CN218634623U - Heat dissipation and shielding structure of electromagnetic pulse vector signal receiving equipment - Google Patents

Abstract

The utility model relates to the technical field of heat dissipation, and discloses a heat dissipation and shielding structure of electromagnetic pulse vector signal receiving equipment, which comprises a main body mechanism, a protection mechanism and a supporting mechanism, wherein the protection mechanism is positioned inside the main body mechanism, and the supporting mechanism is positioned below the main body mechanism; the main body mechanism comprises a supporting base, a protective shell, a connector, a heat conducting plate, a heat conducting silica gel layer and an electromagnetic pulse vector signal receiving circuit board, wherein the protective shell is fixedly installed at the upper end of the supporting base, the connector is fixedly installed at the front end of the protective shell, and the heat conducting plate is fixedly installed at the lower part inside the protective shell. This electromagnetic pulse vector signal receiving equipment's heat dissipation and shielding structure adopts the heat radiation structure of water-cooled, and the water-cooled structure that is platelike structure directly carries out the heat transfer through heat conduction silica gel layer and electromagnetic pulse vector signal receiving circuit board, and the heat transfer effect improves greatly, the effectual radiating effect who improves this equipment.

Description

Heat dissipation and shielding structure of electromagnetic pulse vector signal receiving equipment

Technical Field

The utility model relates to a heat dissipation technical field specifically is a heat dissipation and shielding structure of electromagnetic pulse vector signal receiving equipment.

Background

Present electrical equipment can give off heat more or less at the during operation, according to different electrical components in the different equipment, its degree of generating heat is all different, and electromagnetic pulse vector signal receiving equipment can give off heat equally, and its thermal degree of giving off is relevant with its power of operation, the power is higher more it generates heat more seriously, the power is lower generate heat less, present heat radiation structure effect is still gone when its low power operation, but the heat radiation effect is just relatively poor when equipment high power operation, lead to equipment to generate heat seriously, influence equipment normal operating, and present electromagnetic pulse vector signal receiving equipment still need increase shielding structure when using, present shielding structure is mostly all installed on the shell, there is the shielding electric leakage, shielding effect is relatively poor.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

An object of the utility model is to provide an electromagnetic pulse vector signal receiving equipment's heat dissipation and shielding structure to it is still capable in its low-power operation effect to propose present heat dissipation structure in solving above-mentioned background art, but the radiating effect is just relatively poor when equipment high power operation, it is serious to lead to equipment to generate heat, influence equipment normal operating, and present electromagnetic pulse vector signal receiving equipment still needs to increase shielding structure when using moreover, present shielding structure is most all to install on the shell, there is the shielding electric leakage, the relatively poor problem of shielding effect.

(II) technical scheme

In order to achieve the above purpose, the utility model provides a following technical scheme: a heat dissipation and shielding structure of electromagnetic pulse vector signal receiving equipment comprises a main body mechanism, a protection mechanism and a supporting mechanism, wherein the protection mechanism is positioned inside the main body mechanism, and the supporting mechanism is positioned below the main body mechanism;

the main part mechanism is including supporting base, protective housing, connector, heat-conducting plate, heat conduction silica gel layer and electromagnetic pulse vector signal receiving circuit board, protective housing fixed mounting is in the upper end of supporting the base, connector fixed mounting is at protective housing's front end, heat-conducting plate fixed mounting is in the inside lower part of protective housing, the fixed upper end that sets up at the heat-conducting plate of heat conduction silica gel layer, electromagnetic pulse vector signal receiving circuit board fixed mounting is in the upper end on heat conduction silica gel layer.

Preferably, the protection machanism includes holding water tank, right water pipe and left water pipe, the heat-conducting plate is cavity platelike structure, holding water tank fixed mounting is in protective housing's upper end, holding water tank's lower extreme extends to protective housing's inside upper portion, the fixed intercommunication of right side water pipe is in the right part between holding water tank and heat-conducting plate, the fixed intercommunication of left side water pipe is in the left part between holding water tank and heat-conducting plate, and the heat radiation structure of this equipment adopts the heat radiation structure of water-cooled, and is the water-cooling structure of platelike structure and directly carries out the heat transfer through heat conduction silica gel layer and electromagnetic pulse vector signal receiving circuit board, and the heat transfer effect improves greatly, the effectual radiating effect who improves this equipment.

Preferably, the protection machanism still includes immersible pump, nature communicating pipe, first solenoid valve and second solenoid valve, immersible pump fixed mounting is in the inside of holding in the water tank, the play water end of immersible pump and the fixed intercommunication in upper end of right water pipe, the fixed intercommunication in nature communicating pipe is in the outer end on right water pipe upper portion, nature communicating pipe is located the inside of holding in the water tank, first solenoid valve fixed mounting is in the inner of nature communicating pipe, second solenoid valve fixed mounting is in the inner on right water pipe upper portion, the second solenoid valve is located the left side of nature communicating pipe, and closes first solenoid valve and starts the second solenoid valve when this equipment high power operation, starts the immersible pump afterwards, and the immersible pump can be taken out the inside rivers of holding in the water tank to the right water pipe, and rivers enter into the heat-conducting plate afterwards, and rivers enter into the left water pipe afterwards, and finally rivers get back to the holding in the water tank once more, under this circulation state, the inside rivers that make the heat-conducting plate that can be quick change to accelerate the radiating effect.

Preferably, protection machanism still includes radiating fin, radiator fan and shielding net, the fixed upper end that sets up at the water storage tank of radiating fin, radiator fan fixed mounting is in radiating fin's upper end, shielding net fixed mounting is in the outside of electromagnetic pulse vector signal receiving circuit board, the shielding net is located the outside of heat-conducting plate, and the shielding net of installation is the outside of parcel formula installation at electromagnetic pulse vector signal receiving circuit board, and is in the same place through welded connection between its junction and the heat-conducting plate, therefore shielding structure does not have the dew point, and the shielding effect improves greatly.

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

1. the heat dissipation and shielding structure of the electromagnetic pulse vector signal receiving equipment adopts a water-cooled heat dissipation structure, and the water-cooled structure in a plate-shaped structure directly exchanges heat with the electromagnetic pulse vector signal receiving circuit board through the heat conduction silica gel layer, so that the heat exchange effect is greatly improved, and the heat dissipation effect of the equipment is effectively improved;

2. in the heat dissipation and shielding structure of the electromagnetic pulse vector signal receiving equipment, the installed shielding net is installed outside the electromagnetic pulse vector signal receiving circuit board in a wrapping manner, and the joint of the shielding net and the heat conducting plate are connected together by welding, so that the shielding structure has no dew point;

3. this electromagnetic pulse vector signal receiving arrangement's heat dissipation and shielding structure, close first solenoid valve and start the second solenoid valve when this equipment high power operation, start the immersible pump afterwards, the immersible pump can be taken out the inside rivers of water storage tank to the right water pipe in, rivers enter into the heat-conducting plate afterwards, rivers enter into the left water pipe afterwards, at last rivers get back to the water storage tank once more, under this circulation state, the inside rivers of messenger's heat-conducting plate that can be quick change, thereby accelerate the radiating effect.

Drawings

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

FIG. 2 is a schematic sectional view of the present invention;

FIG. 3 is a schematic view of the cross-sectional structure of the heat-conducting plate of the present invention;

fig. 4 is a schematic view of the right water pipe section structure of the present invention.

In the figure: 1. a main body mechanism; 2. a protection mechanism; 3. a support mechanism; 101. a support base; 102. a protective housing; 103. a connection port; 104. a heat conducting plate; 105. a heat-conducting silica gel layer; 106. an electromagnetic pulse vector signal receiving circuit board; 201. a water storage tank; 202. a right water pipe; 203. a left water pipe; 204. a submersible pump; 205. a natural communicating pipe; 206. a first solenoid valve; 207. a second solenoid valve; 208. a heat dissipating fin; 209. a heat radiation fan; 210. a shielding mesh; 301. installing a base; 302. a damper; 303. a damping spring; 304. and (7) mounting the sheet.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a heat dissipation and shielding structure of an electromagnetic pulse vector signal receiving device comprises a main body mechanism 1, a protection mechanism 2 and a supporting mechanism 3, wherein the protection mechanism 2 is positioned inside the main body mechanism 1, and the supporting mechanism 3 is positioned below the main body mechanism 1; the main mechanism 1 comprises a supporting base 101, a protective shell 102, a connector 103, a heat conducting plate 104, a heat conducting silica gel layer 105 and an electromagnetic pulse vector signal receiving circuit board 106, wherein the protective shell 102 is fixedly arranged at the upper end of the supporting base 101, the connector 103 is fixedly arranged at the front end of the protective shell 102, the heat conducting plate 104 is fixedly arranged at the lower part inside the protective shell 102, the heat conducting silica gel layer 105 is fixedly arranged at the upper end of the heat conducting plate 104, the electromagnetic pulse vector signal receiving circuit board 106 is fixedly arranged at the upper end of the heat conducting silica gel layer 105, the protective mechanism 2 comprises a water storage tank 201, a right water pipe 202 and a left water pipe 203, the heat conducting plate 104 is of a hollow plate structure, the water storage tank 201 is fixedly arranged at the upper end of the protective shell 102, the lower end of the water storage tank 201 extends to the upper part inside the protective shell 102, the right water pipe 202 is fixedly communicated at the right part between the water storage tank 201 and the heat conducting plate 104, the left water pipe 203 is fixedly communicated at the left part between the water storage tank 201 and the heat conducting plate 104, the heat conducting plate 104, the water storage tank 201, the right water pipe 202 and the left water pipe 203 are all filled with water, when the device operates at normal power, the water flow in the whole water flow channel is in a natural flowing state, the cold water can automatically diffuse and sink into the heat conducting plate 104, the heat of the heat conducting plate 104 meets the bottom, the heat on the electromagnetic pulse vector signal receiving circuit board 106 can be absorbed under the heat conduction of the heat conducting silica gel layer 105, so that the electromagnetic pulse vector signal receiving circuit board 106 is kept at a lower temperature, when the water temperature in the heat conducting plate 104 is overhigh, the water in the heat conducting plate can naturally rise, the water flow automatically returns to the water storage tank 201 along the right water pipe 202 and the left water pipe 203 for natural cooling, the heat radiating structure of the device adopts a water-cooled heat radiating structure, and the water-cooled structure in a plate shape directly exchanges heat with the electromagnetic pulse vector signal receiving circuit board 106 through the heat conducting silica gel layer 105, the heat exchange effect is greatly improved, and the heat dissipation effect of the equipment is effectively improved;

the protection mechanism 2 further comprises a submersible pump 204, a natural communicating pipe 205, a first electromagnetic valve 206 and a second electromagnetic valve 207, the submersible pump 204 is fixedly installed inside the water storage tank 201, the water outlet end of the submersible pump 204 is fixedly communicated with the upper end of the right water pipe 202, the natural communicating pipe 205 is fixedly communicated with the outer end of the upper portion of the right water pipe 202, the natural communicating pipe 205 is located inside the water storage tank 201, the first electromagnetic valve 206 is fixedly installed at the inner end of the natural communicating pipe 205, the second electromagnetic valve 207 is fixedly installed at the inner end of the upper portion of the right water pipe 202, the second electromagnetic valve 207 is located on the left side of the natural communicating pipe 205, when the equipment runs at low power, the first electromagnetic valve 206 is opened and the second electromagnetic valve 207 is closed, the heat-conducting plate 104, the water storage tank 201, the right water pipe 202 and the left water pipe 203 are naturally communicated, when the equipment runs at high power, the first electromagnetic valve 206 is closed and the second electromagnetic valve 207 is opened, and then the submersible pump 204 is started, the submersible pump 204 can pump the water flow in the water storage tank 201 to the right water pipe 202, then the water flow enters the heat conducting plate 104, then the water flow enters the left water pipe 203, finally the water flow returns to the water storage tank 201 again, under the circulation state, the water flow in the heat conducting plate 104 can be rapidly changed, so that the heat dissipation effect is accelerated, the protection mechanism 2 further comprises a heat dissipation fin 208, a heat dissipation fan 209 and a shielding net 210, the heat dissipation fin 208 is fixedly arranged at the upper end of the water storage tank 201, the heat dissipation fan 209 is fixedly arranged at the upper end of the heat dissipation fin 208, the shielding net 210 is fixedly arranged at the outer side of the electromagnetic pulse vector signal receiving circuit board 106, the shielding net 210 is positioned at the outer side of the heat conducting plate 104, the heat dissipation fan 209 is started when the equipment runs at high power, the heat dissipation fan 209 can enable the air flow to rapidly flow through the heat dissipation fin 208, so that the water temperature in the water storage tank 201 is rapidly reduced, the submersible pump 204 is matched to quickly reduce the temperature of the electromagnetic pulse vector signal receiving circuit board 106 and improve the heat dissipation effect, the installed shielding net 210 is installed on the outer side of the electromagnetic pulse vector signal receiving circuit board 106 in a wrapping mode, and the connection part of the shielding net and the heat conducting plate 104 are connected together in a welding mode, so that the shielding structure has no dew point, and the shielding effect is greatly improved;

the supporting mechanism 3 comprises an installation base 301, a damper 302 and a shock absorption spring 303, the installation base 301 is located below the support base 101, the damper 302 is fixedly connected between the support base 101 and the installation base 301, the shock absorption spring 303 is located outside the damper 302, the damper 302 and the shock absorption spring 303 of the installation can improve the shock absorption effect of the structure, the supporting mechanism 3 further comprises an installation sheet 304, the installation sheet 304 is fixedly arranged at the outer end of the installation base 301, and the installation sheet 304 is used for installation of the structure.

The working principle is as follows: when the device operates at normal power, the water flow in the whole water flow channel is in a natural flow state, the cold water can automatically diffuse and sink into the heat conducting plate 104, the heat of the heat conducting plate 104 is mixed, the heat on the electromagnetic pulse vector signal receiving circuit board 106 can be absorbed by the heat conduction of the heat-conducting silica gel layer 105, so that the electromagnetic pulse vector signal receiving circuit board 106 can be kept at a low temperature, and when the water temperature in the heat-conducting plate 104 is too high, the water in the water tank naturally rises, the water flow automatically returns to the water storage tank 201 along the right water pipe 202 and the left water pipe 203 for natural cooling, when the apparatus is operated at low power, the first solenoid valve 206 is opened and the second solenoid valve 207 is closed, the heat conductive plate 104, the water storage tank 201, the right water pipe 202 and the left water pipe 203 are naturally communicated, and when the apparatus is operated at high power, the first solenoid valve 206 is closed and the second solenoid valve 207 is activated, and then the submersible pump 204 is activated, the submersible pump 204 may pump the water flow inside the reservoir 201 into the right water pipe 202, then the water flow enters the heat conducting plate 104, then the water flow enters the left water pipe 203, finally the water flow returns to the water storage tank 201 again, in this circulation state, the water flow inside the heat conducting plate 104 can be rapidly changed, the heat dissipation fan 209 is started when the device is operated at high power, the heat dissipation fan 209 can rapidly flow the air flow through the heat dissipation fins 208, so that the water temperature in the water storage tank 201 can be rapidly reduced, the temperature of the electromagnetic pulse vector signal receiving circuit board 106 can be rapidly reduced by matching with the submersible pump 204, the heat dissipation effect is improved, and the installed shielding net 210 is installed outside the electromagnetic pulse vector signal receiving circuit board 106 in a wrapping manner, the joint of the heat conducting plate 104 and the shielding structure is connected together by welding, so that the shielding structure has no dew point.

It should be finally noted that the above only serves to illustrate the technical solution of the present invention, and not to limit the scope of the present invention, and that simple modifications or equivalent replacements performed by those skilled in the art to the technical solution of the present invention do not depart from the spirit and scope of the technical solution of the present invention.

Claims (6)

1. The utility model provides an electromagnetic pulse vector signal receiving equipment's heat dissipation and shielding structure, includes main part mechanism (1), protection machanism (2) and supporting mechanism (3), its characterized in that: the protection mechanism (2) is positioned inside the main body mechanism (1), and the support mechanism (3) is positioned below the main body mechanism (1);

the main body mechanism (1) comprises a supporting base (101), a protective casing (102), a connecting port (103), a heat conducting plate (104), a heat conducting silica gel layer (105) and an electromagnetic pulse vector signal receiving circuit board (106), wherein the protective casing (102) is fixedly arranged at the upper end of the supporting base (101), the connecting port (103) is fixedly arranged at the front end of the protective casing (102), the heat conducting plate (104) is fixedly arranged at the lower part inside the protective casing (102), the heat conducting silica gel layer (105) is fixedly arranged at the upper end of the heat conducting plate (104), and the electromagnetic pulse vector signal receiving circuit board (106) is fixedly arranged at the upper end of the heat conducting silica gel layer (105).

2. The heat dissipation and shielding structure of an electromagnetic pulse vector signal receiving apparatus according to claim 1, wherein: protection machanism (2) are including holding water tank (201), right water pipe (202) and left water pipe (203), heat-conducting plate (104) are hollow platelike structure, holding water tank (201) fixed mounting is in the upper end of protecting casing (102), the lower extreme of holding water tank (201) extends to the inside upper portion of protecting casing (102), the right part of right water pipe (202) fixed intercommunication between holding water tank (201) and heat-conducting plate (104), the left part of left side water pipe (203) fixed intercommunication between holding water tank (201) and heat-conducting plate (104).

3. The heat dissipation and shielding structure of an electromagnetic pulse vector signal receiving apparatus according to claim 2, wherein: protection machanism (2) still include immersible pump (204), nature communicating pipe (205), first solenoid valve (206) and second solenoid valve (207), immersible pump (204) fixed mounting is in the inside of water storage tank (201), the play water end of immersible pump (204) and the fixed intercommunication in upper end of right water pipe (202), the outer end on right water pipe (202) upper portion of nature communicating pipe (205) fixed intercommunication, nature communicating pipe (205) are located the inside of water storage tank (201), first solenoid valve (206) fixed mounting is in the inner of nature communicating pipe (205), second solenoid valve (207) fixed mounting is in the inner on right water pipe (202) upper portion, second solenoid valve (207) are located the left side of nature communicating pipe (205).

4. The heat dissipation and shielding structure of an electromagnetic pulse vector signal receiving apparatus according to claim 3, wherein: protection machanism (2) still include radiating fin (208), cooling fan (209) and shielding net (210), radiating fin (208) are fixed to be set up in the upper end of water storage tank (201), cooling fan (209) fixed mounting is in the upper end of radiating fin (208), shielding net (210) fixed mounting is in the outside of electromagnetic pulse vector signal receiving circuit board (106), shielding net (210) are located the outside of heat-conducting plate (104).

5. The heat dissipation and shielding structure of an electromagnetic pulse vector signal receiving apparatus according to claim 4, wherein: the supporting mechanism (3) comprises an installation base (301), a damper (302) and a damping spring (303), the installation base (301) is located below the support base (101), the damper (302) is fixedly connected between the support base (101) and the installation base (301), the damping spring (303) is fixedly connected between the support base (101) and the installation base (301), and the damping spring (303) is located on the outer side of the damper (302).

6. The heat dissipation and shielding structure of an electromagnetic pulse vector signal receiving apparatus according to claim 5, wherein: the supporting mechanism (3) further comprises an installation sheet (304), and the installation sheet (304) is fixedly arranged at the outer end of the installation base (301).

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