JP2021171752A - Dehumidification device for distribution box - Google Patents

Abstract

To provide a dehumidification device for a distribution box.SOLUTION: A dehumidification device comprises a mounting box. A mounting cavity is installed in the mounting box, the mounting cavity being open back and front. A dehumidification mechanism is arranged in the mounting cavity. The dehumidification mechanism comprises a distribution box fixed on an upper end surface of the mounting cavity. A distribution cavity is installed in the distribution box. The invention can remove water vapor in the power distribution box. The water vapor in the power distribution box is absorbed through a silica gel drying agent, and when the water vapor to be absorbed reaches a saturation state, the silica gel drying agent is fed into a heating box, so that the silica gel drying agent is repeatedly used by heating, and then the silica gel drying agent again having absorbent capacity water vapor is returned to an original position. It is ensured that when the distribution box is operated, moisture values in the distribution box are maintained in a required range.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power distribution related technical field, and specifically is a dehumidifying device for a power distribution box.

The distribution box is composed of a switch device, a measuring instrument, a protective electric appliance, and an auxiliary device that are completely or partially closed in a metal cabinet or screen. If the distribution box is placed in a humid place such as a basement room or outdoors, the demand for dehumidification inside the distribution box will increase, and if the moisture inside the distribution box is not removed immediately, the electrical parts inside the distribution box will be damaged. There is a risk of a power outage.

Chinese Patent Application Publication No. 1044099777

In response to the above technical shortage, the present invention provides a dehumidifying device for a distribution box.

The present invention is a dehumidifying device for a power distribution box, including a mounting box, the mounting space is provided in the mounting space, the mounting space is open in the front-rear direction, and a dehumidifying mechanism is installed inside the mounting space. The dehumidifying mechanism includes a power distribution box fixed to the upper end surface of the mounting space, the power distribution space is installed in the power distribution box, and the upper end surface of the power distribution box is installed on the rear end wall of the mounting space. A drive groove fixed to the lower end surface is fixed, a drive block is installed inside the drive groove, and a lower dehumidifying box connected to the inside of the power distribution space is slidably attached to the drive block. , The lower dehumidifying box is provided with a lower dehumidifying space that can store the desiccant, the upper dehumidifying box is fixed to the right end surface of the power distribution box, and the upper dehumidifying box is provided with the upper dehumidifying space that can store the desiccant. A push mechanism is installed inside the mounting space, a discharge mechanism is installed inside the mounting space, and the discharge mechanism includes a mounting block fixed to the right end wall of the mounting space, and the mounting A trapezoidal groove is formed in the block, and a magnetic discharge box is slidably attached to the inside of the trapezoidal groove, and the discharge box is provided with a discharge space capable of storing a desiccant that has absorbed a lot of moisture. The right end surface of the discharge box and the right end wall of the mounting block are connected by a connecting spring, a heating box is fixed to the bottom wall of the mounting space, a heating space is installed in the heating box, and the heating box is provided. When the upper end surface and the lower end surface of the lower dehumidifying box are connected by a drive spring, the drive springs are arranged symmetrically, and the limit of the bearing capacity of the drive spring reaches the limit of the desiccant capable of absorbing steam. , A switching mechanism is installed inside the heating space, and a transportation mechanism is installed on the right end surface of the heating box.

The dehumidifying mechanism also includes a subpartition plate fixed to the upper end surface of the lower dehumidifying box to allow steam to pass through, and dehumidifying grooves are formed symmetrically on the left and right end surfaces of the lower dehumidifying box. A left-handed rotating shaft with a torsion spring is rotatably attached to the front and rear end walls of the above, a trapezoidal block is fixed to the left-handed rotating shaft, and a lower triangular block is attached to the lower right end surface of the lower dehumidifying space. Is fixed, a connecting groove is formed on the lower end surface of the lower dehumidifying box, and an upper magnetic plate is slidably attached to the inside of the connecting groove. The wall is connected by a lower dehumidifying spring.

The dehumidifying mechanism also includes an upper partition plate fixed to the right end surface of the upper dehumidifying box to allow steam to pass through, and the upper end surface of the upper dehumidifying box communicates with the upper dehumidifying space and can be expanded and contracted. The pipe is fixed, the upper triangular block is fixed to the lower end surface on the right side of the upper dehumidifying space, the upper dehumidifying groove is formed on the lower end surface of the upper dehumidifying box, and the upper connecting plate is inside the upper dehumidifying groove. Is slidably attached, the right end surface of the upper dehumidifying plate and the right end wall of the upper dehumidifying groove are connected by an upper dehumidifying spring, an electric magnet is fixed to the left end wall of the upper dehumidifying groove, and the upper dehumidifying box. A connecting pipe located below the upper connecting plate and communicating with the upper dehumidifying space is fixed to the lower end surface of the above.

The pushing mechanism includes a motor fixed to the front end wall of the mounting space, a driving shaft is movably connected to the rear end of the motor, and a rotary gear is fixed to the driving shaft to cover the mounting space. A fixed block is fixed to the rear end wall, a push rod is slidably attached to the fixed block, and an upper rack that meshes with the rotary gear is fixed to the lower end surface of the push rod. A magnet block is fixed to the right end surface of.

The discharge mechanism also includes a left pulley fixed to the driving shaft and located on the front side of the rotary gear, the pulley shaft is rotatably mounted on the front end wall of the mounting space and is attached to the pulley shaft. The right pulley and front gear are fixed from front to back, the right pulley and the left pulley are connected by a belt, and the connecting shaft is rotatably attached to the right end wall of the mounting space, and the connecting is performed. A rear bevel gear that meshes with the front bevel gear is fixed to the shaft, and a transmission gear located on the left side of the rear bead gear is fixed to the connecting shaft.

The discharge mechanism also includes a discharge shaft rotatably attached to the left end wall of the discharge space and connected to the inside of the mounting space, the discharge shaft located inside the mounting space. A discharge gear that meshes with the transmission gear is fixed, a spiral rotating piece located inside the discharge space is fixed to the discharge shaft, and a spiral rotating piece located inside the discharge space is fixed to the upper end wall of the discharge box and connected to the inside of the discharge space. A lower transport pipe that can be expanded and contracted is fixed, a discharge groove is formed on the lower end surface of the discharge box, and a mounting plate is slidably attached to the inside of the discharge groove, and is below the mounting plate. A mounting block is fixed to the end surface, and the right end surface of the mounting plate and the right end wall of the discharge groove are connected by a discharge spring.

The switching mechanism includes a heating groove formed on the upper end surface of the heating box, and a lower magnetic plate is slidably attached to the inside of the heating groove, and the right end surface of the lower magnetic plate and the heating groove The right end wall is connected by a tension spring, a mounting groove is formed on the right end surface of the heating box, and a right rotation shaft with a torsion spring is rotatably attached to the front and rear end walls of the above-mentioned mounting groove. The lower mounting plate is fixed to the right rotation shaft, the extrusion block is fixed to the right end wall of the mounting space, the extrusion groove is formed in the extrusion block, and the lower rack is inside the extrusion groove. It is slidably attached, and the left end surface of the lower rack and the left end wall of the extrusion groove are connected by an extrusion spring, and the lower drive shaft is located between the rotary gear and the left pulley. A lower half-circle gear that meshes with the rack is fixed, and an extrusion plate located inside the heating space is fixed to the right end surface of the lower rack.

The switching mechanism includes a mounting pipe fixed to the right end surface of the heating box, the upper transport pipe is fixed to the upper end surface of the mounting pipe, and the lower transport pipe is fixed to the rear end surface of the mounting pipe. A blower located inside the mounting tube is fixed to the right end surface of the lower mounting plate.

According to the present invention, moisture in the distribution box can be removed, the vapor in the distribution box is absorbed by the silica gel desiccant, and when the absorbed steam becomes saturated, the silica gel desiccant is sent to the heating box to obtain silica gel. The desiccant is heated and recycled, and the absorbent silica gel desiccant is returned to its original position to ensure that the humidity value in the distribution box is maintained within the required range when the distribution box is activated. ..

In order to explain the present invention in detail with reference to FIGS. 1 to 5 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention and is described in the present application. Each direction is the direction when the device is viewed in the same direction as in FIG.

FIG. 1 is a schematic configuration diagram of the present invention. FIG. 2 is a schematic view of the “AA” part of FIG. FIG. 3 is a schematic view of the “BB” part of FIG. FIG. 4 is a schematic view of the “CC” part of FIG. FIG. 5 is a schematic view of the “DD” part of FIG.

The present invention is a dehumidifying device for a power distribution box, which includes a mounting box 10, in which a mounting space 11 is installed, the mounting space 11 is open in the front-rear direction, and inside the mounting space 11. Is provided with a dehumidifying mechanism 81 capable of maintaining a moisture value within a normal range by absorbing and removing moisture in the distribution box, and the dehumidifying mechanism 81 includes a distribution box 24 fixed to the upper end surface of the mounting space 11. A power distribution space 25 is installed in the power distribution box 24, and a drive groove 68 whose upper end surface is fixed to the lower end surface of the power distribution box 24 is fixed to the rear end wall of the mounting space 11, and the drive groove 68 is fixed. A drive block 67 is installed inside the drive block 67, and a lower dehumidifying box 30 connected to the inside of the power distribution space 25 is slidably attached to the drive block 67, and a desiccant is applied to the lower dehumidifying box 30. A lower dehumidifying space 29 that can be stored is installed, an upper dehumidifying box 31 is fixed to the right end surface of the power distribution box 24, and an upper dehumidifying space 32 that can store a desiccant is installed in the upper dehumidifying box 31. The desiccant stored in the space 29 and the upper dehumidifying space 32 absorbs the steam in the distribution box 24, and the operation of the distribution box 24 can be ensured in a normal state. A pushing mechanism 85 for pushing the desiccant in which the vapor absorbed in the lower dehumidifying box 30 is saturated is installed, and the desiccant absorbing the vapor is replaced with an equal amount inside the mounting space 11 to operate normally. A discharge mechanism 84 that can be secured is installed, and the discharge mechanism 84 includes a mounting block 80 fixed to the right end wall of the mounting space 11, and a trapezoidal groove 79 is formed in the mounting block 80, and the trapezoidal groove 79 is formed. A magnetic discharge box 41 is slidably attached to the inside, and a discharge space 42 capable of storing a desiccant that has absorbed a lot of moisture is installed in the discharge box 41, and the right end surface of the discharge box 41 and the attachment. The right end wall of the block 80 is connected by a connecting spring 78, a heating box 56 is fixed to the bottom wall of the mounting space 11, a heating space 57 is installed in the heating box 56, and an upper end surface of the heating box 56 is installed. And the lower end surface of the lower dehumidifying box 30 are connected by a drive spring 66, the drive spring 66 is arranged symmetrically, and the limit of the bearing capacity of the drive spring 66 is the limit of the desiccant capable of absorbing steam. When it reaches, it can shrink, and inside the heating space 57, a switching mechanism 82 that can recycle the desiccant by heating and drying the desiccant that has absorbed steam is installed. On the right end surface of the heating box 56, a transport mechanism 83 for sending the desiccant to a designated position is installed.

To be beneficial, the dehumidifying mechanism 81 also includes a subpartition plate 28 fixed to the upper end surface of the lower dehumidifying box 30 to allow steam to pass through, and dehumidifying grooves 26 are symmetrical on the left and right end faces of the lower dehumidifying box 30. A left-handed rotating shaft 27 with a torsion spring is rotatably attached to the front and rear end walls of the dehumidifying groove 26, and a trapezoidal block 23 is fixed to the left-handed rotating shaft 27. A lower triangular block 89 is fixed to the lower end surface on the right side of the lower dehumidifying space 29, a connecting groove 87 is formed on the lower end surface of the lower dehumidifying box 30, and an upper magnetic plate 86 is formed inside the connecting groove 87. It is slidably attached, and the right end surface of the upper magnetic plate 86 and the right end wall of the connecting groove 87 are connected by a lower dehumidifying spring 88, and the steam inside the power distribution box 24 is dehumidified by the lower partition plate 28. When entering the space 29, it can be ensured that the desiccant is absorbed by the desiccant, and further, the desiccant can be prevented from entering the power distribution space 25, and the desiccant requiring treatment that absorbs steam by the slope of the lower triangular block 89 It can be guaranteed that it does not accumulate inside the lower dehumidifying space 29.

To be beneficial, the dehumidifying mechanism 81 also includes an upper partition plate 34 fixed to the right end surface of the upper dehumidifying box 31 to allow steam to pass through, and the upper end surface of the upper dehumidifying box 31 has the upper dehumidifying space. An upper transport pipe 33 that communicates with 32 and can be expanded and contracted is fixed, an upper triangular block 35 is fixed to the lower right lower surface of the upper dehumidifying space 32, and an upper dehumidifying groove 36 is fixed to the lower end surface of the upper dehumidifying box 31. Is formed, and the upper connecting plate 38 is slidably attached to the inside of the upper dehumidifying groove 36, and the right end surface of the upper connecting plate 38 and the right end wall of the upper dehumidifying groove 36 are connected by the upper dehumidifying spring 37. An electric magnet 39 is fixed to the left end wall of the upper dehumidifying groove 36, and the lower end surface of the upper dehumidifying box 31 is located below the upper connecting plate 38 and communicates with the upper dehumidifying space 32. When the connecting pipe 65 is fixed and the steam inside the distribution box 24 enters the lower dehumidifying space 29 by the upper partition plate 34, it can be ensured that the desiccant is absorbed by the desiccant, and the desiccant is further distributed in the distribution space 25. It is possible to prevent the dehumidifying agent from entering the upper triangular block 35, and it is possible to guarantee that the desiccant that requires treatment that has absorbed the steam by the slope of the upper triangular block 35 does not accumulate inside the upper dehumidifying space 32.

Beneficially, the push mechanism 85 includes a motor 63 fixed to the front end wall of the mounting space 11, and a drive shaft 13 is ubiquitously connected to the rear end of the motor 63 and is connected to the drive shaft 13. The rotary gear 12 is fixed, the fixed block 20 is fixed to the rear end wall of the mounting space 11, the push rod 19 is slidably mounted on the fixed block 20, and the push rod 19 is slidably mounted on the lower end surface of the push rod 19. The upper rack 18 that meshes with the rotary gear 12 is fixed, the magnet block 22 is fixed to the right end surface of the push rod 19, and the water vapor absorbed in the lower dehumidifying space 29 by the movement of the magnet block 22. Extrudes the desiccant that becomes saturated, and the desiccant that has not yet absorbed the steam is placed in the lower dehumidifying space 29.

Beneficially, the discharge mechanism 84 also includes a left pulley 62 fixed to the driving shaft 13 and located on the front side of the rotary gear 12, with a pulley shaft 74 on the front end wall of the mounting space 11. It is rotatably attached, and the right pulley 73 and the front bevel gear 75 are fixed to the pulley shaft 74 from front to rear, and the right pulley 73 and the left pulley 62 are connected by a belt 72 to form the attachment space. A connecting shaft 71 is rotatably attached to the right end wall of 11, a rear bevel gear 76 that meshes with the front bevel gear 75 is fixed to the connecting shaft 71, and the rear beating gear 71 is fixed to the connecting shaft 71. The transmission gear 70 located on the left side of the bevel gear 76 is fixed, and when the discharge box 41 moves to the left due to the rotation of the transmission gear 70, an equal amount of replacement desiccant can be discharged.

Beneficially, the discharge mechanism 84 also includes a discharge shaft 43 that is rotatably attached to the left end wall of the discharge space 42 and is connected to the inside of the mounting space 11. A discharge gear 77 located inside the mounting space 11 and meshing with the transmission gear 70 is fixed, and a spiral rotating piece 69 located inside the discharge space 42 is fixed to the discharge shaft 43. A lower transport pipe 40 that is connected to the inside of the discharge space 42 and can be expanded and contracted is fixed to the upper end wall of the discharge box 41, and a discharge groove 90 is formed on the lower end surface of the discharge box 41. A mounting plate 45 is slidably attached to the inside of the 90, and a mounting block 47 is fixed to the lower end surface of the mounting plate 45, and the right end surface of the mounting plate 45 and the right end of the discharge groove 90. The wall is connected by the discharge spring 44, and the rotation of the discharge shaft 43 can ensure that the desiccant in the discharge space 42 is discharged.

To be beneficial, the switching mechanism 82 includes a heating groove 53 formed on the upper end surface of the heating box 56, and a lower magnetic plate 55 is slidably attached to the inside of the heating groove 53 to form a lower magnetic plate 55. The right end surface of the magnetic plate 55 and the right end wall of the heating groove 53 are connected by a tension spring 54, a mounting groove 51 is formed on the right end surface of the heating box 56, and the front and rear end walls of the above-mentioned mounting groove 51 are formed. A right rotation shaft 49 with a torsion spring is rotatably attached, a lower mounting plate 50 is fixed to the right rotation shaft 49, and an extrusion block 58 is fixed to the right end wall of the attachment space 11. An extrusion groove 59 is formed in the extrusion block 58, a lower rack 64 is slidably attached to the inside of the extrusion groove 59, and the left end surface of the lower rack 64 and the left end wall of the extrusion groove 59 are extruded. A lower half-circle gear 61, which is connected by a spring 60 and is located between the rotary gear 12 and the left pulley 62 and meshes with the lower rack 64, is fixed to the driving shaft 13, and the lower rack 64 is fixed. An extrusion plate 52 located inside the heating space 57 is fixed to the right end surface of the heating space 57, and a desiccant whose moisture has been removed by heating in the heating space 57 by the thrust of the extrusion plate 52 is placed in the heating space. You can get out of 57.

Beneficially, the switching mechanism 82 includes a mounting tube 46 fixed to the right end surface of the heating box 56, the upper transport tube 33 is fixed to the upper end surface of the mounting tube 46, and the mounting tube 46 is fixed. The lower transport pipe 40 is fixed to the rear end surface, and a blower 48 located inside the mounting pipe 46 is fixed to the right end surface of the lower mounting plate 50, and the heating space is provided by the blower 48. The desiccant leaving 57 is blown, and the mounting pipe 46 blows most of the desiccant into the discharge space 42 through the lower transport pipe 40, and a small portion of the desiccant blows the upper transport pipe 33. It is blown into the upper dehumidifying space 32 through the pipe.

In the initial state, when the drive spring 66 is not deformed and the upper dehumidifying spring 37 is deformed by attracting the upper connecting plate 38 when the electric magnet 39 is energized and the magnet block 22 is not moving, The tension spring 54, the lower dehumidifying spring 88, and the connecting spring 78 are not deformed, the discharge spring 44 is not deformed, and the extrusion spring 60 is deformed.

When the desiccant that has entered the inside of the lower dehumidifying space 29 through the lower partition plate 28 becomes saturated with the absorbed steam, the supporting force of the drive spring 66 contracts to the limit, and the lower dehumidifying box 30 moves downward. When the lower dehumidifying box 30 moves downward, the lower end wall of the power distribution space 25 raises the trapezoidal block 23 so that the dehumidifying grooves 26 on both the left and right sides communicate with each other. 12 rotates to mesh with the upper rack 18, and moves the push rod 19 to the right, and when the magnet block 22 moves to the right, it attracts the upper magnetic plate 86 and moves it to the right. The upper magnetic plate 86 attracts the lower magnetic plate 55 and moves it to the right.
When the driving shaft 13 rotates, the lower half-circle gear 61 is rotated to mesh with the lower rack 64, and the lower rack 64 is moved to the right until the extrusion plate 52 is located on the left side of the heating space 57. Then, the desiccant inside the lower dehumidifying space 29 enters the heating space 57, and due to the slope of the lower triangular block 89, the desiccant that needs to be treated that has absorbed steam does not accumulate in the lower dehumidifying space 29, and the electromagnet 39 loses power. Then, the upper connecting plate 38 is moved to the right, the desiccant inside the upper dehumidifying space 32 is allowed to enter the inside of the heating space 57 together with the connecting pipe 65, and the steam is absorbed by the slope of the upper triangular block 35. When the required desiccant does not accumulate in the upper dehumidifying space 32 and the desiccant runs out inside the upper dehumidifying space 32, the electromagnet 39 is energized to return the upper connecting plate 38 to the initial position.
The main driving shaft 13 rotates the pulley shaft 74 by the transmission of the belt 72 between the left pulley 62 and the right pulley 73, and the pulley shaft 74 rotates the connecting shaft 71 by the meshing transmission of the front gear 75 and the rear gear 76. When the transmission gear 70 is rotated and the magnet block 22 moves to the left, the discharge box 41 is sucked and moved to the left, and the upper magnetic plate 86 is moved to the left to close the lower dehumidifying box. When the heating box 56 is closed by moving the lower magnetic plate 55 to the left and the discharge box 41 is moved to the left, the upper mounting plate 45 is brought into contact with the mounting block 47 and the lower dehumidifying box 30. Moves to the right with respect to the discharge box 41, the discharge shaft 43 rotates due to the engagement between the transmission gear 70 and the discharge gear 77, the spiral rotary piece 69 rotates, and the spiral rotating piece 69 is inside the discharge space 42 to absorb steam. When an equal amount of the desiccant is placed inside the lower dehumidifying space 29 and the magnet block 22 moves until it returns to the initial position, the discharge box 41 also returns to the initial position by the tensile force of the connecting spring 78.

Moisture is removed from the desiccant by heating the heating space 57, and the extrusion plate 52 returns to the initial position by meshing with the lower half-circle gear 61 and the lower rack 64 to push the treated desiccant into the mounting pipe 46. After that, the motor 63 stopped rotating, the desiccant treated inside the heating space 57 was blown by the blower 48, and most of the desiccant started to move by the attachment pipe 46 was passed through the lower transport pipe 40. It enters the discharge space 42, but a small portion enters the upper dehumidifying space 32 via the upper transport pipe 33, and the desiccant inside the lower dehumidifying space 29 and the upper dehumidifying space 32 repeatedly removes the steam inside the distribution space 25. can.

The above-mentioned examples merely explain the technical concept and features of the present invention, the purpose of which is to make a person skilled in the art understand the contents of the present invention and further implement the invention, and the scope of protection of the present invention cannot be limited. .. All equivalent changes or modifications made on the basis of the spiritual substance of the invention should be included within the scope of protection of the invention.

Claims (8)

A mounting space is installed in the mounting box including a mounting box, the mounting space is open to the front and rear, a dehumidifying mechanism is installed inside the mounting space, and the dehumidifying mechanism is above the mounting space. A distribution space is installed in the distribution box including a distribution box fixed to the end face, and a drive groove having an upper end surface fixed to the lower end surface of the distribution box is fixed to the rear end wall of the mounting space. A drive block is installed inside the drive groove, and a lower dehumidifying box connected to the inside of the power distribution space is slidably attached to the drive block, and a desiccant can be stored in the lower dehumidifying box. A lower dehumidifying space is installed, an upper dehumidifying box is fixed to the right end surface of the power distribution box, an upper dehumidifying space that can store a desiccant is installed in the upper dehumidifying box, and a pushing mechanism is provided inside the mounting space. Installed, a discharge mechanism is installed inside the mounting space, the discharge mechanism includes a mounting block fixed to the right end wall of the mounting space, the mounting block is formed with a trapezoidal groove, and the trapezoidal groove is formed. A magnetic discharge box is slidably attached to the inside of the discharge box, and a discharge space capable of storing a desiccant that has absorbed a lot of moisture is provided in the discharge box. The walls are connected by a connecting spring, the heating box is fixed to the bottom wall of the mounting space, the heating space is installed in the heating box, and the upper end surface of the heating box and the lower end surface of the lower dehumidifying box are connected to each other. Connected by a drive spring, the drive springs are arranged symmetrically, and the drive springs can contract when the limit of bearing capacity reaches the limit of a desiccant capable of absorbing steam, and switches to the inside of the heating space. A dehumidifying device for a power distribution box, characterized in that a mechanism is installed and a transportation mechanism is installed on the right end surface of the heating box. The dehumidifying mechanism also includes a subpartition plate fixed to the upper end surface of the lower dehumidifying box to allow steam to pass through, and dehumidifying grooves are formed symmetrically on the left and right end surfaces of the lower dehumidifying box. A left-handed rotating shaft with a torsion spring is rotatably attached to the front and rear end walls of the above, a trapezoidal block is fixed to the left-handed rotating shaft, and a lower triangular block is attached to the lower right end surface of the lower dehumidifying space. Is fixed, a connecting groove is formed on the lower end surface of the lower dehumidifying box, and an upper magnetic plate is slidably attached to the inside of the connecting groove. The dehumidifying device for a power distribution box according to claim 1, wherein the wall is connected by a lower dehumidifying spring. The dehumidifying mechanism also includes an upper partition plate fixed to the right end surface of the upper dehumidifying box to allow steam to pass through, and the upper end surface of the upper dehumidifying box communicates with the upper dehumidifying space and can be expanded and contracted. The pipe is fixed, the upper triangular block is fixed to the lower end surface on the right side of the upper dehumidifying space, the upper dehumidifying groove is formed on the lower end surface of the upper dehumidifying box, and the upper connecting plate is inside the upper dehumidifying groove. Is slidably attached, the right end surface of the upper dehumidifying plate and the right end wall of the upper dehumidifying groove are connected by an upper dehumidifying spring, an electric magnet is fixed to the left end wall of the upper dehumidifying groove, and the upper dehumidifying box. The dehumidifying device for a power distribution box according to claim 1, wherein a connecting pipe located below the upper connecting plate and communicating with the upper dehumidifying space is fixed to the lower end surface of the above. The pushing mechanism includes a motor fixed to the front end wall of the mounting space, a main driving shaft is electrically connected to the rear end of the motor, and a rotary gear is fixed to the main driving shaft to provide the mounting space. A fixed block is fixed to the rear end wall, a push rod is slidably attached to the fixed block, and an upper rack that meshes with the rotary gear is fixed to the lower end surface of the push rod. The dehumidifying device for a power distribution box according to claim 1, wherein a magnet block is fixed to the right end surface of the power distribution box. The discharge mechanism also includes a left pulley fixed to the driving shaft and located on the front side of the rotary gear, the pulley shaft is rotatably mounted on the front end wall of the mounting space and is attached to the pulley shaft. The right pulley and front gear are fixed from front to back, the right pulley and the left pulley are connected by a belt, and the connecting shaft is rotatably attached to the right end wall of the mounting space, and the connecting is performed. The claim is characterized in that a rear bevel gear that meshes with the front bevel gear is fixed to the shaft, and a transmission gear located on the left side of the rear bead gear is fixed to the connecting shaft. The dehumidifying device for the power distribution box according to 1. The discharge mechanism also includes a discharge shaft rotatably attached to the left end wall of the discharge space and connected to the inside of the mounting space, the discharge shaft located inside the mounting space. A discharge gear that meshes with the transmission gear is fixed, a spiral rotating piece located inside the discharge space is fixed to the discharge shaft, and a spiral rotating piece located inside the discharge space is fixed to the upper end wall of the discharge box and connected to the inside of the discharge space. A lower transport pipe that can be expanded and contracted is fixed, a discharge groove is formed on the lower end surface of the discharge box, and a mounting plate is slidably attached to the inside of the discharge groove, and is below the mounting plate. The dehumidifying device for a power distribution box according to claim 1, wherein a mounting block is fixed to an end surface, and the right end surface of the mounting plate and the right end wall of the discharge groove are connected by a discharge spring. The switching mechanism includes a heating groove formed on the upper end surface of the heating box, and a lower magnetic plate is slidably attached to the inside of the heating groove, and the right end surface of the lower magnetic plate and the heating groove The right end wall is connected by a tension spring, a mounting groove is formed on the right end surface of the heating box, and a right rotation shaft with a torsion spring is rotatably attached to the front and rear end walls of the above-mentioned mounting groove. The lower mounting plate is fixed to the right rotation shaft, the extrusion block is fixed to the right end wall of the mounting space, the extrusion groove is formed in the extrusion block, and the lower rack is inside the extrusion groove. It is slidably attached, and the left end surface of the lower rack and the left end wall of the extrusion groove are connected by an extrusion spring, and the lower drive shaft is located between the rotary gear and the left pulley. The first aspect of claim 1, wherein the lower half-circle gear that meshes with the rack is fixed, and an extrusion plate located inside the heating space is fixed to the right end surface of the lower rack. Dehumidifier for power distribution boxes. The switching mechanism includes a mounting pipe fixed to the right end surface of the heating box, the upper transport pipe is fixed to the upper end surface of the mounting pipe, and the lower transport pipe is fixed to the rear end surface of the mounting pipe. The dehumidifying device for a power distribution box according to claim 1, wherein a blower located inside the mounting pipe is fixed to the right end surface of the lower mounting plate.

Images