CN216249039U - Big data server capable of automatically powering off at high temperature - Google Patents

Abstract

The utility model discloses a high-temperature automatic power-off big data server which comprises a server shell, wherein the lower end of the server shell is fixedly connected with a base, four universal wheels are installed at the lower end of the base, a fan is installed on the side wall of the server shell, an opening and closing mechanism is arranged on the inner wall of the other end of the server shell, an L-shaped groove is formed in the base in a penetrating mode, the opening and closing mechanism comprises an L-shaped hollow block fixedly connected with the outer wall of the server shell, a piston is connected to the inner wall of the L-shaped hollow block in a sliding mode, a U-shaped block is fixedly connected to the upper end of the piston, and one end of the U-shaped block penetrates through the L-shaped hollow block and is connected with the inner wall of the U-shaped block in a sliding mode. According to the utility model, the big data server can be automatically disconnected through the heat conduction block, so that the internal circuit is prevented from being broken, and the big data server can be conveniently moved through simple operation of the handle, so that convenience is brought to a user.

Description

Big data server capable of automatically powering off at high temperature

Technical Field

The utility model relates to the technical field of big data servers, in particular to a big data server capable of automatically powering off at high temperature.

Background

The server is a computer, a large amount of heat can be generated when the big data server works, the heat can be accumulated inside the server and is not easy to dissipate, when the temperature is raised to a certain height, circuits inside the big data server can be burnt out, and fire disasters and other conditions can happen seriously.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects in the prior art, and provides a high-temperature automatic power-off big data server which can be automatically disconnected when temperature sensing is carried out through a heat conducting block, so that an internal circuit is prevented from being broken, and then the big data server is conveniently driven to move through a handle, so that convenience is brought to a user.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a high-temperature automatic power-off big data server comprises a server shell, wherein the lower end of the server shell is fixedly connected with a base, four universal wheels are installed at the lower end of the base, a fan is installed on the side wall of the server shell, an opening and closing mechanism is arranged on the inner wall of the other end of the server shell, an L-shaped groove is formed in the base in a penetrating mode, and a limiting mechanism is arranged between the inner wall of the L-shaped groove and the four universal wheels;

preferably, the opening and closing mechanism comprises an L-shaped hollow block fixedly connected with the outer wall of the server shell, one end of the L-shaped hollow block penetrates through the server shell 2 and is fixedly connected with a heat-conducting block, the inner wall of the L-shaped hollow block is connected with a piston in a sliding manner, the upper end of the piston is fixedly connected with a U-shaped block, and one end of the U-shaped block penetrates through the L-shaped hollow block and is connected with the inner wall of the L-shaped hollow block in a sliding manner;

preferably, the upper end of the server shell is penetrated and fixedly connected with a hollow block, the inner wall of the hollow block is fixedly connected with a first iron sheet, the side wall of the hollow block is penetrated and fixedly connected with a magnetic block, the other end of the U-shaped block penetrates through the hollow block and is in sliding connection with the inner wall of the hollow block, the other end of the U-shaped block is fixedly connected with two limiting springs, and the two limiting springs are fixedly connected with a second iron sheet together;

preferably, the limiting mechanism comprises a sliding rod penetrating through the lower end of the L-shaped groove and connected with the inner wall of the L-shaped groove in a sliding manner, a first spring is sleeved on the sliding rod, the lower end of the first spring is fixedly connected with the inner wall of the L-shaped groove, and the upper end of the sliding rod and the first spring are fixedly connected with a first wedge-shaped block;

preferably, the lower end of the sliding rod is fixedly connected with a pressing plate, the lower end of the pressing plate is fixedly connected with two second springs, and the two second springs are fixedly connected with a friction block together;

preferably, the inner wall sliding connection in L-shaped groove has the handle, handle fixedly connected with second wedge, the other end of handle runs through and is equipped with the constant head tank, the lateral wall of base runs through and is equipped with the T-slot, the inner wall of T-slot runs through and sliding connection has the T-shaped piece, the upper end fixedly connected with locating piece of T-shaped piece, the locating piece run through the constant head tank and rather than inner wall sliding connection, fixedly connected with third spring between the inner wall in T-slot and the T-shaped piece.

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

1. when the temperature in the server shell is too high, the heat conducting block transfers the temperature, the expansion liquid is heated to expand to push the piston and the U-shaped block to move upwards, the second iron sheet is driven by the expansion liquid through the two limiting springs to ascend, the second iron sheet is separated from the first iron sheet, namely, the circuit of the big data server is disconnected, and the big data server stops running.

2. When the big data server shell needs to be moved, the handle is pulled to drive the second wedge block to be away from the first wedge block, the first spring drives the first wedge block, the pressing plate, the two second springs and the friction block to ascend under the limiting effect of the first spring, the friction block does not abut against the ground any more, the handle can be pulled to move, and the base is very convenient to move.

To sum up, can break off big data server automatically through heat conduction piece transfer heat, prevent that the inside high temperature from taking place the accident, secondly, conveniently drive big data server through the handle and remove, offer convenience for the user.

Drawings

FIG. 1 is a schematic external view of the present invention;

FIG. 2 is a cross-sectional view of a server housing;

FIG. 3 is an enlarged view of the structure at A in FIG. 2;

fig. 4 is a cross-sectional view of the base.

In the figure: the server comprises a base 1, a server shell 2, a fan 3, a hollow block 4, a hollow block 5L-shaped, a magnetic block 6, a second iron sheet 7, a first iron sheet 8, a heat-conducting block 9, a U-shaped block 10, a piston 11, a first wedge-shaped block 12, a first spring 13, a second wedge-shaped block 14, a handle 15, a T-shaped block 16, a third spring 17, a second spring 18 and a friction block 19.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-4, a high-temperature automatic power-off big data server comprises a server shell 2, wherein a base 1 is fixedly connected to the lower end of the server shell 2, four universal wheels are installed at the lower end of the base 1, a fan 3 is installed on the side wall of the server shell 2, the fan 3 penetrates through the side wall of the server shell 1, a dust screen can be arranged outside the fan 3 so as to prevent dust, and the fan 3 is used for heat dissipation.

Other end inner wall of server casing 2 is equipped with starting and stopping mechanism, and starting and stopping mechanism includes the cavity piece 5 in the L shape with 2 outer wall fixed connection of server casing, and it has the inflation liquid to fill in the cavity piece 5 in the L shape, and the inflation liquid is kerosene, and the one end of cavity piece 5 in the L shape runs through server casing 2 and fixedly connected with heat conduction piece 9, and the inflation liquid pastes mutually with the outer wall of heat conduction piece 9, and the material of heat conduction piece 9 is the aluminum alloy, and heat transfer effect is good.

Inner wall sliding connection of hollow piece 5 has piston 11 in the L shape, the upper end fixedly connected with U-shaped piece 10 of piston 11, the one end of U-shaped piece 10 runs through hollow piece 5 in the L shape and rather than inner wall sliding connection, the upper end of server casing 2 runs through and the hollow piece 4 of fixedly connected with, the first iron sheet 8 of inner wall fixedly connected with of hollow piece 4, the lateral wall of hollow piece 4 runs through and fixedly connected with magnetic path 6, the other end of U-shaped piece 10 runs through hollow piece 4 and rather than inner wall sliding connection, two spacing springs of other end fixedly connected with of U-shaped piece 10, the common fixedly connected with second iron sheet 7 of two spacing springs, the circuit is in the feed through state when first iron sheet 8 offsets with second iron sheet 7.

The base 1 is provided with an L-shaped groove in a penetrating way, a limiting mechanism is arranged between the inner wall of the L-shaped groove and the four universal wheels, the limiting mechanism comprises a sliding rod which penetrates through the lower end of the L-shaped groove and is connected with the inner wall of the L-shaped groove in a sliding way, a first spring 13 is sleeved on the sliding rod, the lower end of the first spring 13 is fixedly connected with the inner wall of the L-shaped groove, the upper end of the sliding rod and the first spring 13 are fixedly connected with a first wedge-shaped block 12, the lower end of the sliding rod is fixedly connected with a pressing plate, the lower end of the pressing plate is fixedly connected with two second springs 18, the two second springs 18 are fixedly connected with a friction block 19, the inner wall of the L-shaped groove is connected with a handle 15 in a sliding way, the handle 15 is fixedly connected with a second wedge-shaped block 14, the other end of the handle 15 is provided with a positioning groove in a penetrating way, the side wall of the base 1 is provided with a T-shaped groove in a penetrating way, the inner wall of the T-shaped groove is connected with a T-shaped block 16 in a penetrating way in a sliding way, and the upper end of the T-shaped block 16 is fixedly connected with a positioning block, the locating piece runs through the constant head tank and rather than inner wall sliding connection, and fixedly connected with third spring 17 between the inner wall in T-shaped groove and T-shaped piece 16, the T-shaped groove carries out spacingly to T-shaped piece 16.

In the utility model, when the heat generated by the work of the big data server is overhigh, the heat conducting block 9 transmits the temperature into the expansion liquid in the L-shaped hollow block 5, the expansion liquid is expanded by heat to push the piston 11 and the U-shaped block 10 to move upwards, because the magnetic block 6 and the second iron sheet 7 have certain attraction force, the two limiting springs can be stretched to a certain distance, when the temperature of the big data server is overhigh, the tension force on the U-shaped block 10 after the expansion liquid is expanded is greater than the attraction force of the magnetic block 6 on the second iron sheet 7, the second iron sheet 7 is driven to rise by the two limiting springs and is separated from the first iron sheet 8, namely, the circuit of the big data server is disconnected, and the big data server stops running.

When the big data server shell 2 needs to be moved, the T-shaped block 16 is pressed downwards and is compressed by the third spring 17, then the handle 15 is pulled, the handle drives the second wedge block 14 to be far away from the first wedge block 12, the first spring 13 drives the first wedge block 12, the pressing plate, the two second springs 18 and the friction block 19 to ascend under the limiting of the first spring 13, the friction block 19 does not abut against the ground any more, and the movement of the whole device can be realized by pulling the handle 15.

Claims (6)

1. The utility model provides a big data server of high temperature auto-power-off, includes server casing (2), its characterized in that, lower extreme fixedly connected with base (1) of server casing (2), four universal wheels are installed to the lower extreme of base (1), fan (3) are installed to the lateral wall of server casing (2), the other end inner wall of server casing (2) is equipped with start-stop mechanism, base (1) runs through and is equipped with the L shape groove, be equipped with stop gear between the inner wall in L shape groove and four universal wheels.

2. The big data server of claim 1, wherein the opening and closing mechanism comprises an L-shaped hollow block (5) fixedly connected with the outer wall of the server shell (2), one end of the L-shaped hollow block (5) penetrates through the server shell (2) and is fixedly connected with a heat conducting block (9), the inner wall of the L-shaped hollow block (5) is slidably connected with a piston (11), the upper end of the piston (11) is fixedly connected with a U-shaped block (10), and one end of the U-shaped block (10) penetrates through the L-shaped hollow block (5) and is slidably connected with the inner wall of the L-shaped hollow block.

3. The high-temperature automatic power-off big data server according to claim 2, wherein the upper end of the server housing (2) is penetrated and fixedly connected with a hollow block (4), the inner wall of the hollow block (4) is fixedly connected with a first iron sheet (8), the side wall of the hollow block (4) is penetrated and fixedly connected with a magnetic block (6), the other end of the U-shaped block (10) is penetrated and slidably connected with the inner wall of the hollow block (4), the other end of the U-shaped block (10) is fixedly connected with two limiting springs, and the two limiting springs are fixedly connected with a second iron sheet (7) together.

4. The big data server of a high temperature auto-power-off of claim 1, wherein the limiting mechanism comprises a sliding rod which penetrates through the lower end of the L-shaped groove and is connected with the inner wall of the L-shaped groove in a sliding manner, a first spring (13) is sleeved on the sliding rod, the lower end of the first spring (13) is fixedly connected with the inner wall of the L-shaped groove, and the upper end of the sliding rod and the first spring (13) are fixedly connected with a first wedge-shaped block (12) together.

5. The big data server of claim 4, wherein a pressing plate is fixedly connected to the lower end of the sliding rod, two second springs (18) are fixedly connected to the lower end of the pressing plate, and a friction block (19) is fixedly connected to the two second springs (18) together.

6. The big data server of claim 5, wherein a handle (15) is slidably connected to the inner wall of the L-shaped groove, a second wedge-shaped block (14) is fixedly connected to the handle (15), a positioning groove is formed in the other end of the handle (15) in a penetrating manner, a T-shaped groove is formed in the side wall of the base (1) in a penetrating manner, a T-shaped block (16) is slidably connected to the inner wall of the T-shaped groove in a penetrating manner, a positioning block is fixedly connected to the upper end of the T-shaped block (16) and penetrates through the positioning groove and is slidably connected to the inner wall of the positioning block, and a third spring (17) is fixedly connected between the inner wall of the T-shaped groove and the T-shaped block (16).

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