CN221551501U - Solid state hard disk heat sink - Google Patents

Abstract

The utility model discloses a solid state hard disk heat sink. The solid state hard disk heat sink comprises: a solid state hard disk heat sink mechanism, the solid state hard disk heat sink mechanism is provided with a base, a solid state hard disk body is fixedly installed inside the base, an aluminum alloy plate is provided at the upper end of the solid state hard disk body, a heat dissipation slot is provided at the upper end of the aluminum alloy plate, a heat conduction pipe is provided inside the heat dissipation slot, a heat dissipation slot fan is provided at one end of the heat dissipation slot, the solid state hard disk is in direct contact with the aluminum alloy plate, the aluminum alloy plate can effectively absorb the heat generated by the solid state hard disk, and conduct it to the heat dissipation slot for heat dissipation, through the rotation of the heat dissipation fan, air can be introduced into the heat dissipation slot to discharge hot air, so that the radiator maintains a low temperature effect, and the heat conduction pipe can assist in absorbing the heat of the heat dissipation slot, thereby achieving heat dispersion and heat dissipation.

Description

Solid state hard disk heat sink

Technical Field

The utility model relates to the technical field of solid state hard disk radiators, in particular to a solid state hard disk radiator.

Background Art

SSD heat sink uses a heat sink to reduce the temperature of the SSD. SSDs will generate a certain amount of heat when running at high load, and excessive temperature may have a negative impact on its performance and lifespan. In order to maintain the stability and reliability of SSDs, heat sink technology is widely used in SSD design.

The prior art discloses a technical solution for a solid-state hard disk heat sink, in which the solid-state hard disk is installed on a thermally conductive base, a cooling fan is installed at a port on the solid-state hard disk, and the heat of the solid-state hard disk is dissipated through the thermally conductive base and the cooling fan.

In this technology, the solid-state drive is installed on a thermally conductive base. The air flow generated by the fan cannot cause the air in the thermally conductive base to flow. The flowing air force is blocked by the solid-state drive. The fan airflow of the radiator cannot dissipate the heat absorbed by the thermally conductive base, resulting in a relatively low heat dissipation effect of the thermally conductive base. Therefore, the heat dissipation effect of the solid-state drive radiator is defective.

Therefore, it is necessary to provide a solid state hard disk heat sink to solve the above technical problems.

Utility Model Content

In view of the above situation, in order to overcome the defects of the prior art, the utility model provides a solid state hard disk heat sink that can solve the heat conduction and heat dissipation effect of the fixed hard disk and can dissipate the heat absorbed by the thermal conductive material.

In order to achieve the above purpose, the technical solution adopted by the utility model is as follows:

A solid state hard disk heat sink comprises: a solid state hard disk heat dissipation mechanism, wherein the solid state hard disk heat dissipation mechanism is provided with a base, a solid state hard disk body is fixedly installed inside the base, an aluminum alloy plate is provided at the upper end of the solid state hard disk body, a heat dissipation slot is provided at the upper end of the aluminum alloy plate, a heat conduction pipe is provided inside the heat dissipation slot, and a heat sink fan is provided at one end of the heat dissipation slot.

Preferably, the base is provided with a fixing bolt and is mounted on one end of the heat dissipation slot, and a motor is provided inside the radiator fan, and a fan blade is fixedly mounted on one end of the motor.

Preferably, a filter screen is provided at one end of the radiator fan, and an air inlet is provided at one end of the radiator fan.

Preferably, a first heat sink is provided at the upper end of the solid state drive body and is mounted on the lower end of the aluminum alloy plate, and a second heat sink is provided at the lower end of the solid state drive body and is mounted on the upper end of the base.

Preferably, an air outlet duct is provided at one end of the heat dissipation slot, a fixing plate is fixedly installed at one end of the air outlet duct, one end of the fixing plate is fixedly installed at one end of a box heat dissipation fan, and an air outlet is provided at one end of the box heat dissipation fan.

Preferably, a rotating motor is fixedly installed inside the box heat dissipation fan, and a wind wheel blade is fixedly installed at one end of the rotating motor.

Compared with the prior art, the utility model has the following beneficial effects:

(1) The utility model can achieve the effect of absorbing and dispersing the heat of the solid-state hard disk and transferring the absorbed heat to other locations to drive the external air to flow and blow it out for heat dissipation by arranging heat dissipation slots, aluminum alloy plates, heat pipes, and radiator fans. Compared with the existing solid-state hard disk radiators, the solid-state hard disk is in direct contact with the aluminum alloy plate, and the aluminum alloy plate can effectively absorb the heat generated by the solid-state hard disk and transfer it to the heat dissipation slots for heat dissipation. Through the rotation of the radiator fan, air can be introduced into the heat dissipation slots to discharge the hot air, so that the radiator maintains a low temperature effect. The heat pipe can assist in absorbing the heat of the heat dissipation slots, thereby achieving heat dispersion and heat dissipation.

(2) The utility model can effectively increase the contact area of heat transfer and improve the heat conduction efficiency by setting the first heat sink and the second heat sink, so that the heat generated by the solid state drive can be transferred to the aluminum alloy plate through the heat sink more quickly.

(3) The utility model sets a box cooling fan and an air outlet duct, so that the cooling fan can actively discharge hot air from the inside of the box and take away the heat generated by the solid state drive. This can effectively reduce the rise in the air temperature inside the box, improve the heat dissipation efficiency, keep the solid state drive running at a lower operating temperature, help keep the air environment inside the box relatively cool, and reduce the re-absorption of heat by the solid state drive.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the structure of a solid state drive heat sink provided by the utility model;

FIG2 is a cross-sectional view of a solid state hard disk heat sink provided by the present invention;

FIG3 is a schematic structural diagram of a solid state hard disk heat sink provided by the present invention;

FIG4 is a schematic structural diagram of a solid state hard disk heat sink provided by the present invention;

Among them, the names corresponding to the figure marks are: 100, heat dissipation mechanism; 102, solid state drive body; 103, aluminum alloy plate; 104, heat dissipation slot; 105, base; 106, radiator fan; 107, fixing bolt; 108, heat pipe; 109, filter; 110, fan blade; 111, motor; 112, air inlet; 113, first heat sink; 114, second heat sink; 115, box cooling fan; 116, rotating motor; 117, wind wheel blade; 118, air outlet; 119, fixing plate; 120, air outlet.

DETAILED DESCRIPTION

The present invention is further described below in conjunction with the accompanying drawings and embodiments. The present invention includes but is not limited to the following embodiments.

First embodiment:

As shown in FIG. 1 and FIG. 2 , the solid state hard disk heat sink provided by the present invention includes: a solid state hard disk heat dissipation mechanism 100 , which is a hardware device for reducing the temperature of the solid state hard disk. It is usually made of metal materials, such as aluminum alloy or copper, and has good thermal conductivity. The solid-state hard disk heat dissipation mechanism 100 is provided with a base 105. The solid-state hard disk heat dissipation mechanism 100 is installed inside the base 105. The solid-state hard disk body 102 is fixedly installed inside the base 105. The solid-state hard disk body 102 is placed inside the base 105. The two sides of the base 105 are connected to the heat dissipation slot 104 by screws. The solid-state hard disk body 102 will be clamped between the heat dissipation slot 104 and the base 105. An aluminum alloy plate 103 is provided at the upper end of the solid-state hard disk body 102. The aluminum alloy plate 103 is clamped and squeezed on the upper end of the solid-state hard disk body 102. A heat dissipation slot 104 is provided at the upper end of the aluminum alloy plate 103. The heat dissipation slot 104 is connected to the upper end of the aluminum alloy plate 103 by screws. The heat dissipation slot 104 and the aluminum alloy plate 103 are made of metal materials, such as aluminum alloy or copper, and have good thermal conductivity. They are used to absorb and disperse the heat generated by the solid-state hard disk. The heat dissipation slot 104 is provided with a heat conductive The heat pipe 108 is made of a highly efficient heat conduction element material. Common heat pipe 108 materials include copper, aluminum, nickel, etc. It can quickly transfer heat to other locations and dissipate it into the surrounding environment. The heat pipe 108 is installed in the heat dissipation slot 104 by inserting it. A heat sink fan 106 is provided at one end of the heat dissipation slot 104. The heat sink fan 106 is connected to one end of the heat dissipation slot 104 by screws. When the solid state drive body 102 is operating normally, a large amount of heat will be generated. The staff uses the aluminum alloy plate 103 and the heat dissipation slot 104 to absorb and disperse the heat generated by the solid state drive. The heat generated by the solid state drive body 102 can be quickly absorbed and transferred to other locations through the heat pipe 108, and dissipated into the surrounding air environment. Finally, the external air airflow generated by the radiator fan 106 flows into the heat dissipation slot 104, and the heat absorbed by the heat dissipation slot 104 is quickly dissipated from the upper end to the external air for heat dissipation.

By providing the heat dissipation slot 104, the aluminum alloy plate 103, the heat pipe 108, and the radiator fan 106, the heat of the solid state hard disk can be absorbed and dispersed, and the absorbed heat can be transferred to other locations to drive the external air to flow and blow it out to achieve the heat dissipation effect. Compared with the existing solid state hard disk radiator, the solid state hard disk is in direct contact with the aluminum alloy plate 103, and the aluminum alloy plate 103 can effectively absorb the heat generated by the solid state hard disk and transfer it to the heat dissipation slot 104 for heat dissipation. Through the rotation of the radiator fan 106, air can be introduced into the heat dissipation slot 104 to discharge the hot air, so that the radiator maintains a low temperature effect. The heat pipe 108 can assist in absorbing the heat of the heat dissipation slot 104, thereby achieving heat dispersion and heat dissipation.

Second embodiment:

As shown in Figures 1 and 2, the base 105 is provided with a fixing bolt 107 and is installed at one end of the heat dissipation slot 104. The fixing bolt 107 is tightened on the side of the base 105, and the base 105 and the side of the heat dissipation slot 104 are tightened and fixed together by the fixing bolt 107. At the same time, the solid state drive body 102 is squeezed and placed between the base 105 and the aluminum alloy plate 103 of the heat dissipation slot 104. The radiator fan 106 is provided with a motor 111 inside. The motor 111 is connected to the inside of the radiator fan 106 by screws. A fan blade 110 is fixedly installed at one end of the motor 111. The fan blade 110 is connected to one end of the motor 111 by bolts, and the power of the motor 111 is transmitted to the fan blade 110 for rotation.

Third embodiment:

As shown in Figures 1 and 2, a filter screen 109 is provided at one end of the radiator fan 106, and the filter screen 109 is connected to one end of the radiator fan 106 by screws. An air inlet 112 is provided at one end of the radiator fan 106, and the air inlet 112 is a ventilation slot opened at one end of the radiator fan 106.

Fourth embodiment:

As shown in Figures 1 and 2, a first heat sink 113 is provided at the upper end of the solid-state hard disk body 102 and is installed on the lower end of the aluminum alloy plate 103. The first heat sink 113 is tightly attached to the upper end of the solid-state hard disk body 102 and the lower end of the aluminum alloy plate 103. A second heat sink 114 is provided at the lower end of the solid-state hard disk body 102 and is installed on the upper end of the base 105. The second heat sink 114 is attached to the upper end of the base 105 at the lower end of the solid-state hard disk body 102. The heat sink is usually made of a material with good thermal conductivity, such as silica gel or graphite sheet. The heat sink is in close contact and attached to their surfaces to increase the contact area of heat transfer and improve the heat conduction efficiency, so that the heat generated by the solid-state hard disk is transferred to the aluminum alloy plate 103 through the heat sink more quickly.

By providing the first heat sink 113 and the second heat sink 114 , the contact area of heat transfer can be effectively increased, and the heat conduction efficiency can be improved, so that the heat generated by the solid state drive can be transferred to the aluminum alloy plate 103 through the heat sink more quickly.

Fifth embodiment:

As shown in Figures 1, 3 and 4, one end of the heat dissipation slot 104 is provided with an air outlet duct 118, and the air outlet duct 118 is connected to one end of the heat dissipation slot 104 by screws. One end of the air outlet duct 118 is fixedly installed with a fixing plate 119, and the fixing plate 119 is provided with a through hole, and one end of the air outlet duct 118 is inserted and connected inside the fixing plate 119, and one end of the fixing plate 119 is fixedly installed at one end of a box heat dissipation fan 115. The box heat dissipation fan 115 is installed at one end of the host box body, and can discharge the heat dissipated by the solid state hard disk into the external environment of the box, and can maintain the internal air environment temperature of the box to reduce the heat dissipation and retain it in the air environment around the solid state hard disk. One end of the fixing plate 119 is connected to one end of the box heat dissipation fan 115 by screws, and one end of the box heat dissipation fan 115 is provided with an air outlet 120. The air outlet 120 is opened in the box. There are ventilation slots at one end of the heat dissipation fan 115, and a rotating motor 116 is fixedly installed inside the box heat dissipation fan 115. The rotating motor 116 is connected to the inside of the box heat dissipation fan 115 by screws. A wind wheel blade 117 is fixedly installed at one end of the rotating motor 116, and the wind wheel blade 117 is connected to one end of the rotating motor 116 by bolts. When the heat dissipated by the solid-state hard disk radiator still remains in the air environment around the solid-state hard disk, the wind force discharged by the radiator fan 106 is not low enough, and the heat dissipation effect of the solid-state hard disk is relatively slow. Therefore, the box heat dissipation fan 115 can discharge the heat dissipated by the solid-state hard disk to the external environment of the box, which can maintain the internal air environment temperature of the box to reduce the heat dissipation heat retained in the air environment around the solid-state hard disk, and the heat absorbed by the heat dissipation slot 104 can be directly discharged out of the box through the air outlet pipe 118.

By setting the box cooling fan 115 and the air outlet duct 118, the box cooling fan 115 can actively discharge hot air from the inside of the box and take away the heat generated by the solid state hard disk. This can effectively reduce the rise in air temperature inside the box, improve heat dissipation efficiency, keep the solid state hard disk running at a lower operating temperature, help keep the air environment inside the box relatively cool, and reduce the re-absorption of heat to the solid state hard disk.

When in use, the installer firstly glues the first heat sink 113 tightly to the upper end of the solid state drive body 102 and the lower end of the aluminum alloy plate 103, and the second heat sink 114 is glued to the upper end of the base 105 at the lower end of the solid state drive body 102. Then, the solid state drive is placed inside the base 105. The solid state drive body 102 is placed inside the base 105, and the two sides of the base 105 are connected to the heat dissipation slot 104 with screws. The solid state drive body 102 will be clamped between the heat dissipation slot 104 and the base 105. The staff uses the aluminum alloy plate 103 and the heat dissipation slot 104 to absorb and disperse the heat generated by the solid state drive. The heat pipe 108 can quickly absorb the heat generated by the solid-state hard disk body 102 and transfer it to other locations, and dissipate it into the surrounding air environment, and finally blow it into the heat dissipation slot 104 through the external air flow generated by the radiator fan 106. The heat absorbed by the heat dissipation slot 104 is quickly dissipated from the upper end to the external air for heat dissipation. Therefore, the heat dissipated by the solid-state hard disk can be discharged to the external environment of the box through the box cooling fan 115, which can maintain the internal air environment temperature of the box to reduce the heat dissipation and retain it in the air environment around the solid-state hard disk. The heat absorbed by the heat dissipation slot 104 can be directly discharged out of the box through the air outlet pipe 118.

The above embodiment is only one of the preferred implementation modes of the present utility model and should not be used to limit the protection scope of the present utility model. Any changes or modifications that are made to the main design concept and spirit of the present utility model without any substantive significance, as long as the technical problems solved are still consistent with the present utility model, should be included in the protection scope of the present utility model.

Claims (6)

1. A solid state hard disk heat sink, characterized in that it comprises: a solid state hard disk heat dissipation mechanism (100), the solid state hard disk heat dissipation mechanism (100) is provided with a base (105), a solid state hard disk body (102) is fixedly installed inside the base (105), an aluminum alloy plate (103) is provided at the upper end of the solid state hard disk body (102), a heat dissipation slot (104) is provided at the upper end of the aluminum alloy plate (103), a heat dissipation slot (104) is provided inside the heat dissipation slot (104), and a heat dissipation fan (106) is provided at one end of the heat dissipation slot (104). 2. A solid state hard disk heat sink according to claim 1, characterized in that the base (105) is provided with a fixing bolt (107) and is installed at one end of the heat dissipation slot (104), and a motor (111) is provided inside the heat sink fan (106), and a fan blade (110) is fixedly installed at one end of the motor (111). 3. A solid state hard disk heat sink according to claim 1, characterized in that a filter screen (109) is provided at one end of the heat sink fan (106), and an air inlet (112) is provided at one end of the heat sink fan (106). 4. A solid-state hard disk heat sink according to claim 1, characterized in that a first heat sink (113) is provided at the upper end of the solid-state hard disk body (102) and is installed at the lower end of the aluminum alloy plate (103), and a second heat sink (114) is provided at the lower end of the solid-state hard disk body (102) and is installed at the upper end of the base (105). 5. A solid state hard disk heat sink according to claim 1, characterized in that an air outlet duct (118) is provided at one end of the heat dissipation slot (104), a fixing plate (119) is fixedly installed at one end of the air outlet duct (118), one end of the fixing plate (119) is fixedly installed at one end of a box heat dissipation fan (115), and an air outlet (120) is provided at one end of the box heat dissipation fan (115). 6. A solid state hard disk heat sink according to claim 5, characterized in that a rotating motor (116) is fixedly installed inside the box heat dissipation fan (115), and a wind wheel blade (117) is fixedly installed at one end of the rotating motor (116).