5, the third embodiment of the protection device for digital equipment that helps heat dissipation of the present invention. In this embodiment, the opening part 33 for internal and external conversion is located at the uppermost front of the digital device 1 , while the opening part 33 for internal and external conversion in the above two embodiments is located at the back of the digital device 1 .

Compared with common protective devices, the protective device for digital equipment that helps to dissipate heat has the following beneficial effects:

(1) The utility model conducts the heat source of the digital device through the internal high thermal conductivity material to the external high thermal conductivity material to enhance heat dissipation, and through heat convection and heat radiation, the heat energy is effectively conducted and radiated to the ambient air, Improve cooling efficiency.

(2) The utility model achieves the characteristics of not affecting the signal of the product through the heat insulation material (plastic material), and through the way of adding a high thermal conductivity material, the signal maintenance and heat dissipation performance coexist; further, it can be designed through the digital device itself According to the location of the antenna and signal generation, corresponding avoidance can be made, and then different heat dissipation schemes can be made according to the digital equipment to be protected.

(3) The utility model achieves the characteristics of isolating the heating area of the protected digital equipment through the heat insulation material (plastic material), so that the user will not directly touch the heating area, avoiding the safety concerns caused by the user touching the heat source, and through The way of adding high thermal conductivity material makes the heat insulation performance and heat dissipation performance coexist. Further, through clever design, the heat dissipation area can be placed in an area that users will not touch when using digital devices normally, so that heat insulation can also be achieved at the same time. Conducting the heat source to the enhanced heat dissipation area has the effect of coexistence of heat insulation, heat dissipation, protection, and communication stability.

The utility model has been exemplarily described above in conjunction with the accompanying drawings. Obviously, the realization of the utility model is not limited by the above-mentioned method, as long as various improvements of the method concept and technical solutions of the utility model are adopted, or the utility model is not improved. Directly applying the conception and technical solutions of the utility model to other occasions is within the protection scope of the utility model.

Claims (5)

1. A digital device protection device for helping heat dissipation, including a digital device protection device body (2), characterized in that: a unit with high thermal conductivity is arranged between the digital device protection device body (2) and the digital device (1) (3); the digital equipment protection device body (2) is combined with the unit (3) with high thermal conductivity, and the unit (3) with high thermal conductivity is provided with an internal absorption heat conduction area (32), and an external The heat dissipation area (31) and the opening part (33) for internal and external conversion; the external handheld part of the digital equipment protection device body (2) is provided with an external heat insulation area (21), which corresponds to the digital equipment heating area; The position is provided with an inner heat insulation area (22). 2. According to claim 1, the protection device for digital equipment that helps to dissipate heat is characterized in that: there are vents on the body (2) of the protection device for digital equipment to allow the heat of the unit (3) with high thermal conductivity to be exported. 3. According to claim 2, the protection device for digital equipment that helps to dissipate heat is characterized in that: the area below or above the internal heat insulation area (22) corresponds to the external heat dissipation area (31), and the area below or above the internal heat-absorbing area (32) The top corresponds to the external heat insulation area (21). 4. According to claim 1, 2 or 3, the protection device for digital equipment that helps to dissipate heat, is characterized in that: the materials of the external heat dissipation area (31) and the internal absorption heat conduction area (32) are high thermal conductivity materials. 5. The digital device protection device for helping heat dissipation according to claim 4, characterized in that: the material of the outer heat insulation area (21) and the inner heat insulation area (22) is plastic.