CN219851604U - Cabinet door compression molding device of power supply cabinet - Google Patents

Abstract

The utility model discloses a cabinet door compression molding device of a power cabinet, and relates to the technical field of machining. The heat-insulating positioning device comprises a heat-insulating positioning frame, an upper support frame and a heat-insulating gas storage box, wherein a first sealing baffle plate and a second sealing baffle plate are rotatably clamped at two ends in the heat-insulating positioning frame, the top of the heat-insulating positioning frame is in penetrating clamping connection with the upper support frame, an upper hot-pressing die is inserted into the inner side of the upper support frame, the bottom of the heat-insulating positioning frame is in penetrating clamping connection with a lower support frame, one side of the heat-insulating positioning frame is fixedly clamped with the heat-insulating gas storage box, and two ends of one side of the heat-insulating positioning frame are respectively in penetrating clamping connection with a first high-pressure gas pump and a second high-pressure gas pump. The utility model solves the problem that the cabinet door compression molding device loses certain heat every time of feeding and discharging by arranging the heat-preserving positioning frame, the upper supporting frame and the heat-preserving gas storage tank, and the compression molding device is usually required to be provided with a feeding mechanism, a positioning mechanism and the like for automatic feeding and discharging, so that the cost is high.

Description

Cabinet door compression molding device of power supply cabinet

Technical Field

The utility model belongs to the technical field of machining, and particularly relates to a cabinet door compression molding device of a power supply cabinet.

Background

The power distribution cabinet is a generic name of a motor control center, is final equipment of a power distribution system, is used in occasions with more dispersed loads and fewer loops, is mainly composed of a leakage protector, an overcurrent protector and a thermal protector, and is mainly used for connecting other electric equipment with a power supply when the power supply cabinet is used for the occasions with more loads and more loops, and is characterized in that all components of the power supply cabinet are usually processed respectively and then assembled in the production and processing process, wherein a cabinet door of the power distribution cabinet is pressed by blanks through a hydraulic cylinder and other structures of a compression molding device and then further processed, so that the processing efficiency of the cabinet door is improved, but the power distribution cabinet still has the following defects in actual use:

1. the utility model has disclosed a cabinet door plate pressing device of publication No. CN212399864U, the feed mechanism links to each other with one side of the stander, there are bases under the stander, there are support columns on both sides in the stander, there are top plates on the top of the support column of both sides, there are driving motors on the top plate, the driving motor connects the hydraulic lever of both sides, the hydraulic lever of both sides is installed under the top plate, there are springs on the hydraulic lever of both sides, there are press plates under the hydraulic lever of both sides, the press plate is embedded with the pressing ring, there are upper hot-pressing mechanisms under the press plate, there are lower hot-pressing mechanisms below the upper hot-pressing mechanisms, the lower hot-pressing mechanisms are installed on working platform, the working platform is installed in the stander, another side of the stander is connected with feed mechanism, the feed mechanism both sides are cooling fans, the cooling fans connect the electrical machinery, the electrical machinery is installed on one side of feed mechanism, in the pressing device presses the course, through heating raw materials in order to raise the pressing efficiency, but in the course of actual use, because hot-pressing mechanism and ambient temperature are great in order to have a large amount of heat to lose in the environment each time, increase the electric charge;

2. for improving the safety of use, the compression molding device generally needs to be provided with a feeding mechanism and a feeding mechanism for automatic feeding and discharging, and for ensuring accurate pressing positions, the device needs to be provided with a positioning mechanism for accurate positioning, so that the structure of the compression molding device is complex, and the production cost is increased.

Disclosure of Invention

The utility model aims to provide a cabinet door compression molding device of a power cabinet, which solves the problems that when the cabinet door compression molding device is in actual use, certain heat is lost during each feeding and discharging, the electric charge expense is increased, and the compression molding device is usually required to be provided with a feeding mechanism, a positioning mechanism and the like for automatic feeding and discharging, but the compression molding device is complex in structure and high in cost.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to a cabinet door compression molding device of a power cabinet, which comprises a heat preservation locating rack, an upper supporting rack and a heat preservation gas storage box, wherein a first sealing baffle and a second sealing baffle are rotatably clamped at two ends in the heat preservation locating rack, when raw materials are fed and discharged, the first sealing baffle or the second sealing baffle can ensure relative tightness of the heat preservation locating rack, so that the raw materials of the cabinet door are prevented from being fed and discharged due to insufficient air pressure, the top of the heat preservation locating rack is penetrated and clamped with the upper supporting rack, the inner side of the upper supporting rack is inserted and connected with an upper hot-pressing mold, the bottom of the heat preservation locating rack is penetrated and clamped with a lower supporting rack, the inner side of the lower supporting rack is inserted and connected with a lower supporting mold, after the raw materials enter the inner side of the heat preservation locating rack, the raw materials fall to the upper side of the lower supporting mold of the lower supporting rack through air pressure, and in the compression molding process, the raw materials can be pressed and formed through the extrusion of the upper hot pressing die and the lower supporting die, the processing efficiency is improved, a heat preservation gas storage tank is clamped and fixed on one side of the heat preservation locating rack, a first high-pressure gas pump and a second high-pressure gas pump are respectively penetrated and clamped at two ends of one side of the heat preservation locating rack, a third high-pressure gas pump is penetrated and clamped at the bottom side of the lower supporting rack, the heat preservation locating rack can be further heated through heating the upper hot pressing die, when feeding is carried out, a worker inserts the raw materials from one end of the heat preservation locating rack, air is pumped into the heat preservation locating rack through the second high-pressure gas pump, high-temperature air can be pumped into the inner side of the heat preservation gas storage tank for storage, meanwhile, the raw materials can rapidly enter the inner side of the heat preservation locating rack for pressing under the action of the air pressure through reducing the air pressure in the heat preservation locating rack, and after the pressing is finished, the first high-pressure air pump and the third high-pressure air pump are used for pumping the high-temperature air in the heat-preservation air storage box to the inner side of the heat-preservation locating rack, and the cabinet door is pushed out from the other end of the heat-preservation locating rack through the increased air pressure.

Further, two ends of the heat-insulating locating frame are respectively provided with a feed inlet and a discharge outlet in a penetrating way, the top of the inner side of the heat-insulating locating frame is inserted with a plurality of limiting frames, the first sealing baffle is positioned at one end of the feed inlet of the heat-insulating locating frame, the first sealing baffle is attached to the other side of one limiting frame relative to the feed inlet, the second sealing baffle is positioned at one end of the discharge outlet of the heat-insulating locating frame, and the second sealing baffle is attached between one limiting frame and the discharge outlet;

staff can change the size of spacing according to the thickness of raw materials, guarantee that the raw materials just can slide in the locating rack that keeps warm inboard, the frictional force between the inboard comparatively smooth and raw materials of locating rack that keeps warm is less, guarantee that the raw materials can slide fast under the atmospheric pressure effect, the locating rack that keeps warm can be certain angle, feed inlet one end is higher than discharge gate one end, further guarantee the speed of feeding and discharging, when carrying out the feeding, the spacing can avoid second sealing baffle to rotate to the locating rack inboard that keeps warm, when carrying out the ejection of compact, the spacing can avoid first sealing baffle to rotate to the locating rack outside that keeps warm, avoid the discharge of hot air, further avoid a large amount of thermal losses, reduce the charges of electricity expense.

Further, the upper side of the upper support frame is penetrated and clamped with a first air cylinder, the upper hot-pressing die is slidably and clamped at the bottom of the first air cylinder, the bottom end of the lower support frame is penetrated and clamped with a second air cylinder, the lower support die is slidably and clamped at the top of the second air cylinder, and the upper hot-pressing die is suspended at the upper end of the lower support die;

after the raw materials enter the inner side of the heat-preserving locating rack under the action of air pressure and fall to the upper end of the lower supporting mould, the upper hot-pressing mould is driven to move downwards through the first air cylinder, the raw materials can be hot-pressed and formed, and after the hot-pressing and forming, the lower supporting mould is driven to move upwards through the second air cylinder, so that the cabinet door falling to the inner side of the lower supporting rack moves to the inner side of the heat-preserving locating rack, and the cabinet door can be discharged through air pressure quickly.

Further, one end of the first high-pressure air pump is fixedly connected with an air charging pipe in a clamping mode, a first vent pipe is fixedly connected with the outer peripheral surface of the first high-pressure air pump in a clamping mode, the other end of the first vent pipe is connected with one side of the heat preservation air storage box in a penetrating mode, one end of the air charging pipe is connected with one side of the heat preservation locating frame in a penetrating mode, and the air charging pipe is located between the first sealing baffle and the upper supporting frame;

when the discharging is carried out, the high-temperature air pump at the inner side of the heat preservation gas storage tank is connected to the inner side of the heat preservation locating rack through the first high-pressure air pump, and the pressed cabinet door is extruded through air pressure, so that the cabinet door can be rapidly discharged through the discharging hole, the structure is simple, and the production cost is reduced.

Further, an exhaust pipe is fixedly clamped at one end of the second high-pressure air pump, a second ventilation pipe is fixedly clamped at the outer peripheral surface of the second high-pressure air pump, the other end of the second ventilation pipe is penetrated and clamped at one side of the heat-preserving gas storage box, one end of the exhaust pipe is penetrated and clamped at one side of the heat-preserving positioning frame, and the exhaust pipe is positioned between the upper supporting frame and the second sealing baffle;

when feeding, the staff inserts the raw materials from feed inlet one end to bleed in to the heat preservation locating rack through the second high-pressure air pump, reduce the inboard atmospheric pressure of heat preservation locating rack, make the raw materials quick feeding under the atmospheric pressure effect, and the hot air storage in heat preservation gas receiver inboard of taking out, avoid feeding in-process heat to scatter and disappear in the environment, reduce the charges of electricity expense.

Further, a corrugated pipe is clamped at the top of the third high-pressure air pump, a one-way valve is clamped at the top of the corrugated pipe, the one-way valve is penetrated and clamped at the bottom of the lower supporting die, a third air-through pipe is clamped at the peripheral surface of the third high-pressure air pump, and the other end of the third air-through pipe is penetrated and clamped at one side of the heat preservation air storage box;

when carrying out the ejection of compact, the third high-pressure air pump can be to pumping in the air between cabinet door and the lower support mould, makes the cabinet door upwards remove and peg graft in the heat preservation locating rack inboard along the lower carriage, avoids because lower support mould is comparatively unsmooth to lead to cabinet door ejection of compact difficulty, and the check valve is located the less position of lower support mould atress, avoids leading to the check valve damage because the pressure of suppression.

The utility model has the following beneficial effects:

1. according to the utility model, the heat-preserving locating rack and the heat-preserving gas storage box are arranged, so that the problem that in the pressing process of the pressing device, a hot pressing mechanism is usually arranged, the pressing efficiency is improved by heating raw materials in the pressing process, but in the actual use process, because the hot pressing mechanism and the ambient temperature differ greatly, a large amount of heat is dissipated in the environment each time of feeding and discharging, and the electricity expense is increased is solved, in the feeding process, the high-temperature air in the heat-preserving locating rack is pumped to the inner side of the gas storage box through the second high-pressure air pump, the heat is stored, meanwhile, raw materials are sucked into the inner side of the heat-preserving locating rack through air pressure, in the discharging process, the high-temperature air pump stored in the heat-preserving gas storage box is pumped to the inner side of the heat-preserving locating rack through the first high-pressure air pump, and the cabinet door is extruded through the air pressure to enable the raw materials to be rapidly discharged, the hot air in the heat-preserving locating rack is difficult to exchange with the external environment, the heat dissipation in the feeding and discharging process is reduced, and the electricity expense is reduced.

2. According to the utility model, the heat-insulating locating rack, the upper supporting frame and the heat-insulating gas storage box are arranged, so that the problem that the compression forming device is high in use safety, a feeding mechanism and a feeding mechanism are required to be arranged for automatic feeding and discharging, and the device is required to be provided with the locating mechanism for accurate locating simultaneously so as to ensure accurate pressing positions, thus the structure of the compression forming device is complex and production cost is increased is solved.

Drawings

FIG. 1 is a structural effect diagram of the present utility model;

FIG. 2 is a block diagram of the thermal insulation positioning frame of the present utility model;

FIG. 3 is a side view of the thermal insulation positioning rack of the present utility model;

FIG. 4 is a cross-sectional view of the thermal insulation positioning frame of the present utility model;

FIG. 5 is a cross-sectional exploded view of the upper and lower support brackets of the present utility model;

FIG. 6 is a block diagram of the insulated gas storage tank of the present utility model.

Reference numerals:

1. a heat-preserving positioning frame; 101. a feed inlet; 102. a limiting frame; 103. a discharge port; 104. a first sealing barrier; 105. a second sealing barrier; 2. an upper support frame; 201. a lower support frame; 202. a first cylinder; 203. a second cylinder; 204. loading a hot pressing die; 205. a lower support die; 3. a heat preservation gas storage tank; 301. a first high-pressure air pump; 302. a second high-pressure air pump; 303. a third high pressure air pump; 304. a first vent pipe; 305. a second vent pipe; 306. an inflation tube; 307. an exhaust pipe; 308. a bellows; 309. a one-way valve; 310. and a third air vent.

Detailed Description

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

Referring to fig. 1-6, the utility model discloses a cabinet door compression molding device of a power cabinet, which comprises a heat-insulation positioning frame 1, an upper supporting frame 2 and a heat-insulation gas storage box 3, wherein a first sealing baffle 104 and a second sealing baffle 105 are rotatably clamped at two ends in the heat-insulation positioning frame 1, when raw materials are fed and discharged, the first sealing baffle 104 or the second sealing baffle 105 ensures relative tightness of the heat-insulation positioning frame 1, so that the raw materials of the cabinet door are prevented from being fed and discharged difficultly due to insufficient air pressure, the top of the heat-insulation positioning frame 1 is penetrated and clamped with the upper supporting frame 2, an upper hot-pressing die 204 is inserted at the inner side of the upper supporting frame 2, a lower supporting frame 201 is penetrated and clamped at the bottom of the heat-insulation positioning frame 1, a lower supporting die 205 is inserted at the inner side of the lower supporting frame 201, after the raw materials enter the inner side of the heat-insulation positioning frame 1, the raw materials are moved in the heat-insulation positioning frame 1 through air pressure, and falls to the upper side of the lower supporting die 205 in the lower supporting frame 201 under the action of gravity, in the process of compression molding, raw materials are compressed and molded through the extrusion of the upper hot pressing die 204 and the lower supporting die 205, one side of the heat preservation locating frame 1 is fixedly clamped with the heat preservation gas storage box 3, two ends of one side of the heat preservation locating frame 1 are respectively penetrated and clamped with the first high-pressure gas pump 301 and the second high-pressure gas pump 302, the bottom side of the lower supporting frame 201 is penetrated and clamped with the third high-pressure gas pump 303, the upper hot pressing die 204 is heated, the heat preservation locating frame 1 is further heated, when feeding is carried out, a worker inserts the raw materials from one end of the heat preservation locating frame 1, pumps air in the heat preservation locating frame 1 through the second high-pressure gas pump 302, pumps high-temperature air to the inner side of the heat preservation gas storage box 3 for storage, and simultaneously, the raw materials rapidly enter the inner side of the heat preservation locating frame 1 for compression under the action of the air pressure, after the pressing is completed, the first high-pressure air pump 301 and the third high-pressure air pump 303 pump the high-temperature air in the heat-preserving air storage tank 3 to the inner side of the heat-preserving positioning frame 1, and the cabinet door is pushed out from the other end of the heat-preserving positioning frame 1 through the increased air pressure.

As shown in fig. 1-4, two ends of the heat-preserving positioning frame 1 are respectively provided with a feed inlet 101 and a discharge outlet 103 in a penetrating manner, the top of the inner side of the heat-preserving positioning frame 1 is inserted with a plurality of limiting frames 102, a first sealing baffle 104 is positioned at one end of the feed inlet 101 of the heat-preserving positioning frame 1, the first sealing baffle 104 is attached to the other side of one limiting frame 102 relative to the feed inlet 101, a second sealing baffle 105 is positioned at one end of the discharge outlet 103 of the heat-preserving positioning frame 1, and the second sealing baffle 105 is attached between one limiting frame 102 and the discharge outlet 103;

before processing, the size of the limiting frame 102 is changed by staff according to the thickness of the raw materials, the raw materials are guaranteed to just slide on the inner side of the heat-preserving positioning frame 1, when feeding is carried out, the limiting frame 102 prevents the second sealing baffle 105 from rotating on the inner side of the heat-preserving positioning frame 1, and when discharging is carried out, the limiting frame 102 prevents the first sealing baffle 104 from rotating on the outer side of the heat-preserving positioning frame 1, and hot air is prevented from being discharged.

As shown in fig. 1 and 5, the upper side of the upper support frame 2 is connected with a first air cylinder 202 in a penetrating manner, an upper hot-pressing die 204 is connected with the bottom of the first air cylinder 202 in a sliding manner, the bottom of the lower support frame 201 is connected with a second air cylinder 203 in a penetrating manner, a lower support die 205 is connected with the top of the second air cylinder 203 in a sliding manner, and the upper hot-pressing die 204 is suspended at the upper end of the lower support die 205;

after raw materials enter the inner side of the heat-preserving positioning frame 1 under the action of air pressure and fall to the upper end of the lower supporting mold 205, the first air cylinder 202 drives the upper hot-pressing mold 204 to move downwards, the raw materials are hot-pressed and formed, and after the hot-pressing and forming, the second air cylinder 203 drives the lower supporting mold 205 to move upwards, so that a cabinet door falling to the inner side of the lower supporting frame 201 moves to the inner side of the heat-preserving positioning frame 1, and the cabinet door is rapidly discharged through air pressure.

As shown in fig. 1 and 6, an air tube 306 is fastened and fixed at one end of the first high-pressure air pump 301, a first ventilation tube 304 is fastened and fixed at the outer peripheral surface of the first high-pressure air pump 301, the other end of the first ventilation tube 304 is fastened and fixed at one side of the heat-insulation gas storage tank 3, one end of the air tube 306 is fastened and fixed at one side of the heat-insulation positioning frame 1, the air tube 306 is positioned between the first sealing baffle 104 and the upper support frame 2, an air tube 307 is fastened and fixed at one end of the second high-pressure air pump 302, a second ventilation tube 305 is fastened and fixed at the outer peripheral surface of the second high-pressure air pump 302, the other end of the second ventilation tube 305 is fastened and fixed at one side of the heat-insulation gas storage tank 3, one end of the air tube 307 is fastened and fixed at one side of the heat-insulation positioning frame 1, and the air tube 307 is positioned between the upper support frame 2 and the second sealing baffle 105;

the top of the third high-pressure air pump 303 is clamped with a corrugated pipe 308, the top of the corrugated pipe 308 is clamped with a one-way valve 309, the one-way valve 309 is penetrated and clamped at the bottom of the lower supporting die 205, the outer peripheral surface of the third high-pressure air pump 303 is clamped with a third three-way air pipe 310, and the other end of the third three-way air pipe 310 is penetrated and clamped at one side of the heat preservation air storage tank 3;

when feeding, the staff inserts the raw materials from feed inlet 101 one end, and bleed in to heat preservation locating rack 1 through second high-pressure air pump 302, reduce heat preservation locating rack 1 inboard atmospheric pressure, make the raw materials quick feeding under the atmospheric pressure effect, and the hot air of taking out is stored in heat preservation gas receiver 3 inboard through second breather pipe 305, avoid feeding in-process heat to scatter and disappear in the environment, when carrying out the ejection of compact, pump heat preservation gas receiver 3 inboard high temperature air through first breather pipe 304 and gas tube 306 to heat preservation locating rack 1 inboard through first high-pressure air pump 301, extrude the cabinet door that presses through the atmospheric pressure, pump air between cabinet door and the lower support mould 205 simultaneously third high-pressure air pump 303 makes the cabinet door upwards move and peg graft in heat preservation locating rack 1 inboard along lower support frame 201, avoid because lower support mould 205 comparatively unsmooth lead to cabinet door ejection of compact difficulty, make the cabinet door pass through ejection of compact 103 quick ejection of compact.

The specific working principle of the utility model is as follows: before processing, the staff changes the size of spacing 102 according to the thickness of raw materials, guarantee that the raw materials just can slide in thermal insulation locating rack 1 inboard, when carrying out the feeding, peg graft raw materials one end in feed inlet 101, bleed down in thermal insulation locating rack 1 through second high-pressure air pump 302, reduce thermal insulation locating rack 1 inboard atmospheric pressure, make the raw materials quick feeding under the atmospheric pressure effect, and the hot air of taking out stores in thermal insulation gas storage box 3 inboard through second vent pipe 305, avoid feeding in-process heat to scatter and disappear in the environment, the raw materials gets into thermal insulation locating rack 1 inboard under the atmospheric pressure effect and falls to the back of lower support mould 205 upper end, drive hot briquetting through first cylinder 202 and go up hot briquetting 204 down, after hot briquetting, drive lower support mould 205 through second cylinder 203 and upwards move, make the cabinet door that falls to the lower support 201 inboard move to thermal insulation locating rack 1 inboard, through first high-pressure air pump 301 with thermal insulation gas storage box 3 inboard high temperature air through first breather pipe 304 and inflation tube 306 pump to thermal insulation locating rack 1 inboard, extrude cabinet door 205 through pressing, simultaneously, it is difficult to make cabinet door and lower support door 205 down to make the ejection of compact along the die, make the ejection of compact because of compact is difficult to make down along the cabinet door side between the lower support mould 201.

The foregoing is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, and any modification, equivalent replacement, and improvement of some of the technical features described in the foregoing embodiments are all within the scope of the present utility model.

Claims (6)

1. The utility model provides a cabinet door compression molding device of power cabinet, includes heat preservation locating rack (1), upper bracket (2) and heat preservation gas receiver (3), its characterized in that: the heat preservation locating rack (1) is interior both ends rotation joint has first sealing baffle (104) and second sealing baffle (105), the joint has last support frame (2) to run through at heat preservation locating rack (1) top, go up support frame (2) inboard grafting and have hot pressing mould (204), the joint has lower support frame (201) to run through at heat preservation locating rack (1) bottom, lower support frame (201) inboard grafting has lower support mould (205), heat preservation locating rack (1) one side joint is fixed with heat preservation gas receiver (3), heat preservation locating rack (1) one side both ends run through the joint respectively and have first high-pressure air pump (301) and second high-pressure air pump (302), lower support frame (201) bottom side runs through the joint has third high-pressure air pump (303).

2. The cabinet door compression molding device of a power cabinet according to claim 1, wherein: the utility model discloses a heat preservation locating rack, including heat preservation locating rack (1), feed inlet (101) and discharge gate (103) have been seted up in running through respectively at heat preservation locating rack (1) both ends, it has a plurality of spacing (102) to peg graft at heat preservation locating rack (1) inboard top, first sealing baffle (104) are located feed inlet (101) one end of heat preservation locating rack (1), first sealing baffle (104) laminating in spacing (102) for feed inlet (101) opposite side, second sealing baffle (105) are located discharge gate (103) one end of heat preservation locating rack (1), second sealing baffle (105) laminating between spacing (102) and discharge gate (103).

3. The cabinet door compression molding device of a power cabinet according to claim 1, wherein: the upper side of the upper supporting frame (2) is penetrated and clamped with a first air cylinder (202), the upper hot-pressing die (204) is slidably clamped at the bottom of the first air cylinder (202), the bottom end of the lower supporting frame (201) is penetrated and clamped with a second air cylinder (203), the lower supporting die (205) is slidably clamped at the top of the second air cylinder (203), and the upper hot-pressing die (204) is suspended at the upper end of the lower supporting die (205).

4. The cabinet door compression molding device of a power cabinet according to claim 1, wherein: the novel high-pressure air storage device is characterized in that an air charging pipe (306) is fixedly connected to one end of the first high-pressure air pump (301) in a clamping mode, a first vent pipe (304) is fixedly connected to the outer peripheral face of the first high-pressure air pump (301) in a clamping mode, the other end of the first vent pipe (304) penetrates through the side of the heat-preservation air storage box (3), one end of the air charging pipe (306) penetrates through the side of the heat-preservation locating rack (1) in a clamping mode, and the air charging pipe (306) is located between the first sealing baffle plate (104) and the upper supporting frame (2).

5. The cabinet door compression molding device of a power cabinet according to claim 1, wherein: the air pump is characterized in that an air extraction pipe (307) is fixedly connected to one end of the second high-pressure air pump (302) in a clamping mode, a second vent pipe (305) is fixedly connected to the outer peripheral face of the second high-pressure air pump (302) in a clamping mode, the other end of the second vent pipe (305) penetrates through and is connected to one side of the heat-preserving air storage tank (3) in a clamping mode, one end of the air extraction pipe (307) penetrates through and is connected to one side of the heat-preserving locating frame (1) in a clamping mode, and the air extraction pipe (307) is located between the upper supporting frame (2) and the second sealing baffle (105).

6. The cabinet door compression molding device of a power cabinet according to claim 1, wherein: the top joint of third high-pressure air pump (303) has bellows (308), bellows (308) top joint has check valve (309), check valve (309) run through joint in lower support mould (205) bottom, third high-pressure air pump (303) outer peripheral face joint has third tee bend trachea (310), third tee bend trachea (310) other end runs through the joint in heat preservation gas receiver (3) one side.