CN115421528B - Reactive compensation control cabinet with normal temperature dehumidification function - Google Patents

Abstract

The invention relates to the field of control cabinets, in particular to a reactive compensation control cabinet with a normal-temperature dehumidification function. Technical problems: the reactive compensation equipment generates heat during operation, so that ageing of insulating materials is affected, moisture can condense on the surfaces of functional parts, insulating faults are caused, and safe operation of the equipment is endangered. The technical scheme is as follows: a reactive compensation control cabinet with normal temperature dehumidification function comprises a dehumidification unit, a filtering unit and the like; the interior of the dehumidification unit is connected with the filtering unit. According to the invention, after the hot air generated by the operation of the functional components in the control cabinet is filtered for the second time, the hot air is cooled, so that the hot air is changed into dry normal-temperature air, the dry normal-temperature air is led into the control cabinet again, the moisture condensed on the surfaces of the functional components is absorbed by the dry normal-temperature air through the hygroscopicity of the dry normal-temperature air, and then the air absorbed with the moisture is filtered for the second time and recycled, so that the temperature in the control cabinet is effectively controlled, and the moisture residue in the control cabinet is reduced.

Description

Reactive compensation control cabinet with normal temperature dehumidification function

Technical Field

The invention relates to the field of control cabinets, in particular to a reactive compensation control cabinet with a normal-temperature dehumidification function.

Background

With the increasing number of enterprise users' equipment, the functional components in the control cabinet are more and more, and corresponding reactive power needs to be provided for the equipment in the operation process, so that the electric energy loss of the circuit is reduced.

However, heat can be generated in the working process of the reactive compensation equipment, so that the ageing of insulating materials is affected, and when the air temperature is lower than the temperature in the reactive compensation equipment, moisture in the air can be condensed on the surfaces of functional components in the reactive compensation control cabinet, and after the surfaces of the functional components are condensed, insulation faults can be caused, so that the safe operation of the equipment is endangered.

In summary, it is necessary to develop a reactive compensation control cabinet with a normal temperature dehumidification function to solve the above problems.

Disclosure of Invention

In order to overcome the defects that heat can be generated in the working process of reactive compensation equipment to influence the ageing of insulating materials, moisture in air can condense on the surfaces of functional components in the reactive compensation control cabinet to cause insulation faults and endanger the safe operation of the equipment, the invention provides the reactive compensation control cabinet with the normal-temperature dehumidification function.

The technical implementation scheme of the invention is as follows: a reactive compensation control cabinet with a normal temperature dehumidification function comprises a control cabinet, an instrument panel and a cabinet door; the upper part of the control cabinet is connected with an instrument panel; the left part of the front side of the control cabinet is movably connected with a cabinet door; the system also comprises a dehumidifying unit, a filtering unit, a fresh air unit and a double-channel cooling unit; the upper part of the control cabinet is connected with a dehumidifying unit for dehumidifying the air in the control cabinet; the upper part of the control cabinet is connected with a filtering unit for filtering air dust impurities in the control cabinet; the lower part of the control cabinet is connected with a fresh air unit for removing water on the surface of the internal part of the control cabinet; the rear part of the control cabinet is connected with a double-channel cooling unit for cooling high-temperature air in the control cabinet; the rear part of the instrument panel is connected with the dehumidification unit; the rear part of the instrument panel is connected with the filtering unit; the interior of the dehumidification unit is connected with the filtering unit; the rear part of the dehumidifying unit is connected with the double-channel cooling unit; the rear part of the fresh air unit is connected with the double-channel cooling unit.

Furthermore, it is particularly preferred that the dehumidifying unit includes a dehumidifying cover, a first L-shaped plate, a collecting case, an electric slide rail, an electric slider, a mounting plate, a limiting frame, a sponge block and an inclined rod; the upper surface of the control cabinet is fixedly connected with a dehumidifying cover; the dehumidifying cover is connected with the filtering unit; the rear side of the dehumidifying cover is connected with the double-channel cooling unit; the lower part of the dehumidifying cover is provided with a through groove; the rear middle part of the inner bottom surface of the dehumidifying cover is fixedly connected with a first L-shaped plate; the upper part of the first L-shaped plate is provided with a plurality of through holes; the upper part of the first L-shaped plate is connected with the filtering unit; the upper surface of the first L-shaped plate is fixedly connected with a collecting box; the bottom of the collecting box is provided with a plurality of through holes which are matched with the through holes at the upper part of the first L-shaped plate; an electric sliding rail is arranged at the upper part of the rear side of the instrument panel; two electric sliding blocks are connected to the electric sliding rail in a sliding way; the rear sides of the two electric sliding blocks are fixedly connected with a mounting plate respectively; the lower parts of the two mounting plates are connected with the filtering unit; a limit frame is fixedly connected to the upper part of the inner rear wall of the dehumidification cover; the lower part of the limiting frame is provided with a water filtering groove; the upper part of the limit frame is fixedly connected with a wedge-shaped cover; a sponge block is connected in the limit frame in a sliding way; the sponge block is positioned above the water filtering tank; the rear sides of the two mounting plates are fixedly connected with an inclined rod respectively; the rear part between the two inclined rods is fixedly connected with the sponge block.

Furthermore, it is particularly preferred that the rear ends of the two diagonal rods are spherical ends, and when the two diagonal rods are used for pressing the sponge block, moisture on the sponge block drops along the spherical ends of the two diagonal rods, so that the water drops are prevented from adhering to the two diagonal rods.

Furthermore, it is particularly preferred that the filter unit comprises a first electric actuator, a second L-shaped plate, a dust filter box, a first support plate, a bidirectional screw rod, a first driving wheel, a driving rod, a second driving wheel, a cam, a sliding rod, a dust sweeping plate, a first elastic member, a T-shaped plate, a second electric actuator, a collecting box, a flow guide pipe, a second support plate, a third support plate, a second elastic member and a sealing plate; the left part of the inner bottom surface and the right part of the inner bottom surface of the dehumidification cover are respectively provided with a first electric actuator; the upper ends of the telescopic parts of the two first electric actuators are fixedly connected with a second L-shaped plate respectively; the lower parts of the opposite sides of the two second L-shaped plates are fixedly connected with dust filtering boxes; the outer surface of the dust filtering box is connected with the dehumidifying cover in a sliding way; a filter screen is arranged in the dust filtering box; the lower sides of the two mounting plates are fixedly connected with a first support plate respectively; the upper part in the dehumidifying cover is rotationally connected with a bidirectional screw rod; the left part and the right part of the bidirectional screw rod are respectively connected with a first support plate in a screwing way; the left part of the outer surface of the bidirectional screw rod and the right part of the outer surface are fixedly connected with a first driving wheel respectively; the left part and the right part in the dehumidifying cover are respectively connected with a transmission rod in a rotating way; the outer surfaces of the two transmission rods are fixedly connected with a second transmission wheel respectively; the outer ring surfaces of the two second driving wheels are respectively connected with one first driving wheel in a driving way through a belt; the outer surfaces of the two transmission rods are fixedly connected with a cam respectively; the two cams are positioned between the two second driving wheels; the left part and the right part of the back side of the instrument panel are fixedly connected with a slide bar respectively; the rear ends of the two slide bars are fixedly connected with the dehumidifying cover; a dust sweeping plate is connected between the two sliding rods in a sliding way; the left part and the right part of the rear side of the dust sweeping plate are fixedly connected with a first elastic piece respectively; the rear parts of the two first elastic pieces are fixedly connected with the dehumidifying cover; the upper left part of the rear side of the dust sweeping plate and the upper right part of the rear side are fixedly connected with a T-shaped plate respectively; the two first elastic pieces are positioned between the two T-shaped plates; a second electric actuator is respectively arranged at the lower left part of the inner rear wall of the dehumidification cover and the lower right part of the inner rear wall; the front ends of the telescopic parts of the two second electric actuators are fixedly connected with collecting boxes; the lower part of the collecting box is connected with the dehumidifying cover in a sliding way; the left part and the right part of the rear side of the collecting box are respectively communicated with a guide pipe; the middle part of the rear side of the collecting box is fixedly connected with a second support plate; the upper left part and the upper right part of the first L-shaped plate are fixedly connected with a third support plate respectively; the front part and the rear part of the opposite sides of the two third support plates are fixedly connected with a second elastic piece respectively; sealing plates are fixedly connected to the opposite sides of the two front second elastic pieces respectively; sealing plates are fixedly connected to the opposite sides of the two second elastic pieces at the rear part respectively; the upper surfaces of the two sealing plates are both in sliding connection with the first L-shaped plate; the opposite sides of the two sealing plates are wedge-shaped surfaces, and a plurality of through holes are formed in the two sealing plates.

In addition, it is particularly preferred that the lower part of the dust sweeping plate is provided with a plurality of flexible bristles for sweeping dust impurities on the filter screen in the dust filtering box.

Furthermore, it is particularly preferred that the inner bottom of the collecting box is high at the middle and low at the left and right for transferring the collected matter to both the left and right.

In addition, it is particularly preferable that the sealing plate is provided with a plurality of through holes and communicates with the through holes in the upper portion of the first L-shaped plate for conducting the first L-shaped plate and the sealing plate.

Furthermore, it is particularly preferred that the fresh air unit comprises a fresh air box, a dust filter screen, a first baffle and a second baffle; the lower surface of the control cabinet is fixedly connected with a new bellows; a dehumidifying cavity is arranged in the new bellows; a dispersing cavity is formed in the new bellows; the dispersing cavity is positioned above the dehumidifying cavity, and the dehumidifying cavity is communicated with the dispersing cavity through a plurality of through holes in the middle; the rear side of the new bellows is connected with the double-channel cooling unit; the left part and the right part of the new bellows are respectively provided with a dust filtering net; three first baffles are fixedly connected to the upper left part of the dehumidifying cavity at equal intervals; three first baffles are fixedly connected to the right part of the dehumidifying cavity at equal intervals; three second baffles are fixedly connected to the lower left part of the dehumidification cavity at equal intervals; three second baffles are fixedly connected to the right part of the lower part of the dehumidifying cavity at equal intervals; the first baffle and the second baffle on the same side in the dehumidifying cavity are alternately arranged.

In addition, it is particularly preferable that the first baffle plate and the second baffle plate are made of sponge materials capable of absorbing water, are used for absorbing water in the air, and are used for primarily filtering dust and impurities in the air.

Furthermore, it is particularly preferred that the two-channel cooling unit comprises a cooling box, a partition plate, a first air duct, a power assembly, a second air duct, a heat collection box, a third air duct and a T-shaped pipe; the upper part of the rear side of the control cabinet is provided with a cooling box; the upper part of the front side of the cooling box is fixedly connected with the dehumidifying cover; four partition plates are fixedly connected in the cooling box; the cooling box is divided into five spaces by four partition plates; the upper parts of the four partition plates are respectively provided with a through hole; five spaces in the cooling box are communicated through holes at the upper parts of the four partition plates; the four partition plates are fixedly connected with first air ducts; the upper part of the first air duct is communicated with the dehumidifying cover; the lower part of the rear side of the control cabinet is provided with a power assembly; the upper part of the power assembly is communicated with the first air duct; the rear part of the power assembly is communicated with a second air duct; the lower part of the second air duct is communicated with a fresh air box; five heat collection boxes are fixedly connected at equal intervals at the rear part of the cooling box; the front parts of the five heat collection boxes are communicated with five spaces in the cooling box; the lower parts of the five heat collection boxes are fixedly connected with a third air duct; the lower parts of the five third air guide pipes are fixedly connected with T-shaped pipes; the lower part of the T-shaped pipe is communicated with the second air duct.

The beneficial effects are that: according to the invention, dust impurities and moisture in hot air are removed after the hot air generated by the operation of functional components in the control cabinet is filtered for the second time, the hot air is cooled, so that the hot air is changed into dry normal-temperature air, the dry normal-temperature air is led into the control cabinet again, the moisture condensed on the surfaces of the functional components in the control cabinet is absorbed by the dry normal-temperature air through the hygroscopicity of the dry normal-temperature air, the air with the moisture absorbed is filtered for the second time and recycled, the temperature in the control cabinet is effectively controlled, and the moisture residue in the control cabinet is reduced.

Drawings

Fig. 1 is a schematic diagram of a first three-dimensional structure of a reactive compensation control cabinet with a normal-temperature dehumidification function according to the present invention;

fig. 2 is a schematic diagram of a second three-dimensional structure of a reactive compensation control cabinet with a normal-temperature dehumidification function according to the present invention;

fig. 3 is a schematic diagram of a third three-dimensional structure of a reactive compensation control cabinet with a normal-temperature dehumidification function according to the present invention;

fig. 4 is a schematic diagram of a first combined three-dimensional structure of a reactive compensation control cabinet with a normal-temperature dehumidification function according to the invention;

fig. 5 is a schematic diagram of a three-dimensional structure of a dehumidification unit of a reactive compensation control cabinet with normal temperature dehumidification function according to the present invention;

fig. 6 is a schematic diagram of a first partial perspective structure of a dehumidifying unit of a reactive compensation control cabinet with normal temperature dehumidifying function according to the present invention;

fig. 7 is a schematic diagram of a second partial perspective structure of a dehumidifying unit of a reactive compensation control cabinet with normal temperature dehumidifying function according to the present invention;

fig. 8 is a schematic diagram of a second combined three-dimensional structure of a reactive compensation control cabinet with a normal-temperature dehumidification function according to the invention;

fig. 9 is a schematic diagram of a first partial perspective structure of a filtering unit of a reactive compensation control cabinet with a normal temperature dehumidification function according to the present invention;

fig. 10 is a schematic diagram of a second partial perspective structure of a filtering unit of a reactive compensation control cabinet with a normal temperature dehumidification function according to the present invention;

fig. 11 is a schematic perspective view of a third part of a second part of a filtering unit of a reactive compensation control cabinet with a normal temperature dehumidification function;

fig. 12 is a schematic diagram of a third combined three-dimensional structure of a reactive compensation control cabinet with a normal-temperature dehumidification function according to the present invention;

FIG. 13 is a cross-sectional view of a fresh air unit of a reactive compensation control cabinet with normal temperature dehumidification function according to the present invention;

fig. 14 is a schematic diagram of a fourth combined three-dimensional structure of a reactive compensation control cabinet with a normal-temperature dehumidification function according to the present invention;

fig. 15 is a schematic diagram of a three-dimensional structure of a dual-channel cooling unit of a reactive compensation control cabinet with a normal-temperature dehumidification function.

In the figure: 1-control cabinet, 2-instrument panel, 3-cabinet door, 101-dehumidification cover, 102-first L-shaped plate, 103-collecting box, 104-electric slide rail, 105-electric slide block, 106-mounting plate, 107-limit frame, 108-sponge block, 109-diagonal bar, 10101-through slot, 10701-water filtering slot, 10702-wedge cover, 201-first electric actuator, 202-second L-shaped plate, 203-dust filtering box, 204-first support plate, 205-bi-directional screw, 206-first driving wheel, 207-driving bar, 208-second driving wheel, 209-cam, 2010-slide bar, 2011-dust sweeping plate, 2012-first elastic member, 2013-T-shaped plate, 2014-second electric actuator, 2015-collecting box, 2016-honeycomb duct, 2017-second support plate, 2018-third support plate, 2019-second elastic member, 2020-sealing plate, 301-new bellows, 302-dust filtering net, 303-first baffle, 304-second humidity-dispersing cavity, 30102-cooling air duct, 401-402-guide tube, 402-partition plate, power duct 408-406, power duct assembly, heat guide tube assembly, heat pipe assembly, etc.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the embodiment of the present invention, the first elastic member 2012 and the second elastic member 2019 are springs, the first electric actuator 201 and the second electric actuator 2014 are electric push rods, and the power assembly 404 is an air pump.

Example 1

The reactive compensation control cabinet 1 with the normal temperature dehumidification function comprises a control cabinet 1, an instrument panel 2 and a cabinet door 3 according to the illustrations of figures 1-3; the upper part of the control cabinet 1 is connected with an instrument panel 2; the left part of the front side of the control cabinet 1 is hinged with a cabinet door 3; the system also comprises a dehumidifying unit, a filtering unit, a fresh air unit and a double-channel cooling unit; the upper part of the control cabinet 1 is connected with a dehumidifying unit; the upper part of the control cabinet 1 is connected with a filtering unit; the lower part of the control cabinet 1 is connected with a fresh air unit; the rear part of the control cabinet 1 is connected with a double-channel cooling unit; the rear part of the instrument panel 2 is connected with a dehumidifying unit; the rear part of the instrument panel 2 is connected with a filtering unit; the interior of the dehumidification unit is connected with the filtering unit; the rear part of the dehumidifying unit is connected with the double-channel cooling unit; the rear part of the fresh air unit is connected with the double-channel cooling unit.

Before using a reactive compensation control cabinet 1 with normal temperature dehumidification function, the reactive compensation control cabinet 1 is firstly placed in a machine room by an operator through a fresh air unit, a power supply is externally connected, a cabinet door 3 is closed, the control cabinet 1 starts to work, an instrument panel 2 is used for recording data of all functional components in the control cabinet 1, when the control cabinet 1 works, the functional components in the control cabinet 1 generate heat, air in the control cabinet 1 is heated, hot air floats upwards, hot air in the control cabinet 1 passes through a filtering unit, dust impurities carried in the hot air are filtered, then the hot air enters a dehumidification unit, moisture in the hot air is absorbed by the dehumidification unit, then the hot air is extracted from the dehumidification unit through the two-channel cooling unit, the hot air is cooled in the two-channel cooling unit, cooled low-temperature dry air is introduced into the fresh air unit, meanwhile, the air in the control cabinet 1 runs off through the upper part, the fresh air after being supplemented and filtered into the control cabinet 1, and the dry air in the fresh air is introduced into the control cabinet 1, the two-channel cooling unit absorbs moisture in the surface of the control cabinet 1, and the moisture residue in the fresh air is absorbed by the two-channel cooling unit; according to the invention, dust impurities and moisture in hot air are removed after the hot air generated by the operation of functional components in the control cabinet 1 is filtered for the second time, the hot air is cooled, so that the hot air is changed into dry normal-temperature air, the dry normal-temperature air is guided into the control cabinet 1 again through the hygroscopicity of the dry normal-temperature air, the moisture condensed on the surfaces of the functional components in the control cabinet 1 is absorbed through the dry normal-temperature air, and the air with the moisture absorbed is filtered for the second time and recycled, so that the temperature in the control cabinet 1 is effectively controlled, and the moisture residue in the control cabinet 1 is reduced.

Example 2

On the basis of embodiment 1, according to fig. 1 and fig. 4 to 7, the dehumidifying unit comprises a dehumidifying cover 101, a first L-shaped plate 102, a collecting box 103, an electric sliding rail 104, an electric sliding block 105, a mounting plate 106, a limiting frame 107, a sponge block 108 and an inclined rod 109; the upper surface of the control cabinet 1 is fixedly connected with a dehumidifying cover 101; the dehumidifying cover 101 is connected with the filtering unit; the rear side of the dehumidifying cover 101 is connected with a double-channel cooling unit; a through groove 10101 is formed in the lower part of the dehumidifying cover 101; the rear middle part of the inner bottom surface of the dehumidifying cover 101 is welded with a first L-shaped plate 102; the upper part of the first L-shaped plate 102 is provided with a plurality of through holes; the upper part of the first L-shaped plate 102 is connected with the filtering unit; the upper surface of the first L-shaped plate 102 is fixedly connected with a collecting box 103; the bottom of the collecting box 103 is provided with a plurality of through holes which are matched with the through holes at the upper part of the first L-shaped plate 102; an electric sliding rail 104 is arranged at the upper part of the rear side of the instrument panel 2; two electric sliding blocks 105 are connected on the electric sliding rail 104 in a sliding way; the rear sides of the two electric sliding blocks 105 are fixedly connected with a mounting plate 106 respectively; the lower parts of the two mounting plates 106 are connected with the filtering unit; a limit frame 107 is fixedly connected to the upper part of the inner rear wall of the dehumidification cover 101; a water filtering groove 10701 is arranged at the lower part of the limiting frame 107; a wedge-shaped cover 10702 is fixedly connected to the upper part of the limiting frame 107; a sponge block 108 is connected in a sliding way in the limit frame 107; the sponge block 108 is positioned above the water filtering groove 10701; a diagonal bar 109 is welded to the rear sides of the two mounting plates 106; the rear part between the two inclined rods 109 is fixedly connected with the sponge block 108.

The rear ends of the two diagonal rods 109 are ball-shaped ends.

As shown in fig. 1 and 8-11, the filtering unit includes a first electric actuator 201, a second L-shaped plate 202, a dust filtering box 203, a first support plate 204, a bidirectional screw rod 205, a first driving wheel 206, a driving rod 207, a second driving wheel 208, a cam 209, a sliding rod 2010, a dust sweeping plate 2011, a first elastic member 2012, a T-shaped plate 2013, a second electric actuator 2014, a collecting box 2015, a flow guiding tube 2016, a second support plate 2017, a third support plate 2018, a second elastic member 2019 and a sealing plate 2020; a first electric actuator 201 is respectively arranged at the left part of the inner bottom surface and the right part of the inner bottom surface of the dehumidification cover 101; the upper ends of the telescopic parts of the two first electric actuators 201 are fixedly connected with a second L-shaped plate 202 respectively; the lower parts of the opposite sides of the two second L-shaped plates 202 are fixedly connected with dust filtering boxes 203; the outer surface of the dust filtering box 203 is in sliding connection with the dehumidifying cover 101; a filter screen is arranged in the dust filtering box 203; a first support plate 204 is welded on the lower sides of the two mounting plates 106 respectively; the upper part in the dehumidifying cover 101 is rotatably connected with a bidirectional screw rod 205; the left part and the right part of the bidirectional screw rod 205 are respectively screwed with a first support plate 204; a first driving wheel 206 is fixedly connected to the left part of the outer surface and the right part of the outer surface of the bidirectional screw rod 205 respectively; a transmission rod 207 is rotatably connected to the left part and the right part in the dehumidifying cover 101; a second driving wheel 208 is fixedly connected to the outer surfaces of the two driving rods 207 respectively; the outer annular surfaces of the two second driving wheels 208 are respectively connected with one first driving wheel 206 in a driving way through belts; one cam 209 is fixedly connected to the outer surfaces of the two transmission rods 207 respectively; two cams 209 are located between the two second driving wheels 208; a sliding rod 2010 is welded at the left part and the right part of the rear side of the instrument panel 2; the rear ends of the two sliding rods 2010 are fixedly connected with the dehumidifying cover 101; a dust sweeping plate 2011 is connected between the two sliding rods 2010 in a sliding manner; a first elastic piece 2012 is fixedly connected to the left part at the rear side and the right part at the rear side of the dust sweeping plate 2011 respectively; the rear parts of the two first elastic pieces 2012 are fixedly connected with the dehumidification cover 101; a T-shaped plate 2013 is welded on the upper left part of the rear side and the upper right part of the rear side of the dust sweeping plate 2011 respectively; two first resilient members 2012 are positioned between the two T-shaped plates 2013; a second electric actuator 2014 is respectively arranged at the lower left part of the inner rear wall and the lower right part of the inner rear wall of the dehumidification cover 101; the front ends of the telescopic parts of the two second electric actuators 2014 are fixedly connected with a collecting box 2015; the lower part of the collecting box 2015 is connected with the dehumidifying cover 101 in a sliding way; the left part and the right part of the rear side of the collecting box 2015 are respectively communicated with a flow guide pipe 2016; a second support plate 2017 is welded at the middle part of the rear side of the collection box 2015; a third support plate 2018 is welded on the upper left part and the upper right part of the first L-shaped plate 102 respectively; the front part and the rear part of the opposite sides of the two third support plates 2018 are fixedly connected with a second elastic piece 2019 respectively; sealing plates 2020 are fixedly connected to the opposite sides of the front two second elastic pieces 2019 respectively; sealing plates 2020 are fixedly connected to the opposite sides of the two rear second elastic pieces 2019 respectively; the upper surfaces of the two sealing plates 2020 are in sliding connection with the first L-shaped plate 102; the opposite sides of the two sealing plates 2020 are wedge-shaped, and a plurality of through holes are formed in the two sealing plates 2020.

The lower part of the dust sweeping plate 2011 is provided with a plurality of flexible bristles.

The inner bottom of the collection box 2015 is low with the middle high left and right.

The sealing plate 2020 is provided with a plurality of through holes and communicates with the through holes in the upper portion of the first L-shaped plate 102.

Firstly, when the functional components in the control cabinet 1 start to operate, the functional components can generate heat, air around the functional components can be heated synchronously, hot air floats upwards after being heated, the hot air carries dust impurities to move upwards, when the hot air reaches the inner top of the control cabinet 1, the hot air enters from the lower part of the dust filtering box 203, when the hot air passes through a filter screen in the dust filtering box 203, dust impurities carried in the hot air are blocked by the filter screen, the hot air is discharged from a wound of the dust filtering box 203, and the hot air enters into the dehumidifying cover 101.

Moisture removal stage: when hot air enters the dehumidifying cover 101, an opening is arranged at the upper part of the rear side of the dehumidifying cover 101, the hot air entering the dehumidifying cover 101 can only leave from the position of the opening, at the moment, the hot air passes through the sponge block 108, moisture carried in the hot air is remained in the sponge block 108 when the hot air passes through the sponge block 108, when the hot air comes out from the position of the opening at the upper part of the dehumidifying cover 101, the hot air has completed removing moisture, after the reactive compensation control cabinet 1 is used for a period of time, the sponge block 108 absorbs the moisture, the moisture absorption effect of the sponge block 108 is reduced, at the moment, two electric sliding blocks 105 respectively drive one mounting plate 106 to move in the direction of Wang Hu on the electric sliding rail 104, two mounting plates 106 respectively drive one inclined rod 109 to move in the direction of approaching each other, the two inclined rods 109 compress the sponge block 108 from two ends to the middle, when the sponge block 108 is compressed to the middle part of the limiting frame 107, the sponge block 108 is deformed upwards and limited by the wedge-shaped cover 10702, moisture in the sponge block 108 is extruded in the deformation process, two sides of the sponge block 108 are pressed by the two inclined rods 109, the moisture moves downwards along the two inclined rods 109 after coming out of the sponge block 108, when water drops reach the tail ends of the two inclined rods 109, the water drops do not stay at the ball positions of the two inclined rods 109, the water drops fall into the water filtering groove 10701, the water stays at the ball positions of the two inclined rods 109, the two electric sliding blocks 105 stop moving, the extruded water enters the collecting box 103 through the water filtering groove 10701, after the moisture in the sponge block 108 is extruded, the two electric sliding blocks 105 start moving in the direction away from each other, synchronously drive one inclined rod 109 to move in the direction away from each other, at the moment, the sponge block 108 starts to restore the shape, the two motorized sliders 105 stop moving.

Stage of dust impurity filtering in air in control cabinet 1: after the reactive compensation control cabinet 1 is used for a period of time, dust residues are accumulated on the filter screen in the dust filter box 203, after the dust filter box 203 is plugged by dust, the efficiency of hot air passing through the dust filter box 203 is reduced, the circulation effect of the hot air is reduced, at this time, by starting the two first electric actuators 201, the two first electric actuators 201 extend to drive the second L-shaped plates 202 to move upwards, the two second L-shaped plates 202 drive the dust filter box 203 to move upwards, the lower part of the dust filter box 203 is withdrawn from the control cabinet 1, the dust filter box 203 continues to move upwards, when the lower surface of the dust filter box 203 is higher than the upper surface of the collecting box 2015, and when bristles of the dust sweeping plate 2011 contact with the filter screen of the dust filter box 203, the two first electric actuators 201 are closed, then the two second electric actuators 2014 are started, the two second electric actuators 2014 extend to drive the collecting box 2015 to move forwards, after the collecting box 2015 reaches the right lower part of the dust filtering box 203, the two second electric actuators 2014 are closed, then, when the two electric sliding blocks 105 move in the direction of approaching the electric sliding rails 104, the two electric sliding blocks 105 respectively drive one mounting plate 106 to move in the direction of approaching the electric sliding rails, the two mounting plates 106 respectively drive one first support plate 204 to move in the direction of approaching the electric sliding rails, so that the two first support plates 204 drive the bidirectional screw rod 205 to rotate, the bidirectional screw rod 205 respectively drive one second driving wheel 208 to rotate through the first driving wheel 206, the two second driving wheels 208 respectively drive one cam 209 to rotate through the driving rod 207, the two cams 209 drive the dust sweeping plate 2011 to slide on the two sliding rods 2010 through the T-shaped plates 2013, at the moment, the two first elastic pieces 2012 are stretched, when the two cams 209 do not drive the T-shaped plates 2013 to move forwards, the two first elastic pieces 2012 are restored, the dust sweeping plate 2011 is synchronously reset, the dust sweeping plate 2011 brushes the filter screen in the dust filtering box 203 through horizontally moving on the two sliding rods 2010, soft bristles at the lower part of the dust sweeping plate 2011 brush dust in the dust filtering box 203, dust on the lower surface of the filter screen is prevented from flying, soft bristles at the lower part of the dust sweeping plate 2011 pass through meshes of the filter screen, the dust brushes down, the dust falls into the collecting box 2015, the dust slides upwards on the slope of the bottom surface of the collecting box 2015, after the electric sliding block 105 resets, the two second electric actuators 2014 are started, the two second electric actuators 2014 shrink, the collecting box 2015 is synchronously driven to withdraw from the lower part of the dust filtering box 203, meanwhile, the collecting box 2017 drives the second supporting plate 2017 to move backwards, after the second supporting plate 2017 moves backwards to be contacted with the two sealing plates 2020, the four second elastic pieces 2019 are compressed, the two sealing plates 2020 move towards directions away from each other, when the through holes on the two sealing plates 2020 are communicated with the through holes on the upper part of the first L102, water in the collecting box 103 flows down through the through holes, the water falls down from the collecting box 2015, the water flows upwards along the two wedge-shaped structures and the two wedge-shaped structures are simultaneously carried away from the two sides of the collecting box 2015, and the water flows upwards along the two wedge-shaped structures of the two wedge-shaped structures are simultaneously, and the water flows upwards along the two wedge-shaped structures and the two wedge-shaped structures are simultaneously upwards along the water flow structures and the two wedge-shaped structures can be collected by the water.

According to fig. 1 and 12-13, the fresh air unit comprises a fresh air box 301, a dust filter net 302, a first baffle 303 and a second baffle 304; the lower surface of the control cabinet 1 is fixedly connected with a fresh air box 301; a dehumidifying cavity 30101 is arranged in the new bellows 301; a dispersion cavity 30102 is arranged in the new bellows 301; the dispersion chamber 30102 is located above the dehumidifying chamber 30101, and the dehumidifying chamber 30101 and the dispersion chamber 30102 communicate through a plurality of through holes in the middle; the rear side of the new bellows 301 is connected with a dual-channel cooling unit; the left part and the right part of the new bellows 301 are respectively provided with a dust filtering net 302; three first baffles 303 are fixedly connected to the upper left part of the dehumidifying cavity 30101 at equal intervals; three first baffles 303 are fixedly connected to the right part of the dehumidifying cavity 30101 at equal intervals; three second baffles 304 are fixedly connected to the lower left part of the dehumidifying cavity 30101 at equal intervals; three second baffles 304 are fixedly connected to the right part of the lower part of the dehumidifying cavity 30101 at equal intervals; the first baffle 303 and the second baffle 304 on the same side in the dehumidifying chamber 30101 are arranged alternately.

The first baffle 303 and the second baffle 304 are sponge materials capable of absorbing water.

Air compensation stage: after the air in the control cabinet 1 is heated, the hot air flows upwards, the air pressure in the control cabinet 1 is reduced, at this time, the outside air enters the control cabinet 1 through the fresh air box 301 to be supplemented, when the air passes through the dust filtering net 302, dust impurities carried in the air are blocked by the dust filtering net 302, then, the air enters the dehumidifying chamber 30101, the air flows along the first baffle 303 and the second baffle 304, the flowing time of the air in the fresh air box 301 is prolonged, the contact area between the air and the first baffle 303 and the second baffle 304 is increased, moisture in the air is absorbed by the first baffle 303 and the second baffle 304, then, the air enters the dispersing chamber 30102 at the upper part from the dehumidifying chamber 30101, then, the air is uniformly discharged into the control cabinet 1 from the through holes at the upper part of the dispersing chamber 30102, the air pressure in the control cabinet 1 is supplemented, and the temperature in the control cabinet 1 is reduced.

According to fig. 1 and 14-15, the dual-channel cooling unit comprises a cooling box 401, a partition plate 402, a first air duct 403, a power assembly 404, a second air duct 405, a heat collection box 406, a third air duct 407 and a T-shaped pipe 408; the upper part of the rear side of the control cabinet 1 is provided with a cooling box 401; the upper part of the front side of the cooling box 401 is fixedly connected with the dehumidifying cover 101; four partition plates 402 are welded in the cooling box 401; the cooling box 401 is divided into five spaces by four partition plates 402; the upper parts of the four partition plates 402 are respectively provided with a through hole; five spaces in the cooling box 401 are communicated through holes in the upper parts of four partition plates 402; the four partition plates 402 are fixedly connected with first air guide pipes 403; the upper part of the first air duct 403 is communicated with the dehumidifying cover 101; the lower part of the rear side of the control cabinet 1 is provided with a power component 404; the upper part of the power assembly 404 is communicated with the first air duct 403; a second air duct 405 is communicated with the rear part of the power assembly 404; the lower part of the second air duct 405 is communicated with the new air box 301; five heat collection boxes 406 are equidistantly welded at the rear part of the cooling box 401; the front parts of the five heat collection boxes 406 are communicated with five spaces in the cooling box 401; a third air duct 407 is fixedly connected to the lower parts of the five heat collection boxes 406; the lower parts of the five third air guide pipes 407 are fixedly connected with T-shaped pipes 408; the lower portion of the tee 408 communicates with the second airway 405.

Two-channel cooling stage: after the hot air is filtered for the second time, the power component 404 is started, the hot air is pumped out of the dehumidifying cover 101 by the power component 404 through the first air duct 403, the hot air flows along the first air duct 403, the cooling box 401 cools the air in the first air duct 403, then the cooled dry air is discharged into the dehumidifying cavity 30101 through the second air duct 405, the dry air enters the dispersing cavity 30102 from the dehumidifying cavity 30101 and then enters the control cabinet 1 from the dispersing cavity 30102, the dry air absorbs moisture on the surfaces of functional parts in the control cabinet 1, and the dry air sucked by the moisture enters the dehumidifying unit and the filtering unit again along with the suction force of the power component 404 after being started, the hot air enters the cooling box 401 from the through hole in the upper part of the rear side of the dehumidifying cover 101 while the air is led out through the first air duct 403, the hot air entering the cooling box 401 from the through hole in the upper part of the rear side of the dehumidifying cover 101 enters five spaces separated by the four partition plates 402 respectively, and then enters the fifth air duct 408 from the fifth air duct 408 to the fifth air duct 408, and the fifth air duct 408 flows into the fifth air duct 408 correspondingly, and the fifth air duct 405 flows into the fifth air duct 408.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted equally without departing from the spirit and scope of the technical solution of the present invention.

Claims (9)

1. A reactive compensation control cabinet with a normal temperature dehumidification function comprises a control cabinet (1), an instrument panel (2) and a cabinet door (3); the upper part of the control cabinet (1) is connected with an instrument panel (2); the left part of the front side of the control cabinet (1) is movably connected with a cabinet door (3); the method is characterized in that: the system also comprises a dehumidifying unit, a filtering unit, a fresh air unit and a double-channel cooling unit; the upper part of the control cabinet (1) is connected with a dehumidifying unit for dehumidifying the air in the control cabinet (1); the upper part of the control cabinet (1) is connected with a filtering unit for filtering air dust impurities in the control cabinet (1); the lower part of the control cabinet (1) is connected with a fresh air unit for removing the surface moisture of the internal parts of the control cabinet (1); the rear part of the control cabinet (1) is connected with a double-channel cooling unit for cooling high-temperature air in the control cabinet (1); the rear part of the instrument panel (2) is connected with the dehumidifying unit; the rear part of the instrument panel (2) is connected with the filtering unit; the interior of the dehumidification unit is connected with the filtering unit; the rear part of the dehumidifying unit is connected with the double-channel cooling unit; the rear part of the fresh air unit is connected with the double-channel cooling unit;

the dehumidifying unit comprises a dehumidifying cover (101), a first L-shaped plate (102), a collecting box (103), an electric sliding rail (104), an electric sliding block (105), a mounting plate (106), a limiting frame (107), a sponge block (108) and an inclined rod (109); the upper surface of the control cabinet (1) is fixedly connected with a dehumidifying cover (101); the dehumidifying cover (101) is internally connected with the filtering unit; the rear side of the dehumidifying cover (101) is connected with the double-channel cooling unit; a through groove (10101) is formed at the lower part of the dehumidifying cover (101); the rear middle part of the inner bottom surface of the dehumidifying cover (101) is fixedly connected with a first L-shaped plate (102); the upper part of the first L-shaped plate (102) is provided with a plurality of through holes; the upper part of the first L-shaped plate (102) is connected with the filtering unit; the upper surface of the first L-shaped plate (102) is fixedly connected with a collecting box (103); the bottom of the collecting box (103) is provided with a plurality of through holes which are matched with the through holes at the upper part of the first L-shaped plate (102); an electric sliding rail (104) is arranged at the upper part of the rear side of the instrument panel (2); two electric sliding blocks (105) are connected to the electric sliding rail (104) in a sliding manner; the rear sides of the two electric sliding blocks (105) are fixedly connected with a mounting plate (106) respectively; the lower parts of the two mounting plates (106) are connected with the filtering unit; a limit frame (107) is fixedly connected to the upper part of the inner rear wall of the dehumidifying cover (101); a water filtering groove (10701) is arranged at the lower part of the limit frame (107); a wedge-shaped cover (10702) is fixedly connected to the upper part of the limit frame (107); a sponge block (108) is connected in a sliding way in the limit frame (107); the sponge block (108) is positioned above the water filtering groove (10701); the rear sides of the two mounting plates (106) are fixedly connected with an inclined rod (109) respectively; the rear part between the two inclined rods (109) is fixedly connected with the sponge block (108).

2. The reactive compensation control cabinet with normal temperature dehumidification function according to claim 1, wherein: the tail ends of the rear parts of the two inclined rods (109) are spherical ends, and when the two inclined rods (109) are used for extruding the sponge block (108), water on the sponge block (108) drops along the spherical ends of the two inclined rods (109), so that water drops are prevented from adhering to the two inclined rods (109).

3. The reactive compensation control cabinet with normal temperature dehumidification function according to claim 1, wherein: the filtering unit comprises a first electric actuator (201), a second L-shaped plate (202), a dust filtering box (203), a first support plate (204), a bidirectional screw rod (205), a first driving wheel (206), a driving rod (207), a second driving wheel (208), a cam (209), a sliding rod (2010), a dust sweeping plate (2011), a first elastic piece (2012), a T-shaped plate (2013), a second electric actuator (2014), a collecting box (2015), a flow guiding pipe (2016), a second support plate (2017), a third support plate (2018), a second elastic piece (2019) and a sealing plate (2020); a first electric actuator (201) is respectively arranged at the left part of the inner bottom surface and the right part of the inner bottom surface of the dehumidifying cover (101); the upper ends of the telescopic parts of the two first electric actuators (201) are fixedly connected with a second L-shaped plate (202) respectively; the lower parts of the opposite sides of the two second L-shaped plates (202) are fixedly connected with dust filtering boxes (203); the outer surface of the dust filtering box (203) is in sliding connection with the dehumidifying cover (101); a filter screen is arranged in the dust filtering box (203); the lower sides of the two mounting plates (106) are fixedly connected with a first support plate (204) respectively; the upper part in the dehumidifying cover (101) is rotationally connected with a bidirectional screw rod (205); the left part and the right part of the bidirectional screw rod (205) are respectively screwed with a first support plate (204); the left part and the right part of the outer surface of the bidirectional screw rod (205) are fixedly connected with a first driving wheel (206) respectively; the left part and the right part in the dehumidifying cover (101) are respectively connected with a transmission rod (207) in a rotating way; the outer surfaces of the two transmission rods (207) are fixedly connected with a second transmission wheel (208) respectively; the outer annular surfaces of the two second driving wheels (208) are respectively connected with one first driving wheel (206) in a driving way through belts; the outer surfaces of the two transmission rods (207) are fixedly connected with a cam (209) respectively; the two cams (209) are positioned between the two second driving wheels (208); a sliding rod (2010) is fixedly connected to the left part and the right part of the rear side of the instrument panel (2); the rear ends of the two sliding rods (2010) are fixedly connected with the dehumidifying cover (101); a dust sweeping plate (2011) is connected between the two sliding rods (2010) in a sliding manner; the left part and the right part of the rear side of the dust sweeping plate (2011) are fixedly connected with a first elastic piece (2012) respectively; the rear parts of the two first elastic pieces (2012) are fixedly connected with the dehumidifying cover (101); the upper left part of the rear side of the dust sweeping plate (2011) and the upper right part of the rear side are fixedly connected with a T-shaped plate (2013) respectively; two first elastic members (2012) are positioned between the two T-shaped plates (2013); a second electric actuator (2014) is respectively arranged at the lower left part of the inner rear wall and the lower right part of the inner rear wall of the dehumidifying cover (101); the front ends of the telescopic parts of the two second electric actuators (2014) are fixedly connected with a collecting box (2015); the lower part of the collecting box (2015) is connected with the dehumidifying cover (101) in a sliding way; the left part and the right part of the rear side of the collecting box (2015) are respectively communicated with a flow guide pipe (2016); a second support plate (2017) is fixedly connected to the middle part of the rear side of the collecting box (2015); a third support plate (2018) is fixedly connected to the upper left part and the upper right part of the first L-shaped plate (102) respectively; the front part and the rear part of the opposite sides of the two third support plates (2018) are fixedly connected with a second elastic piece (2019) respectively; sealing plates (2020) are fixedly connected to the opposite sides of the two front second elastic pieces (2019) respectively; sealing plates (2020) are fixedly connected to the opposite sides of the two second elastic pieces (2019) at the rear; the upper surfaces of the two sealing plates (2020) are in sliding connection with the first L-shaped plate (102); the opposite sides of the two sealing plates (2020) are wedge-shaped surfaces, and a plurality of through holes are formed in the two sealing plates (2020).

4. A reactive compensation control cabinet with normal temperature dehumidification function according to claim 3, characterized in that: the lower part of the dust sweeping plate (2011) is provided with a plurality of flexible bristles which are used for stirring and sweeping dust impurities on a filter screen in the dust filtering box (203).

5. A reactive compensation control cabinet with normal temperature dehumidification function according to claim 3, characterized in that: the inner bottom of the collecting box (2015) is high at the middle and low at the left and right, and is used for transferring the collected objects to the left and right sides.

6. A reactive compensation control cabinet with normal temperature dehumidification function according to claim 3, characterized in that: the sealing plate (2020) is provided with a plurality of through holes and is communicated with the through holes at the upper part of the first L-shaped plate (102) for conducting the first L-shaped plate (102) and the sealing plate (2020).

7. The reactive compensation control cabinet with normal temperature dehumidification function according to claim 1, wherein: the fresh air unit comprises a fresh air box (301), a dust filtering net (302), a first baffle (303) and a second baffle (304); a fresh air box (301) is fixedly connected to the lower surface of the control cabinet (1); a dehumidifying cavity (30101) is arranged in the new air box (301); a dispersion cavity (30102) is formed in the new air box (301); the dispersing cavity (30102) is positioned above the dehumidifying cavity (30101), and the dehumidifying cavity (30101) and the dispersing cavity (30102) are communicated through a plurality of through holes in the middle; the rear side of the new air box (301) is connected with the double-channel cooling unit; the left part and the right part of the new air box (301) are respectively provided with a dust filtering net (302); three first baffles (303) are fixedly connected to the upper left part of the dehumidifying cavity (30101) at equal intervals; three first baffles (303) are fixedly connected to the right part of the dehumidifying cavity (30101) at equal intervals; three second baffles (304) are fixedly connected to the lower left part of the dehumidifying cavity (30101) at equal intervals; three second baffles (304) are fixedly connected at equal intervals on the lower right part of the dehumidifying cavity (30101); a first baffle (303) and a second baffle (304) on the same side in the dehumidifying cavity (30101) are arranged alternately.

8. The reactive compensation control cabinet with normal temperature dehumidification function according to claim 7, wherein: the first baffle (303) and the second baffle (304) are made of sponge materials capable of absorbing water, are used for absorbing water in the air and are used for primarily filtering dust and impurities in the air.

9. The reactive compensation control cabinet with normal temperature dehumidification function according to claim 1, wherein: the double-channel cooling unit comprises a cooling box (401), a partition plate (402), a first air duct (403), a power assembly (404), a second air duct (405), a heat collection box (406), a third air duct (407) and a T-shaped pipe (408); a cooling box (401) is arranged at the upper part of the rear side of the control cabinet (1); the upper part of the front side of the cooling box (401) is fixedly connected with the dehumidifying cover (101); four partition plates (402) are fixedly connected in the cooling box (401); the cooling box (401) is divided into five spaces by four partition plates (402); the upper parts of the four partition plates (402) are respectively provided with a through hole; five spaces in the cooling box (401) are communicated through holes at the upper parts of four partition plates (402); the four partition plates (402) are fixedly connected with first air guide pipes (403); the upper part of the first air duct (403) is communicated with the dehumidifying cover (101); a power component (404) is arranged at the lower part of the rear side of the control cabinet (1); the upper part of the power assembly (404) is communicated with the first air duct (403); the rear part of the power component (404) is communicated with a second air duct (405); the lower part of the second air duct (405) is communicated with the new air box (301); five heat collection boxes (406) are fixedly connected at equal intervals at the rear part of the cooling box (401); the front parts of the five heat collection boxes (406) are communicated with five spaces in the cooling box (401); a third air duct (407) is fixedly connected to the lower parts of the five heat collection boxes (406); the lower parts of the five third air guide pipes (407) are fixedly connected with T-shaped pipes (408); the lower part of the T-shaped pipe (408) is communicated with the second air guide pipe (405).