CN111416291A

CN111416291A - Outdoor power distribution cabinet

Info

Publication number: CN111416291A
Application number: CN202010414588.0A
Authority: CN
Inventors: 宋天娇
Original assignee: Harbin Shanliang Stainless Steel Products Co ltd
Current assignee: BAODING FUYANG ELECTRIC POWER TECHNOLOGY Co.,Ltd.
Priority date: 2020-05-15
Filing date: 2020-05-15
Publication date: 2020-07-14
Anticipated expiration: 2040-05-15
Also published as: CN111416291B

Abstract

The invention relates to a power distribution cabinet, in particular to an outdoor power distribution cabinet, which comprises a power distribution cabinet, a sliding door, a mounting bracket, a lifting mechanism, an ash cleaning mechanism, an air inlet mechanism and an air outlet mechanism.

Description

Outdoor power distribution cabinet

Technical Field

The invention relates to a power distribution cabinet, in particular to an outdoor power distribution cabinet.

Background

For example, publication No. CN208923619U discloses a distribution box with distribution box mounting bracket and radiating effect is good, including distribution box mounting bracket and install in the distribution box casing on the distribution box mounting bracket. The utility model can be adjusted according to the size of the distribution box, and is suitable for distribution boxes with various models and sizes; besides the side vent holes arranged on the side wall of the distribution box shell, the middle part of the top wall of the distribution box shell is provided with a top vent hole, a gap is reserved between the bottom wall of the distribution box shell and the distribution box mounting frame, and the bottom wall of the distribution box shell is provided with a bottom vent hole; the utility model discloses a shortcoming is that can not carry out the deashing to the switch board and electrical components forced air cooling in it.

Disclosure of Invention

The invention aims to provide an outdoor power distribution cabinet, which can be used for carrying out dust removal on the power distribution cabinet and air cooling on electrical components in the power distribution cabinet.

The purpose of the invention is realized by the following technical scheme:

the utility model provides an outdoor switch board, includes switch board, sliding door, installing support, elevating system, deashing mechanism, air inlet mechanism and air-out mechanism, the front side sliding connection of switch board has the sliding door, and sliding connection has the installing support in the switch board, and installing support sliding connection is connected with elevating system on the sliding door, and last fixedly connected with deashing mechanism of elevating system is connected with air inlet mechanism on the switch board, and air inlet mechanism can be with in the switch board is inhaled to wind, and air-out mechanism can take out the switch board with wind.

As further optimization of the technical scheme, the outdoor power distribution cabinet comprises two power distribution cavities, four sliding tracks I, four supporting frames, a sliding track II, two sliding cavities, a sensor and a bidirectional threaded rod, wherein the two power distribution cavities are connected in a sliding mode, the four sliding tracks I are fixedly connected into the two power distribution cavities respectively, the sliding tracks II are fixedly connected into the two power distribution cavities respectively, the supporting frames are fixedly connected onto the sliding cavities, the sensor is fixedly connected onto the supporting frames, the bidirectional threaded rod is rotatably connected onto the sliding cavities, the two power distribution cavities are connected onto two ends of the bidirectional threaded rod respectively through threads, and the thread turning directions of two ends of the bidirectional threaded rod are opposite.

As a further optimization of the technical scheme, the outdoor power distribution cabinet comprises two sliding doors, sliding rails, sliding plates I, sliding columns I, pushing columns, pushing rings, sliding columns II, cross insertion shafts and cross insertion holes, wherein the sliding doors are provided with four sliding plates I which are connected between the two sliding doors in a sliding mode, the four sliding rails are fixedly connected to the two sliding doors respectively, the four sliding rails are respectively connected into the four sliding rails I in a sliding mode, the sliding columns I are fixedly connected to the sliding plates I, the two sliding doors are both connected to the sliding columns I in a sliding mode, compression springs are fixedly connected between the two sliding doors and the sliding plates I, the pushing columns are fixedly connected to the sliding plates I, the two pushing rings are fixedly connected to the pushing columns, the sliding columns II are fixedly connected to the two sliding doors, the cross insertion shafts are fixedly connected to one of the sliding columns II, and a cross jack is arranged on the other sliding column II, a cross inserting shaft is connected in the cross jack in a sliding manner, and the two sliding columns II, the cross inserting shaft and the cross jack form a lifting slide rail.

As a further optimization of the technical scheme, the outdoor power distribution cabinet comprises two mounting bottom plates and two sliding plates II, the two mounting bottom plates are connected with the sliding plates II in a sliding mode, the two mounting bottom plates are respectively connected onto the two sliding rails II in a sliding mode, the pushing columns are connected onto the sliding plates II in a sliding mode, the sliding plates II are located between the two pushing rings, and the two pushing rings can push the sliding plates II to slide.

As a further optimization of the technical scheme, the outdoor power distribution cabinet comprises a lifting mechanism, a lifting motor and a lifting drum, wherein the lifting mechanism comprises a lifting support, the lifting motor and a lifting drum, the lifting support is slidably connected to a lifting slide rail formed by two sliding columns ii, a cross insertion shaft and a cross insertion hole, the lifting motor is fixedly connected to the lifting support, the lifting motor is a motor with double output shafts, the lifting drum is fixedly connected to two ends of an output shaft of the lifting motor, steel wire ropes are wound on the two lifting drums, and two ends of the two steel wire ropes are respectively and fixedly connected to two sliding door bodies.

As a further optimization of the technical scheme, the outdoor power distribution cabinet comprises the ash removal mechanism, the ash removal support, the ash suction barrel, the ash suction fan and the ash suction motor, wherein the extension mechanism is fixedly connected to the lifting support, the ash removal support is fixedly connected to the extension end of the extension mechanism, the ash removal brush is fixedly connected to the ash removal support, the lower end of the ash removal support is rotatably connected with the two ash suction barrels, the two ash suction barrels are respectively provided with a plurality of ash suction holes, the outer ends of the two ash suction barrels are rotatably connected with the ash suction fan, the ash suction motor is fixedly connected to the ash removal support, and the two ash suction fans are in transmission connection with an output shaft of the ash suction motor.

As a further optimization of the technical scheme, the outdoor power distribution cabinet comprises an air inlet mechanism and an air inlet fan, wherein the air inlet fan is rotatably connected to the power distribution cavity on the upper side, the air inlet motor is in transmission connection with the air inlet fan, the air inlet motor is fixedly connected to the power distribution cavity on the upper side, and the air inlet motor is connected with the sensor.

As a further optimization of the technical scheme, the outdoor power distribution cabinet comprises an air outlet mechanism and an air outlet fan, wherein the air outlet mechanism comprises an air outlet shaft and an air outlet fan, the air outlet shaft is rotatably connected to the power distribution cavity on the upper side, the air outlet fan is rotatably connected to the power distribution cavity on the lower side, the air outlet fan is in transmission connection with the air outlet shaft, and the air outlet shaft is in transmission connection with the air inlet motor.

The outdoor power distribution cabinet has the beneficial effects that:

according to the outdoor power distribution cabinet, the device can be opened by sliding the sliding door on the power distribution cabinet, the sliding door can pull the mounting bracket to slide while sliding the device, the mounting bracket can slide to the front end of the power distribution cabinet, the lifting mechanism can drive the ash cleaning mechanism to lift on the sliding door, the ash cleaning mechanism can clean ash on the mounting bracket, the mounting bracket is driven to slide backwards when the sliding door slides backwards, the mounting bracket can extrude a sensor, the air inlet mechanism and the air outlet mechanism move when the sensor is extruded, the air inlet mechanism can suck air into the power distribution cabinet, and the air outlet mechanism can draw the air out of the power distribution cabinet.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

Fig. 1 is a schematic view of the overall structure of the outdoor power distribution cabinet of the invention;

FIG. 2 is a schematic view of a partial structure of the outdoor power distribution cabinet of the present invention;

FIG. 3 is a first schematic diagram of the structure of the power distribution cabinet of the present invention;

FIG. 4 is a schematic diagram of a power distribution cabinet structure according to the present invention;

FIG. 5 is a first schematic view of the sliding door structure of the present invention;

FIG. 6 is a second schematic view of the sliding door structure of the present invention;

FIG. 7 is a schematic view of the mounting bracket configuration of the present invention;

FIG. 8 is a schematic view of the lift mechanism of the present invention;

FIG. 9 is a schematic view of the ash removal mechanism of the present invention;

FIG. 10 is a schematic view of the air intake mechanism of the present invention;

fig. 11 is a schematic structural view of the air outlet mechanism of the present invention.

In the figure: a power distribution cabinet 1; a power distribution cavity 101; a sliding track I102; a sliding rail II 103; a sliding chamber 104; a support frame 105; a sensor 106; a bidirectional threaded rod 107; a sliding door 2; a sliding door body 201; a slide rail 202; a sliding plate I203; a sliding column I204; a push post 205; a push ring 206; a sliding column II 207; a cross plug shaft 208; a cross-shaped jack 209; a mounting bracket 3; mounting a base plate 301; a sliding plate II 302; a lifting mechanism 4; a lifting bracket 401; a lift motor 402; a lifting drum 403; an ash removal mechanism 5; a telescoping mechanism 501; a soot cleaning support 502; an ash suction cylinder 503; an ash suction fan 504; a dust suction motor 505; an air inlet mechanism 6; an air intake motor 601; an intake fan 602; an air outlet mechanism 7; an air outlet shaft 701; an air outlet fan 702.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 11, and an outdoor power distribution cabinet includes a power distribution cabinet 1, a sliding door 2, a mounting bracket 3, a lifting mechanism 4, an ash removal mechanism 5, an air intake mechanism 6 and an air exhaust mechanism 7, wherein the sliding door 2 is slidably connected to the front side of the power distribution cabinet 1, the mounting bracket 3 is slidably connected to the sliding door 2, the lifting mechanism 4 is connected to the sliding door 2, the ash removal mechanism 5 is fixedly connected to the lifting mechanism 4, the air intake mechanism 6 is connected to the power distribution cabinet 1, the air intake mechanism 6 can suck air into the power distribution cabinet 1, and the air exhaust mechanism 7 can draw air out of the power; can slide on switch board 1 through sliding door 2 and make the device open, sliding door 2 can stimulate installing support 3 to slide when sliding the opening device, installing support 3 can slide to the front end of switch board 1, elevating system 4 can drive deashing mechanism 5 and go up and down on sliding door 2, deashing mechanism 5 can carry out the deashing to installing support 3, sliding door 2 drives installing support 3 and slides backward when sliding backward, installing support 3 can extrude sensor 106, air inlet mechanism 6 and air outlet mechanism 7 move when sensor 106 receives the extrusion, air inlet mechanism 6 can be with in the wind suction switch board 1, air outlet mechanism 7 can take out wind out switch board 1.

The second embodiment is as follows:

this embodiment will be described with reference to fig. 1 to 11, which further illustrate the first embodiment, switch board 1 includes distribution cavity 101, slip track I102, slip track II 103, slip cavity 104, support frame 105, sensor 106 and two-way threaded rod 107, distribution cavity 101 is provided with two, sliding connection has slip cavity 104 between two distribution cavities 101, slip track I102 is provided with four, four slip track I102 difference fixed connection are in two distribution cavities 101, equal fixedly connected with slip track II 103 in two distribution cavities 101, fixedly connected with support frame 105 on the slip cavity 104, fixedly connected with sensor 106 on the support frame 105, it is connected with two-way threaded rod 107 to rotate on the slip cavity 104, two distribution cavities 101 are respectively through threaded connection at the both ends of two-way threaded rod 107, the screw thread at two-way threaded rod 107 both ends is turned to opposite directions.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 11, and the embodiment further describes the second embodiment, where the sliding door 2 includes two sliding door bodies 201, four sliding rails 202, four sliding rails 203, four sliding columns i 204, four pushing columns 205, two pushing rings 206, two sliding columns ii 207, a cross insertion shaft 208, and a cross insertion hole 209, the two sliding door bodies 201 are provided, the sliding plate i 203 is slidably connected between the two door bodies 201, the four sliding rails 202 are provided with four sliding rails 202, the four sliding rails 202 are respectively and fixedly connected to the two sliding door bodies 201, the four sliding rails 202 are respectively and slidably connected to the four sliding rails i 102, the sliding column i 204 is fixedly connected to the sliding plate i 203, the two sliding door bodies 201 are both slidably connected to the sliding column i 204, compression springs are fixedly connected between the two sliding door bodies 201 and the sliding plate i 203, the pushing column 205 is fixedly connected to the sliding plate i 203, the two pushing, equal fixedly connected with slip post II 207 on two sliding door bodies 201, fixedly connected with cross on one of them slip post II 207 inserts axle 208, is provided with cross jack 209 on another slip post II 207, and cross insert axle 208 sliding connection is in cross jack 209, and two slip posts II 207, cross insert axle 208 and cross jack 209 constitute the lift slide rail.

The fourth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 11, and the present embodiment further describes an embodiment three, where the mounting bracket 3 includes two mounting bottom plates 301 and two sliding plates ii 302, the two mounting bottom plates 301 are slidably connected to the sliding plates ii 302, the two mounting bottom plates 301 are respectively slidably connected to the two sliding rails ii 103, the pushing column 205 is slidably connected to the sliding plate ii 302, the sliding plate ii 302 is located between the two pushing rings 206, and the two pushing rings 206 can push the sliding plate ii 302 to slide.

The fifth concrete implementation mode:

the fourth embodiment is described below with reference to fig. 1 to 11, and the fourth embodiment is further described in the present embodiment, where the lifting mechanism 4 includes a lifting support 401, a lifting motor 402 and a lifting reel 403, the lifting support 401 is slidably connected to a lifting slide rail formed by two sliding columns ii 207, a cross insertion shaft 208 and a cross insertion hole 209, the lifting support 401 is fixedly connected to the lifting motor 402, the lifting motor 402 is a motor with two output shafts, the two ends of an output shaft of the lifting motor 402 are both fixedly connected to the lifting reel 403, the two lifting reels 403 are both wound with steel wire ropes, and the two ends of the two steel wire ropes are respectively and fixedly connected to the two pulling door bodies 201.

The sixth specific implementation mode:

the following describes the present embodiment with reference to fig. 1 to 11, and the fifth embodiment is further described in the present embodiment, where the ash removal mechanism 5 includes a telescopic mechanism 501, an ash removal support 502, an ash suction cylinder 503, an ash suction fan 504 and an ash suction motor 505, the telescopic mechanism 501 is fixedly connected to the lifting support 401, the telescopic end of the telescopic mechanism 501 is fixedly connected to the ash removal support 502, the ash removal support 502 is fixedly connected to an ash removal brush, the lower end of the ash removal support 502 is rotatably connected to two ash suction cylinders 503, both the two ash suction cylinders 503 are provided with a plurality of ash suction holes, the outer ends of both the two ash suction cylinders 503 are rotatably connected to the ash suction fan 504, the ash removal support 502 is fixedly connected to the ash suction motor 505, and both the two ash suction fans 504 are in transmission connection with the output shaft of the ash suction motor 505.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 11, and the sixth embodiment is further described in the present embodiment, where the air intake mechanism 6 includes an air intake motor 601 and an air intake fan 602, the air intake fan 602 is rotatably connected to the power distribution cavity 101 located on the upper side, the air intake motor 601 is in transmission connection with the air intake fan 602, the air intake motor 601 is fixedly connected to the power distribution cavity 101 located on the upper side, and the air intake motor 601 is connected to the sensor 106.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 11, and the seventh embodiment is further described in the present embodiment, where the air outlet mechanism 7 includes an air outlet shaft 701 and an air outlet fan 702, the air outlet shaft 701 is rotatably connected to the power distribution cavity 101 located on the upper side, the air outlet fan 702 is rotatably connected to the power distribution cavity 101 located on the lower side, the air outlet fan 702 is in transmission connection with the air outlet shaft 701, and the air outlet shaft 701 is in transmission connection with the air inlet motor 601.

The invention relates to an outdoor power distribution cabinet, which has the working principle that:

when the sliding door 2 is covered on the power distribution cabinet 1 in use, the four sliding rails 202 respectively slide on the four sliding rails I102, the sliding door body 201 is in contact with the power distribution cavity 101, the device is in a closed state, the pushing ring 206 positioned at the front side pushes the sliding plate II 302 to slide backwards, the sliding plate II 302 drives the mounting bracket 3 to slide between the two sliding rails II 103 when sliding backwards, the sliding plate II 302 extrudes the sensor 106 when sliding backwards to a limit position, the sensor 106 can be a pressure sensor or a contact sensor when being extruded, the air intake motor 601 is connected with the sensor 106, the sensor 106 is electrically connected with the air intake motor 601 through technical means in the field, the air intake motor 601 is started to rotate when the sensor 106 is extruded or pressed, and the air intake fan 602 is driven to rotate when the air intake motor 601 rotates, air is sucked into the power distribution cabinet 1 when the air inlet fan 602 rotates, the air outlet shaft 701 is driven to rotate when the output shaft of the air inlet motor 601 rotates, the air outlet shaft 701 drives the air outlet fan 702 to rotate when the air outlet shaft 701 rotates, air in the power distribution cabinet 1 is discharged when the air outlet fan 702 rotates, wind power circulation is formed between the air inlet fan 602 and the air outlet fan 702, the mounting bracket 3 is positioned between the air inlet fan 602 and the air outlet fan 702, an electrical component can be mounted on the mounting bracket 3, and the air inlet fan 602 and the air outlet fan 702 cool the mounting bracket 3 when the device is in a closed state; the two-way threaded rod 107 is rotated, the two power distribution cavities 101 are respectively connected to two ends of the two-way threaded rod 107 through threads, the thread turning directions of the two ends of the two-way threaded rod 107 are opposite, the two power distribution cavities 101 are driven to move through the threads when the two-way threaded rod 107 rotates, when the two power distribution cavities 101 can be close to or far away from each other and the distance between the two power distribution cavities 101 changes, the two power distribution cavities 101 respectively drive the two zipper bodies 201 to rotate, the two installation bottom plates 301 are driven to move when the two zipper bodies 201 move, and the use size of the device is adjusted; when the device needs to clean ash, the sliding door 2 is pulled backwards, the sliding door 2 moves backwards for a certain distance to push the ring 206 to be contacted with the sliding plate II 302, the sliding plate II 302 moves backwards under the pulling force of the sliding door 2, the sliding plate II 302 is separated from the sensor 106, the sensor 106 is not extruded by the ash suction motor 505 any longer and does not rotate, and the air inlet mechanism 6 and the air outlet mechanism 7 do not move any longer; when the sliding plate II 302 slides backwards to the limit position, the lifting motor 402 is started, the output shaft of the lifting motor 402 starts to rotate, the output shaft of the lifting motor 402 drives the lifting drums 403 to rotate, when the two lifting drums 403 rotate, one of the two lifting drums 403 receives the steel wire rope, the other lifting drum 403 discharges the steel wire rope, the steel wire rope is wound on each of the two lifting drums 403, two ends of each of the two steel wire ropes are fixedly connected to the two sliding door bodies 201 respectively, the sliding door bodies 201 are fixedly connected with the sliding columns II 207, one of the sliding columns II 207 is fixedly connected with the cross insertion shaft 208, the other sliding column II 207 is provided with the cross insertion hole 209, the cross insertion shaft 208 is slidably connected into the cross insertion hole 209, the two sliding columns II 207, the cross insertion shaft 208 and the cross insertion hole 209 form a lifting slide rail, and the two lifting drums 403 drive the ash removing mechanism 5 to, the lifting mechanism 4 can drive the ash removing mechanism 5 to lift on the sliding door 2; start telescopic machanism 501, telescopic machanism 501 can be pneumatic cylinder or electric putter, telescopic machanism 501's flexible end drives deashing support 502 and moves, fixedly connected with deashing brush on the deashing support 502, deashing brush and electrical components contact, the deashing brush is driven to move during elevating system 4 motion, the deashing brush is deashing about going on electrical components, start ash suction motor 505, ash suction motor 505's output shaft rotates, ash suction motor 505's output shaft drives ash suction fan 504 and rotates, produce the wind-force of inhaling the dust when ash suction fan 504 rotates, all be provided with a plurality of suction holes on two ash suction barrels 503, two ash suction barrels 503 can be with the dust suction device that the deashing brush cleared up.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides an outdoor switch board, includes switch board (1), sliding door (2), installing support (3), elevating system (4), deashing mechanism (5), air inlet mechanism (6) and air-out mechanism (7), its characterized in that: the front side of switch board (1) sliding connection has sliding door (2), and sliding connection has installing support (3) in switch board (1), and installing support (3) sliding connection is on sliding door (2), is connected with elevating system (4) on sliding door (2), fixedly connected with deashing mechanism (5) on elevating system (4), is connected with air inlet mechanism (6) on switch board (1), and air inlet mechanism (6) can be with wind suction switch board (1) in, and air-out mechanism (7) can take wind out switch board (1).

2. An outdoor switch board of claim 1 characterized in that: the power distribution cabinet (1) comprises power distribution cavities (101), two sliding tracks I (102), two sliding tracks II (103), sliding cavities (104), support frames (105), sensors (106) and a bidirectional threaded rod (107), wherein the number of the power distribution cavities (101) is two, the sliding cavities (104) are connected between the two power distribution cavities (101) in a sliding mode, the number of the sliding tracks I (102) is four, the four sliding tracks I (102) are respectively and fixedly connected into the two power distribution cavities (101), the sliding tracks II (103) are respectively and fixedly connected into the two power distribution cavities (101), the support frames (105) are fixedly connected onto the sliding cavities (104), the sensors (106) are fixedly connected onto the support frames (105), the bidirectional threaded rod (107) is rotatably connected onto the sliding cavities (104), and the two power distribution cavities (101) are respectively connected onto two ends of the bidirectional threaded rod (107, the two-way threaded rod (107) has opposite thread directions at both ends.

3. An outdoor switch board of claim 2 characterized in that: the sliding door (2) comprises sliding door bodies (201), sliding rails (202), sliding plates I (203), sliding columns I (204), pushing columns (205), pushing rings (206), sliding columns II (207), cross insertion shafts (208) and cross insertion holes (209), two sliding plates I (203) are arranged between the two door bodies (201), four sliding rails (202) are arranged between the two door bodies (201), the four sliding rails (202) are respectively and fixedly connected to the two sliding door bodies (201), the four sliding rails (202) are respectively and slidably connected into the four sliding rails I (102), the sliding plates I (203) are fixedly connected with the sliding columns I (204), the two sliding door bodies (201) are respectively and slidably connected to the sliding columns I (204), compression springs are fixedly connected between the two sliding door bodies (201) and the sliding plates I (203), the pushing columns (205) are fixedly connected to the sliding plates I (203), two propelling rings (206) of fixedly connected with on the promotion post (205), equal fixedly connected with slip post II (207) on two sliding door bodies (201), fixedly connected with cross plug shaft (208) on one of them slip post II (207), be provided with cross jack (209) on another slip post II (207), cross plug shaft (208) sliding connection is in cross jack (209), two slip post II (207), cross plug shaft (208) and cross jack (209) constitute the lift slide rail.

4. An outdoor switch board of claim 3 characterized in that: the mounting bracket (3) comprises mounting bottom plates (301) and sliding plates II (302), the two mounting bottom plates (301) are arranged, the sliding plates II (302) are connected between the two mounting bottom plates (301) in a sliding mode, the two mounting bottom plates (301) are respectively connected onto the two sliding rails II (103) in a sliding mode, the pushing columns (205) are connected onto the sliding plates II (302) in a sliding mode, the sliding plates II (302) are located between the two pushing rings (206), and the two pushing rings (206) can push the sliding plates II (302) to slide.

5. An outdoor switch board of claim 4 characterized in that: elevating system (4) are including lifting support (401), elevator motor (402) and lift reel (403), lifting support (401) sliding connection is on two slip post II (207), the cross is inserted on the lift slide rail of axle (208) and cross jack (209) constitution, fixedly connected with elevator motor (402) on lifting support (401), elevator motor (402) are dual output shaft motor, the equal fixedly connected with lift reel (403) in both ends of elevator motor (402) output shaft, all twine wire rope on two lift reels (403), two wire rope's both ends difference fixed connection is on two zipper body (201).

6. An outdoor switch board of claim 5 characterized in that: the ash removal mechanism (5) comprises a telescopic mechanism (501), an ash removal support (502), ash suction cylinders (503), an ash suction fan (504) and an ash suction motor (505), wherein the telescopic mechanism (501) is fixedly connected to the lifting support (401), the telescopic end of the telescopic mechanism (501) is fixedly connected with the ash removal support (502), an ash removal brush is fixedly connected to the ash removal support (502), the lower end of the ash removal support (502) is rotatably connected with the two ash suction cylinders (503), the two ash suction cylinders (503) are provided with a plurality of ash suction holes, the outer ends of the two ash suction cylinders (503) are rotatably connected with the ash suction fan (504), the ash removal support (502) is fixedly connected with the ash suction motor (505), and the two ash suction fans (504) are in transmission connection with an output shaft of the ash suction motor (505).

7. An outdoor switch board of claim 6 characterized in that: air inlet mechanism (6) are including air inlet motor (601) and air inlet fan (602), and air inlet fan (602) rotate to be connected on distribution cavity (101) that are located the upside, and air inlet motor (601) and air inlet fan (602) transmission are connected, and air inlet motor (601) fixed connection is on distribution cavity (101) that are located the upside, and air inlet motor (601) and sensor (106) are connected.

8. An outdoor switch board of claim 7 characterized in that: air-out mechanism (7) are including air-out axle (701) and air-out fan (702), and air-out axle (701) rotates to be connected on distribution cavity (101) that are located the upside, and air-out fan (702) rotates to be connected on distribution cavity (101) that are located the downside, and air-out fan (702) and air-out axle (701) transmission are connected, and air-out axle (701) and air inlet motor (601) transmission are connected.