CN111564770A - High-low voltage power distribution cabinet - Google Patents

Abstract

The invention relates to a power distribution cabinet, in particular to a high-low voltage power distribution cabinet, which comprises a device support, a positioning mechanism, a traversing mechanism, a mounting mechanism I, a lifting mechanism, a lifting support, a mounting mechanism II, a power distribution cabinet and a sensor, wherein the power distribution cabinet with different lengths and widths can be clamped through a plurality of mounting mechanisms I and a plurality of mounting mechanisms II, the traversing mechanism can drive the mounting mechanism I to transversely move, the mounting mechanism I drives the power distribution cabinet on the mounting mechanism I to transversely move, the number of the mounting mechanisms II is one more than that of the mounting mechanisms I, the mounting mechanism II can lift, the mounting mechanism II drives the power distribution cabinet on the mounting mechanism II to lift, any power distribution cabinet positioned on the mounting mechanism II can fall to the lower side through the movement of the plurality of traversing mechanisms, the power distribution cabinet on the upper side is convenient, so that the device can be suitable for power distribution cabinets with different heights.

Description

High-low voltage power distribution cabinet

Technical Field

The invention relates to a power distribution cabinet, in particular to a high-low voltage power distribution cabinet.

Background

For example, publication number CN210468398U is low-voltage distribution cabinet frame for outdoor use relates to outdoor use low-voltage distribution cabinet auxiliary device technical field, for solving the staff and dismantling the low-voltage distribution cabinet frame convenient and increase staff's working strength's problem inadequately. A sensor placing groove is formed in one end of the low-voltage distribution cabinet frame, four illumination induction lamps are arranged above the low-voltage distribution cabinet frame, a rubber sealing block is arranged above the low-voltage distribution cabinet frame and fixedly connected with the low-voltage distribution cabinet frame, fixed column movable grooves are formed in the rubber sealing block and the low-voltage distribution cabinet frame, four fixed column movable grooves are formed in the rubber sealing block and the low-voltage distribution cabinet frame, a rainproof top cover is arranged above the low-voltage distribution cabinet frame, top cover fixed columns are arranged at four corners below the rainproof top cover and fixedly connected with the rainproof top cover; the utility model discloses a shortcoming is the position that can not adjust the switch board according to the user demand of difference.

Disclosure of Invention

The invention aims to provide a high-low voltage power distribution cabinet, which can adjust the positions of power distribution cabinets with different sizes according to different use requirements.

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

a high-low voltage power distribution cabinet comprises a device bracket, a positioning mechanism, a transverse moving mechanism, an installation mechanism I, a lifting mechanism, a lifting bracket, an installation mechanism II, a power distribution cabinet and a sensor, fixedly connected with positioning mechanism on the device support, be connected with a plurality of sideslip mechanisms on the device support, all be connected with installation mechanism I on every installation mechanism I, all be connected with the switch board on every installation mechanism I, it is connected with elevating system to rotate on the device support, there is lifting support through threaded connection on the elevating system, a plurality of installation mechanism II of fixedly connected with on the lifting support, all be connected with the switch board on a plurality of installation mechanism II, the quantity of installation mechanism II is more one than the quantity of sideslip mechanism, a plurality of sensors of fixedly connected with on the device support, the quantity of sensor equals with the quantity of installation mechanism II, a plurality of sensors respectively with all a plurality of installation mechanism II connections.

According to the high-low voltage power distribution cabinet, the device support comprises a rectangular support I, racks, sliding supports, sliding waist holes and a connecting plate, the racks are fixedly connected to the front side and the rear side of the rectangular support I, the sliding supports are fixedly connected to the front side and the rear side of the rectangular support I, the sliding waist holes are formed in the two sliding supports, the connecting plate is fixedly connected to the middle of the rectangular support I, and a plurality of sensors are fixedly connected to the connecting plate.

As a further optimization of the technical scheme, the high-low voltage power distribution cabinet comprises a positioning mechanism, a positioning sliding column and a spring baffle, wherein the positioning base plate is fixedly connected to the rectangular support I, the positioning base plate is fixedly connected with a plurality of positioning sliding columns, the number of the positioning sliding columns is equal to that of the sensors, the spring baffle is fixedly connected to each of the plurality of positioning sliding columns, a compression spring is fixedly connected between the spring baffle and the positioning base plate, a round ball is arranged at the upper end of the positioning base plate, and the sensors are extruded when the positioning sliding columns slide downwards.

As further optimization of the technical scheme, the invention discloses a high-low voltage power distribution cabinet, wherein a transverse moving mechanism comprises a transverse moving bracket, a sliding cylinder and a transverse moving shaft, sideslip slider, sideslip gear and sideslip motor, the equal fixedly connected with slide cartridge in both ends around the sideslip support upside, the left and right sides of sideslip support all rotates and is connected with the sideslip axle, it is connected with two sideslip sliders all to rotate on two sideslip axles, two sideslip gears of equal fixedly connected with on two sideslip axles, sideslip motor fixed connection is on the sideslip slider of one side, the output shaft and one of them sideslip axle fixed connection of sideslip motor, the sideslip mechanism is provided with a plurality ofly, a plurality of sideslip sliders of both sides are sliding connection respectively in two slip waist holes around, a plurality of sideslip gears of both sides are respectively with two rack toothing transmissions around, the lower extreme of sideslip support is provided with the circular arc groove, the circular arc inslot.

As the technical scheme is further optimized, the high-low voltage power distribution cabinet comprises a mounting mechanism I, a telescopic mechanism I, sliding columns, side plates I, a mounting threaded rod I and a mounting plate I, wherein the telescopic end of the telescopic mechanism I is fixedly connected with the mounting plate I, the lower end of the mounting plate I is fixedly connected with two sliding columns, the upper end of the mounting plate I is fixedly connected with four side plates I, the four side plates I are respectively connected with the mounting threaded rod I through threads, the inner side of each mounting threaded rod I is rotatably connected with the mounting plate I, the four mounting plates I are respectively connected onto the mounting plate I in a sliding mode, each transverse support is respectively and fixedly connected with the telescopic mechanism I, and the sliding columns are slidably connected into the corresponding sliding cylinders.

As a further optimization of the technical scheme, the high-low voltage power distribution cabinet comprises four rotating cylinders and four synchronous belt wheels, wherein the four rotating cylinders are fixedly connected with the synchronous belt wheels, the four synchronous belt wheels are in transmission connection, the transmission ratio of the four synchronous belt wheels is one, and the four rotating cylinders are all in transmission connection with a rectangular support I.

As a further optimization of the technical scheme, the high-low voltage power distribution cabinet comprises a lifting support, wherein the lifting support comprises a rectangular support II, a connecting bottom plate and lifting threaded rods, the rectangular support II is fixedly connected with a plurality of connecting bottom plates, the rectangular support II is fixedly connected with four lifting threaded rods, and the four lifting threaded rods are respectively connected into four rotating cylinders through threads.

According to the high-low voltage power distribution cabinet, the mounting mechanism II comprises a mounting bottom plate II, a telescopic mechanism II, side plates II, mounting threaded rods II and a mounting plate II, the telescopic end of the telescopic mechanism II is fixedly connected with the mounting bottom plate II, the four side plates II are fixedly connected onto the mounting bottom plate II, the mounting threaded rods II are connected onto the four side plates II through threads, the mounting plate II is rotatably connected onto the inner sides of the four mounting threaded rods II, the four mounting plates II are slidably connected onto the mounting bottom plate II, the telescopic mechanisms II are fixedly connected onto the connecting bottom plates, and the telescopic mechanisms II are respectively connected with the sensors.

The high-low voltage power distribution cabinet has the beneficial effects that:

according to the high-low voltage power distribution cabinet, the power distribution cabinets with different lengths and widths can be clamped through the multiple mounting mechanisms I and the multiple mounting mechanisms II, the transverse moving mechanism can drive the mounting mechanisms I to transversely move, the mounting mechanisms I drive the power distribution cabinets on the mounting mechanisms I to transversely move, the number of the mounting mechanisms II is one more than that of the mounting mechanisms I, the mounting mechanisms II can lift, the mounting mechanisms II drive the power distribution cabinets on the mounting mechanisms II to lift, the power distribution cabinets on the mounting mechanisms II can fall to the lower side through the movement of the multiple transverse moving mechanisms, the power distribution cabinets on the upper side can be conveniently mounted and replaced, and the lifting mechanisms can adjust the heights of the lifting supports, so that the device can be suitable for power distribution cabinets with.

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 diagram of the overall structure of a high-low voltage power distribution cabinet of the invention;

fig. 2 is a schematic view of a partial structure of a high-low voltage power distribution cabinet of the invention;

FIG. 3 is a schematic view of the positioning mechanism of the present invention;

FIG. 4 is a schematic structural view of the traversing mechanism of the present invention;

FIG. 5 is a schematic structural diagram of the mounting mechanism I of the present invention;

FIG. 6 is a schematic view of the lift mechanism of the present invention;

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

FIG. 8 is a schematic structural diagram of the mounting mechanism II of the present invention.

In the figure: a device holder 1; a rectangular bracket I101; a rack 102; a sliding bracket 103; a sliding kidney hole 104; a connecting plate 105; a positioning mechanism 2; a positioning base plate 201; positioning the sliding post 202; a spring retainer 203; a traversing mechanism 3; the bracket 301 is transversely moved; a slide cylinder 302; a traversing shaft 303; a traversing slide block 304; a traverse gear 305; a traverse motor 306; an installation mechanism I4; mounting a bottom plate I401; a telescoping mechanism I402; a sliding post 403; a side plate I404; mounting a threaded rod I405; mounting plate I406; a lifting mechanism 5; a rotary cylinder 501; a timing pulley 502; a lifting bracket 6; a rectangular bracket II 601; a connection base plate 602; a lifting threaded rod 603; an installation mechanism II 7; mounting a bottom plate II 701; a telescoping mechanism II 702; a side plate II 703; mounting a threaded rod II 704; mounting plate II 705; a power distribution cabinet 8; and a sensor 9.

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. 1-8, a high-low voltage power distribution cabinet, which comprises a device support 1, a positioning mechanism 2, a traversing mechanism 3, a mounting mechanism i 4, a lifting mechanism 5, a lifting support 6, a mounting mechanism ii 7, a power distribution cabinet 8 and sensors 9, wherein the positioning mechanism 2 is fixedly connected to the device support 1, the device support 1 is connected with a plurality of traversing mechanisms 3, each mounting mechanism i 4 is connected with a mounting mechanism i 4, each mounting mechanism i 4 is connected with a power distribution cabinet 8, the device support 1 is rotatably connected with the lifting mechanism 5, the lifting mechanism 5 is connected with the lifting support 6 through threads, the lifting support 6 is fixedly connected with a plurality of mounting mechanisms ii 7, the mounting mechanisms ii 7 are connected with power distribution cabinets 8, the number of the mounting mechanisms ii 7 is one more than that of the traversing mechanisms 3, and the device support 1 is fixedly connected with a plurality of sensors 9, the number of the sensors 9 is equal to that of the mounting mechanisms II 7, and the plurality of sensors 9 are respectively connected with the plurality of mounting mechanisms II 7; can carry out the clamping to the switch board 8 that length and width are different through a plurality of installation mechanism I4 and a plurality of installation mechanism II 7, sideslip mechanism 3 can drive installation mechanism I4 and carry out the sideslip, switch board 8 that installation mechanism I4 drove on it carries out the sideslip, the quantity of installation mechanism II 7 is one more than the quantity of installation mechanism I4, installation mechanism II 7 can go up and down, installation mechanism II 7 drives switch board 8 on it and goes up and down, move through a plurality of sideslip mechanisms 3, make arbitrary one be located switch board 8 on installation mechanism II 7 can fall the downside, conveniently install and change the switch board 8 of upside, elevating system 5 can adjust the height of lifting support 6, make the device can be to being applicable to the not switch board 8 of co-altitude.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 8, and the present embodiment further describes the first embodiment, where the apparatus bracket 1 includes a rectangular bracket i 101, a rack 102, a sliding bracket 103, a sliding waist hole 104, and a connecting plate 105, the rack 102 is fixedly connected to both front and rear sides of the rectangular bracket i 101, the sliding bracket 103 is fixedly connected to both front and rear sides of the rectangular bracket i 101, the sliding waist holes 104 are respectively disposed on the two sliding brackets 103, the connecting plate 105 is fixedly connected to a middle portion of the rectangular bracket i 101, and the plurality of sensors 9 are fixedly connected to the connecting plate 105.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 8, and the present embodiment further describes the second embodiment, the positioning mechanism 2 includes a positioning bottom plate 201, positioning sliding columns 202 and a spring baffle 203, the positioning bottom plate 201 is fixedly connected to the rectangular support i 101, a plurality of positioning sliding columns 202 are fixedly connected to the positioning bottom plate 201, the number of the positioning sliding columns 202 is equal to the number of the sensors 9, the spring baffles 203 are fixedly connected to the plurality of positioning sliding columns 202, compression springs are fixedly connected between the spring baffles 203 and the positioning bottom plate 201, an upper end ball of the positioning bottom plate 201 is arranged, and the positioning sliding columns 202 extrude the sensors 9 when sliding downward.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1-8, wherein the traverse mechanism 3 includes a traverse bracket 301, a sliding cylinder 302, a traverse shaft 303, traverse sliders 304, traverse gears 305, and a traverse motor 306, the slide cylinder 302 is fixedly connected to both front and rear ends of the upper side of the traverse bracket 301, the traverse shaft 303 is rotatably connected to both left and right sides of the traverse bracket 301, two traverse sliders 304 are rotatably connected to both the traverse shafts 303, two traverse gears 305 are fixedly connected to both the traverse shafts 303, the traverse motor 306 is fixedly connected to the traverse slider 304 on one side, an output shaft of the traverse motor 306 is fixedly connected to one of the traverse shafts 303, the traverse mechanism 3 is provided with a plurality of traverse sliders 304 on both front and rear sides are respectively slidably connected to the two sliding waist holes 104, the traverse gears 305 on both front and rear sides are respectively engaged with the two racks 102 for transmission, the lower end of the transverse moving support 301 is provided with an arc groove, and the upper end of the positioning bottom plate 201 can be inserted into the arc groove.

The fifth concrete implementation mode:

this embodiment mode will be described below with reference to fig. 1 to 8, and this embodiment mode will further describe a fourth embodiment mode, installation mechanism I4 includes mounting plate I401, telescopic machanism I402, sliding column 403, I404 of curb plate, installation threaded rod I405 and I406 of mounting panel, I401 of fixedly connected with mounting plate is served in telescopic machanism I402's the flexible, two sliding column 403 of the lower extreme fixedly connected with of mounting plate I401, I404 of four curb plates of the upper end fixedly connected with of mounting plate I401, all there is I405 of installation threaded rod through threaded connection on I404 of four curb plates, the inboard of I405 of every installation threaded rod is all rotated and is connected with I406 of mounting panel, the equal sliding connection of I406 of four mounting panels is on I401 of mounting plate, equal I402 of fixedly connected with telescopic machanism on every sideslip support 301, sliding column 403 sliding connection is in the slide barrel 302 of using.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 8, and the fifth embodiment is further described in the present embodiment, the lifting mechanism 5 includes four rotating cylinders 501 and synchronous pulleys 502, the four rotating cylinders 501 are provided with four synchronous pulleys 502, the four synchronous pulleys 502 are fixedly connected to the four rotating cylinders 501, the four synchronous pulleys 502 are in transmission connection, a transmission ratio between the four synchronous pulleys 502 is one, and the four rotating cylinders 501 are all rotatably connected to the rectangular bracket i 101.

The seventh embodiment:

the following describes the present embodiment with reference to fig. 1 to 8, and the present embodiment further describes an embodiment six, where the lifting bracket 6 includes a rectangular bracket ii 601, a connecting bottom plate 602, and lifting threaded rods 603, the rectangular bracket ii 601 is fixedly connected with a plurality of connecting bottom plates 602, the rectangular bracket ii 601 is fixedly connected with four lifting threaded rods 603, and the four lifting threaded rods 603 are respectively connected in the four rotating cylinders 501 through threads.

The specific implementation mode is eight:

the following describes the present embodiment with reference to fig. 1 to 8, and the seventh embodiment is further described in the present embodiment, where the mounting mechanism ii 7 includes a mounting bottom plate ii 701, a telescoping mechanism ii 702, side plates ii 703, a mounting threaded rod ii 704 and a mounting plate ii 705, the telescoping end of the telescoping mechanism ii 702 is fixedly connected with the mounting bottom plate ii 701, the mounting bottom plate ii 701 is fixedly connected with four side plates ii 703, the four side plates ii 703 are all connected with the mounting threaded rod ii 704 through threads, and the inner sides of the four mounting threaded rods ii 704 are all rotatably connected with the mounting plate ii

705, four mounting plates II 705 are all connected on the mounting base plate II 701 in a sliding manner, a plurality of connecting base plates 602 are all fixedly connected with telescopic mechanisms II 702, and the telescopic mechanisms II 702 are respectively connected with a plurality of sensors 9.

The working principle of the high-low voltage power distribution cabinet provided by the invention is as follows:

when the power distribution cabinet is used, the power distribution cabinet 8 is placed on the installation mechanism I4 and the installation mechanism II 7, as shown in figure 1, the number of the installation mechanisms II 7 is one more than that of the installation mechanisms I4, the number of the installation mechanisms I4 is two, the number of the installation mechanisms II 7 is three, the installation threaded rods I405 are rotated, the installation threaded rods I405 push the installation plates I406 to slide on the installation base plate I401 through threads, as shown in FIG. 5, four mounting plates I406 are arranged, four mounting plates I406 are used for clamping four sides of the power distribution cabinet 8, the four mounting plates I406 can be used for clamping power distribution cabinets 8 with different widths and lengths, a mounting threaded rod II 704 is rotated, the mounting threaded rod II 704 pushes a mounting plate II 705 to slide on a mounting base plate II 701 through threads, as shown in fig. 8, four mounting plates ii 705 clamp four sides of the power distribution cabinet 8, and the four mounting plates ii 705 can clamp the power distribution cabinet 8 with different widths and lengths; as shown in fig. 1, a power distribution cabinet 8 is installed on each of three installation mechanisms ii 7 located at the upper side, a power distribution cabinet 8 is installed on each of two installation mechanisms i 4 located at the lower side, the two installation mechanisms i 4 are respectively located at both sides of the device, the upper end of the positioning sliding column 202 located in the middle is not clamped into the traverse support 301, the positioning sliding column 202 located in the middle does not move downwards to press the corresponding sensor 9, the sensor 9 can be a pressing sensor or a pressure sensor, the plurality of telescopic mechanisms ii 702 are respectively connected with the plurality of sensors 9 through electric control, the corresponding telescopic mechanisms ii 702 are cut off by power when the sensors 9 are pressed, which is equivalent to a double switch, the telescopic mechanisms ii 702 can move at the lower side only when the sensors 9 are not pressed, the power distribution cabinet 8 can be protected, and under the condition that the power distribution cabinet 8 exists at the lower side, the mounting mechanism II 7 moves downwards to extrude the power distribution cabinet 8 on the lower side to cause damage; the telescopic mechanism I402 and the telescopic mechanism II 702 can be hydraulic cylinders or electric push rods, when the power distribution cabinet 8 on the lower side needs to be transversely moved, the corresponding transverse moving motor 306 is started, the output shaft of the transverse moving motor 306 starts to rotate, the output shaft of the transverse moving motor 306 drives the corresponding transverse moving shaft 303 to move, the transverse moving shaft 303 drives the corresponding transverse moving gear 305 to rotate, the transverse moving gear 305 moves on the corresponding rack 102 to push the transverse moving mechanism 3 to move on the device support 1, the position of the power distribution cabinet 8 on the lower side is further adjusted, after the position is adjusted, the plurality of transverse moving mechanisms 3 move, any power distribution cabinet 8 on the installation mechanism II 7 can fall to the lower side, the installation mechanism II 7 without the power distribution cabinet 8 on the lower side can be started, the telescopic end of the telescopic mechanism II 702 pushes the installation bottom plate 701 II to move up and down, and the power distribution cabinet 8 on the installation, the power distribution cabinet 8 on the upper side is convenient to install and replace; all fixedly connected with synchronous pulley 502 on four rotating barrel 501, the transmission is connected between four synchronous pulley 502, and the drive ratio between four synchronous pulley 502 is one, rotates one of them rotating barrel 501, and one of them rotating barrel 501 drives four rotating barrel 501 and rotates together, and four rotating barrel 501 promote lifting support 6 through the screw thread when rotating together and go up and down, and elevating system 5 can adjust the height of lifting support 6 for the device can be to being applicable to not switch board 8 of co-altitude.

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 (8)

1. The utility model provides a high-low voltage power distribution cabinet, includes device support (1), positioning mechanism (2), sideslip mechanism (3), installation mechanism I (4), elevating system (5), lifting support (6), installation mechanism II (7), switch board (8) and sensor (9), its characterized in that: fixedly connected with positioning mechanism (2) on device support (1), be connected with a plurality of sideslip mechanisms (3) on device support (1), all be connected with installation mechanism I (4) on every installation mechanism I (4), all be connected with switch board (8) on every installation mechanism I (4), it is connected with elevating system (5) to rotate on device support (1), there is lifting support (6) through threaded connection on elevating system (5), a plurality of installation mechanism II (7) of fixedly connected with on lifting support (6), all be connected with switch board (8) on a plurality of installation mechanism II (7), the quantity of installation mechanism II (7) is more one than the quantity of sideslip mechanism (3), a plurality of sensor of fixedly connected with (9) on device support (1), the quantity of sensor (9) equals with the quantity of installation mechanism II (7), a plurality of sensor (9) are connected with all a plurality of installation mechanism II (7) respectively.

2. A high-low voltage distribution cabinet according to claim 1, characterized in that: the device support (1) comprises a rectangular support I (101), racks (102), sliding supports (103), sliding waist holes (104) and a connecting plate (105), wherein the racks (102) are fixedly connected to the front side and the rear side of the rectangular support I (101), the sliding supports (103) are fixedly connected to the front side and the rear side of the rectangular support I (101), the sliding waist holes (104) are formed in the two sliding supports (103), the connecting plate (105) is fixedly connected to the middle of the rectangular support I (101), and a plurality of sensors (9) are fixedly connected to the connecting plate (105).

3. A high-low voltage distribution cabinet according to claim 2, characterized in that: positioning mechanism (2) are including location bottom plate (201), location slip post (202) and spring baffle (203), location bottom plate (201) fixed connection is on rectangle support I (101), a plurality of location slip posts (202) of fixedly connected with are gone up in location bottom plate (201), the quantity of location slip post (202) and the quantity of sensor (9) equal, equal fixedly connected with spring baffle (203) are gone up in a plurality of location slip posts (202), fixedly connected with compression spring between spring baffle (203) and location bottom plate (201), the upper end ball setting of location bottom plate (201), extrude sensor (9) when location slip post (202) slides down.

4. A high-low voltage distribution cabinet according to claim 3, characterized in that: the transverse moving mechanism (3) comprises a transverse moving support (301), sliding cylinders (302), transverse moving shafts (303), transverse moving sliders (304), transverse moving gears (305) and a transverse moving motor (306), the front end and the rear end of the upper side of the transverse moving support (301) are fixedly connected with the sliding cylinders (302), the left side and the right side of the transverse moving support (301) are rotatably connected with the transverse moving shafts (303), the two transverse moving shafts (303) are rotatably connected with the two transverse moving sliders (304), the two transverse moving gears (305) are fixedly connected with the two transverse moving shafts (303), the transverse moving motor (306) is fixedly connected with the transverse moving slider (304) on one side, an output shaft of the transverse moving motor (306) is fixedly connected with one transverse moving shaft (303), the transverse moving mechanism (3) is provided with a plurality of transverse moving sliders (304) on the front side and the rear side are respectively slidably connected in the two sliding waist holes (104), the transverse moving gears (305) on the front side and the rear side are respectively meshed, the lower end of the transverse moving support (301) is provided with an arc groove, and the upper end of the positioning bottom plate (201) can be inserted into the arc groove.

5. A high-low voltage distribution cabinet according to claim 4, characterized in that: the mounting mechanism I (4) comprises a mounting base plate I (401), a telescopic mechanism I (402), a sliding column (403), a side plate I (404), a mounting threaded rod I (405) and a mounting plate I (406), fixedly connected with mounting plate I (401) is served in the flexible of telescopic machanism I (402), two sliding column of lower extreme fixedly connected with (403) of mounting plate I (401), four curb plate I (404) of the upper end fixedly connected with of mounting plate I (401), all there is installation threaded rod I (405) on four curb plate I (404) through threaded connection, the inboard of every installation threaded rod I (405) all rotates and is connected with mounting plate I (406), equal sliding connection of four mounting plate I (406) is on mounting plate I (401), equal fixedly connected with telescopic machanism I (402) on every sideslip support (301), sliding column (403) sliding connection is in slide cylinder (302) to using.

6. A high-low voltage distribution cabinet according to claim 5, characterized in that: elevating system (5) are including rotating a section of thick bamboo (501) and synchronous pulley (502), rotate a section of thick bamboo (501) and be provided with four, and equal fixedly connected with synchronous pulley (502) on four rotation section of thick bamboos (501), the transmission is connected between four synchronous pulley (502), and the drive ratio between four synchronous pulley (502) is one, and four rotation sections (501) are all rotated and are connected on rectangle support I (101).

7. A high-low voltage distribution cabinet according to claim 6, characterized in that: lifting support (6) are including rectangular support II (601), connecting bottom plate (602) and lifting threaded rod (603), and a plurality of connecting bottom plates of fixedly connected with (602) are gone up in rectangular support II (601), four lifting threaded rod (603) of fixedly connected with on rectangular support II (601), and four lifting threaded rod (603) are respectively through threaded connection in four rotating barrel (501).

8. The high-low voltage power distribution cabinet according to claim 7, characterized in that: installation mechanism II (7) is including mounting plate II (701), telescopic machanism II (702), curb plate II (703), installation threaded rod II (704) and mounting panel II (705), telescopic end fixedly connected with mounting plate II (701) of telescopic machanism II (702), four curb plates II (703) of fixedly connected with are gone up in mounting plate II (701), all there is installation threaded rod II (704) through threaded connection on four curb plates II (703), the inboard of four installation threaded rod II (704) is all rotated and is connected with mounting panel II (705), four equal sliding connection of mounting panel II (705) are on mounting plate II (701), equal fixedly connected with telescopic machanism II (702) are gone up on a plurality of connecting bottom plate (602), a plurality of telescopic machanism II (702) are connected with a plurality of sensors (9) respectively.

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