CN216084330U - Control structure for testing solid state disk - Google Patents

Abstract

The utility model relates to a control structure for testing a solid state disk, which comprises a shell, an X86 mainboard, a radiator and a cooling fan, wherein the shell is provided with a shell body; a plurality of external butt joint slots are formed in one side of the shell; one end of the shell is provided with a heat dissipation port; the X86 main board is vertically arranged in the shell; an X86 processor and a memory bank are arranged on one side of the X86 mainboard, and a plurality of board-to-board connectors correspondingly arranged with external butt joint slots are arranged on the other side of the X86 mainboard; the radiator is arranged on the X86 mainboard and is attached to the X86 processor; the heat dissipation fan is arranged in the shell and is positioned at the heat dissipation port; according to the utility model, through adopting the board-to-board connector, the X86 mainboard has a compact structure, unnecessary interfaces in the field of testing redundant solid state disks are removed, and the interfaces required by testing the solid state disks are maximally expanded, so that the capability of simultaneously testing a plurality of solid state disks by one X86 mainboard can be realized.

Description

Control structure for testing solid state disk

Technical Field

The utility model relates to the field of solid state disk testing, in particular to a control structure for solid state disk testing.

Background

The high-temperature aging test equipment is a high-temperature and severe environment test equipment which is simulated aiming at high-performance electronic products, is important experimental equipment for improving the stability and the reliability of products, is an important production process for improving the quality and the competitiveness of products of various production enterprises, and is widely applied to the fields of power electronics, computers, communication, biological pharmacy and the like.

At present, the solid state disk test adopts standard ATX or MiniATX and other mainboard structures, although ATX or MiniATX and other mainboards are provided with a plurality of interfaces, most of requirements can be met, the size of the mainboard is large, and a plurality of interfaces are designed to be unavailable in the solid state disk test, so that the waste of volume and space is caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide a control structure for testing a solid state disk.

In order to achieve the purpose, the utility model adopts the technical scheme that: a control structure for testing a solid state disk comprises a shell, an X86 mainboard, a radiator and a radiating fan;

a plurality of external butt joint slots are formed in one side of the shell; one end of the shell is provided with a heat dissipation port;

the X86 main board is vertically arranged in the shell; an X86 processor and a memory bank are arranged on one side of the X86 mainboard, and a plurality of board-to-board connectors correspondingly arranged with external butt joint slots are arranged on the other side of the X86 mainboard;

the radiator is arranged on the X86 mainboard and is attached to the X86 processor;

the heat radiation fan is arranged in the shell and is positioned at the heat radiation opening.

Preferably, four connecting columns are connected to the X86 main board in a threaded manner; four corners of the radiator are respectively arranged on the four connecting columns in a sliding manner; and springs which enable the radiator to be tightly attached to the X86 processor are sleeved on the four connecting columns.

Preferably, the cooling fan is an exhaust fan.

Preferably, the fins of the heat sink are disposed in parallel along the air suction direction of the heat dissipation fan.

Preferably, the heat dissipation fan is provided in plurality and is disposed vertically, and the total height thereof is greater than the height of the heat dissipation fan.

Preferably, the shell is of a stepped structure; the X86 mainboard, radiator fan set up the one end that the casing is thicker.

Preferably, the housing is provided with ventilation openings in a grid pattern on both sides thereof.

Due to the application of the technical scheme, compared with the prior art, the utility model has the following advantages:

1. according to the utility model, by adopting the board-to-board connector, the X86 mainboard has a compact structure, unnecessary interfaces in the field of testing redundant solid state disks are removed, and the interfaces required by testing the solid state disks are maximally expanded, so that the capability of simultaneously testing a plurality of solid state disks by one X86 mainboard can be realized;

2. the utility model adopts an air suction type heat dissipation mode, and has better heat dissipation effect compared with the traditional air blowing type heat dissipation mode.

Drawings

The technical scheme of the utility model is further explained by combining the accompanying drawings as follows:

FIG. 1 is a schematic diagram of an outer side structure of a control structure for testing a solid state disk according to the present invention;

FIG. 2 is a schematic diagram of an inner side structure of the control structure for testing the solid state disk according to the present invention;

FIG. 3 is a schematic diagram of a partial structure of a control structure for testing a solid state disk according to the present invention;

FIG. 4 is an end view of the X86 main plate of the present invention;

fig. 5 is a schematic structural diagram of an X86 motherboard in the present invention.

Wherein: 1. a housing; 11. an external docking slot; 12. a heat dissipation port; 13. a vent; 2. an X86 motherboard; 21. an X86 processor; 22. a memory bank; 23. a board-to-board connector; 3. a heat sink; 4. a heat radiation fan; 5. connecting columns; 6. a spring.

Detailed Description

The utility model is described in further detail below with reference to the figures and the embodiments.

Fig. 1 to 5 show a control structure for testing a solid state disk according to the present invention, which includes a housing 1, an X86 motherboard 2, a heat sink 3, and a heat dissipation fan 4; one side of the shell 1 is provided with four external butt joint slots 11; one end of the shell 1 is provided with a heat dissipation port 12; the X86 main board 2 is vertically arranged in the shell 1; one side of the X86 mainboard 2 is provided with an X86 processor 21 and a memory bank 22, and the other side is provided with four board-to-board connectors 23 correspondingly arranged with the external butt joint slot 11; the radiator 3 is arranged on the X86 mainboard 2 and is attached to the X86 processor 21; the heat dissipation fan 4 is arranged in the shell 1 and is positioned at the heat dissipation port 12; by adopting the board-to-board connector 23, the utility model not only enables the X86 mainboard 2 to have a compact structure, removes unnecessary interfaces in the field of testing of redundant solid state disks, but also maximizes the expansion of the interfaces required by the testing of the solid state disks, thereby realizing the capability of simultaneously testing a plurality of solid state disks by one X86 mainboard 2.

Further, four connecting columns 5 are connected to the X86 main board 2 in a threaded manner; four corners of the radiator 3 are respectively arranged on the four connecting columns 5 in a sliding manner; the four connecting columns 5 are all sleeved with springs 6 which enable the heat radiator 3 to be tightly attached to the X86 processor 21; the utility model can lead the radiator 3 to be tightly attached to the X86 processor 21 through the spring 6, thereby further improving the heat radiation effect.

Further, the cooling fan 4 is an exhaust fan; the utility model adopts an air suction type heat dissipation mode, and has better heat dissipation effect compared with the traditional air blowing type heat dissipation mode.

Furthermore, the fins on the heat sink 3 are arranged in parallel along the air suction direction of the heat dissipation fan 4, so that the heat dissipation effect is further improved.

Further, the three heat dissipation fans 4 are vertically arranged, and the total height of the three heat dissipation fans is greater than that of the heat dissipation fan 4, so that the heat dissipation effect is further improved.

Further, the shell 1 is of a stepped structure; the X86 mainboard 2, the radiator 3 and the radiator fan 4 are arranged at one thicker end of the shell 1, so that the structure is more compact.

Furthermore, both sides of the housing 1 are provided with grid-shaped ventilation openings 13, so that the sufficient air flow and air pressure of the heat dissipation fan 4 are ensured, and the heat dissipation effect is further improved.

The above is only a specific application example of the present invention, and the protection scope of the present invention is not limited in any way. All the technical solutions formed by equivalent transformation or equivalent replacement fall within the protection scope of the present invention.

Claims (7)

1. The utility model provides a control structure for solid state hard drives test which characterized in that: comprises a shell, an X86 mainboard, a radiator and a radiating fan;

a plurality of external butt joint slots are formed in one side of the shell; one end of the shell is provided with a heat dissipation port;

the X86 main board is vertically arranged in the shell; an X86 processor and a memory bank are arranged on one side of the X86 mainboard, and a plurality of board-to-board connectors correspondingly arranged with external butt joint slots are arranged on the other side of the X86 mainboard;

the radiator is arranged on the X86 mainboard and is attached to the X86 processor;

the heat radiation fan is arranged in the shell and is positioned at the heat radiation opening.

2. The control structure for testing the solid state disk according to claim 1, wherein: the X86 main board is in threaded connection with four connecting columns; four corners of the radiator are respectively arranged on the four connecting columns in a sliding manner; and springs which enable the radiator to be tightly attached to the X86 processor are sleeved on the four connecting columns.

3. The control structure for testing the solid state disk according to claim 2, wherein: the cooling fan is an exhaust fan.

4. The control structure for testing the solid state disk according to claim 3, wherein: the fins on the radiator are arranged in parallel along the air suction direction of the radiating fan.

5. The control structure for testing the solid state disk according to claim 4, wherein: the heat radiation fans are arranged in a plurality of vertical positions, and the total height of the heat radiation fans is larger than that of the heat radiation fans.

6. The control structure for testing the solid state disk according to any one of claims 1 to 5, wherein: the shell is of a stepped structure; the X86 mainboard, radiator fan set up the one end that the casing is thicker.

7. The control structure for testing the solid state disk according to claim 6, wherein: both sides of the shell are provided with latticed ventilation openings.

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