CN115282745A - Dehumidifier with anti-static structure for optical control equipment and use method - Google Patents

Abstract

The invention discloses a dehumidifier with an antistatic structure for optical control equipment and a using method thereof, and relates to the technical field of antistatic of electric cabinet dehumidifiers, the dehumidifier comprises a dehumidifier shell, an antistatic mechanism and an air guide mechanism, wherein an air guide sleeve is embedded in the dehumidifier shell, cylindrical filter cotton is plugged into the air guide sleeve from an opening structure of the air guide sleeve, one end of the air guide sleeve close to the opening structure is connected with the end part of an air inlet pipe, the side wall of one air storage box is connected with the end part of an air outlet pipe, one end of the air guide sleeve close to a closed structure is connected with a communicating pipe, the communicating pipe is communicated with the side wall of the other air storage box, a heating wire is embedded in the inner wall of the communicating pipe, a power shaft of a motor penetrates through the dehumidifier shell in a rotating manner and then extends into the one air storage box, and the end part of the power shaft is fixedly connected with a first fan blade positioned in the air storage box. The invention utilizes the static electricity removing mechanism and the air guide mechanism to carry out heat exchange and static electricity removing operation on high-temperature static air, thereby avoiding the electric appliance components from working in static electricity and dry high-temperature environments.

Description

Dehumidifier with anti-static structure for optical control equipment and use method

Technical Field

The invention relates to the technical field of electrostatic prevention of electric cabinet dehumidifiers, in particular to a dehumidifier with an electrostatic prevention structure for optical control equipment and a use method of the dehumidifier.

Background

In the use process of the optical control equipment, the phenomenon of circuit short circuit can be caused because the generated heat meets cold air to generate cold frost, and the dehumidifier is special equipment for removing water vapor in the air in the optical control equipment and keeping the internal environment of the optical control equipment dry so as to prevent the internal circuit of the electric cabinet from short circuit;

at present, the dehumidification device used by domestic optical control equipment is generally dehumidification by a heating method, the heating mode can rapidly process the moisture inside an electric cabinet, the daily working process of the electric cabinet is performed in the optical control equipment, static electricity can be generated and distributed in the cabinet body, the electricity safety of the electric cabinet is seriously influenced, the heating type dehumidification is adopted, the static electricity is more easily influenced on a circuit in the high-temperature drying environment in the cabinet body, the risk of line faults is further increased, and therefore, the dehumidifier with the anti-static structure and the use method are designed, so that the problems are solved.

Disclosure of Invention

The present invention is directed to a dehumidifier for optical control equipment with an antistatic structure and a method for using the same, so as to solve the problems of the background art.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a dehumidifier for optical control equipment with prevent static structure, including the dehumidifier casing, static mechanism and air guide mechanism remove, the inside respectively embedded intake pipe and outlet duct that has of dehumidifier casing, the intake pipe is the copper material, the tip of intake pipe and outlet duct extends to lateral wall about the dehumidifier casing, intake pipe and outlet duct are used for docking optical control equipment internally mounted electrical components's space, the high temperature air that has static that optical control equipment inner space produced passes through the intake pipe and derives, finally can lead back optical control equipment inner space through the outlet duct, realize optical control equipment inner space circulation of air, so that static mechanism removes static operation and air guide mechanism carries out the heat transfer operation.

Destatic mechanism includes cylindricality filter pulp and sealed piece, the inside air guide sleeve that has the copper material of inlaying of dehumidifier casing, the inside copper conducting rod that has can ground connection of inlaying of dehumidifier casing, and the tip and the air guide sleeve outer wall connection of copper conducting rod, the intake pipe, air guide sleeve and copper conducting rod constitute the conductor and be used for the conduction static, the intake pipe of copper material can conduct the static in the air as electrically conductive, derive through the air guide sleeve and the copper conducting rod of copper material, avoid the static to cause the influence to the circuit.

The one end of wind-guiding sleeve is seal structure, the other end is open structure, wind-guiding sleeve's open structure one end extends to dehumidifier casing front side lateral wall, the cylindricality is filtered the cotton and is fixed to be set up at the sealed piece lateral wall, the cylindricality is filtered the cotton and is filled in inside the wind-guiding sleeve from wind-guiding sleeve open structure, and sealed piece passes through external screw thread and wind-guiding sleeve opening inner wall internal thread connection, the wind-guiding sleeve is close to open structure's one end and intake pipe end connection, the high temperature air that contains static through the wind-guiding sleeve passes through moist cylindricality and filters the cotton, can cool down with moist cylindricality and filter the cotton contact, the cylindricality is filtered the cotton simultaneously and can also filters the impurity that mixes in the air, more importantly, static is filtered the cotton through moist cylindricality, can be eliminated, still mix in avoiding leading-in the air to communicating pipe and have static to enter into the cooling tube, finally lead back optical control equipment inner space once more.

Air guide mechanism includes motor and guide duct, the standing groove has been seted up to the left side lateral wall of dehumidifier casing, the guide duct is located inside the standing groove, and the both ends of guide duct are connected with the wind box that stores up respectively, one of them wind box lateral wall and outlet duct end connection, the wind guide sleeve is close to enclosed construction one end and is connected with communicating pipe, communicating pipe and another wind box lateral wall intercommunication that stores up, the inside high temperature of optical control equipment and the air that has static derive from optical control equipment inner space through the intake pipe, enter into the wind guide sleeve, then lead to one of them wind box that stores up through communicating pipe, through the guide duct cooling, derive from another wind box that stores up afterwards and derive through the outlet duct, get into optical control equipment inner space once more, the guide duct is located the standing groove, the guide duct exposes in the outside air promptly, help carrying out the heat transfer operation to the high temperature air of flowing through the guide duct.

The heating wire is embedded in the inner wall of the communicating pipe, the heating temperature of the heating wire is preset, the air after heating is guaranteed to be lower than the temperature of the inner space of the optical control equipment, the moist air is heated by the heating wire and becomes dry, then the air is cooled through the air guide pipe, the air temperature guided back to the inside of the optical control equipment is guaranteed to be lower than the temperature of the inside of the optical control equipment, and the air is dry and free of static electricity.

The motor is fixedly arranged on the side wall of the rear side of the dehumidifier shell, a power shaft of the motor rotates to penetrate through the dehumidifier shell and then extends into one of the air storage boxes, and the end part of the power shaft is fixedly connected with a first fan blade located in the air storage box.

In a further embodiment, the air guide mechanism further comprises a cooling pipe, the cooling pipe is positioned inside the placing groove, and two ends of the cooling pipe are respectively and fixedly connected with the side walls at two sides inside the placing groove;

the guide duct and two wind storage boxes are located inside the cooling tube, one of the wind storage boxes is fixedly connected with one end of the cooling tube in the axial direction, the cooling tube serves as a cooling place, wind energy blown up by the second fan blade can be conveyed along the axial direction inside the cooling tube, the wind energy can be stored for a short time, the wind energy can flow inside the cooling tube, the guide duct is convenient to cool, heat exchange operation is carried out on heated wind in the guide duct through the guide duct, and effective cooling operation is achieved.

In a further embodiment, the outer wall of the power shaft of the motor is fixedly sleeved with a second fan blade positioned at one end inside the cooling pipe.

In a further embodiment, the outer wall of the cooling pipe is provided with a plurality of heat dissipation holes which are uniformly distributed at intervals.

In further embodiment, sealing block outer wall connection has the connecting pipe, and the tip of connecting pipe has L type to dock the pipe through external screw thread connection, and the end connection that the L type docked the pipe has the stock solution box, through filling up the running water in the stock solution box, then docks the L type of stock solution box tip to dock pipe and connecting pipe, and water in the stock solution box pours into the cylindricality filter pulp into through L type to dock pipe and connecting pipe in for the cylindricality filter pulp is in moist state in real time.

The outer wall of the sealing block is provided with a rubber sealing gasket.

In further embodiment, the one end that the connecting pipe was kept away from to sealed piece is connected with the catheter that communicates with the connecting pipe, a plurality of drain hole has been seted up to the outer wall of catheter, cylindricality filter pulp axial lateral wall sets up the spliced eye of pegging graft with the catheter, water in the stock solution box is passed through L type and is passed through in the pipe is poured into the drain to the connecting pipe, the running water sees through in the drain hole excessive cylindricality filter pulp for adsorb moisture fast on the cylindricality filter pulp, thereby can filter impurity and eliminate static.

In a further embodiment, a docking mechanism is attached to the right side wall of the dehumidifier housing.

Docking mechanism includes docking sleeve and threaded sleeve, docking sleeve fixed welding is at the right side lateral wall of dehumidifier casing, docking sleeve slides through T type spliced eye and pegs graft and has copper butt joint pipe, copper butt joint pipe is located the telescopic one end fixedly connected with of butt joint and can be along the spacing dish of T type spliced eye inner wall horizontal slip copper, inlet port and venthole have been seted up to the axial direction of copper butt joint pipe and the spacing dish of copper, all be connected with the copper bellows between inlet port and the intake pipe and between venthole and the outlet duct, utilize the copper bellows to connect intake pipe and outlet duct respectively as copper butt joint pipe, the realization switches on the route of gaseous intercommunication.

The fixed rotation of screw sleeve cup joints the one end that is located the butt joint sleeve outside at copper butt joint pipe, and the outer wall of copper butt joint pipe is fixed to be adjusted to have and is located the inside separation dish of screw sleeve.

In a further embodiment, four corner positions of the right end face of the dehumidifier shell are fixedly provided with four jacking columns, and the four jacking columns are used for enhancing the installation stability of the dehumidifier shell and the stability of the docking mechanism during docking.

In a further embodiment, the sum of the lengths of the butt joint sleeve and the copper butt joint pipe is equal to the length of the jacking column, the end portion of the jacking column is abutted to the outer wall of the optical control device, feeding is continuously performed along with rotation of the threaded sleeve, the copper butt joint pipe horizontally slides along the inner wall of the T-shaped plug hole, when the air inlet hole and the air outlet hole are respectively and seamlessly attached to two through holes formed in the butt joint pipeline, the threaded sleeve cannot rotate and feed along the outer wall of the butt joint pipeline, and meanwhile the end portion of the jacking column can be stably abutted to the outer wall of the optical control device.

Preferably, based on the above mentioned dehumidifier for optical control equipment with antistatic structure and its using method, the method comprises the following steps:

a1, forming a conductor by an air inlet pipe, an air guide sleeve and a copper conducting rod for conducting static electricity, wherein the air inlet pipe made of copper can conduct the static electricity in the air as a conducting piece, and the static electricity is led out through the air guide sleeve made of copper and the copper conducting rod, so that the influence of the static electricity on a circuit is avoided;

a2, the high temperature air that contains static through air guide sleeve passes through moist cylindricality filter pulp, can cool down with the contact of moist cylindricality filter pulp, and the impurity that dopes in the air can also be filtered to the cylindricality filter pulp simultaneously, and more importantly, static can be eliminated through moist cylindricality filter pulp.

Compared with the prior art, the invention has the beneficial effects that:

the invention relates to a dehumidifier with an anti-static structure for optical control equipment and a use method thereof.A dehumidifier shell is arranged outside the optical control equipment, meanwhile, an air inlet pipe made of copper extends into the optical control equipment to be used as a conductive piece, static electricity is led out of the optical control equipment through an air guide sleeve made of copper and a copper conductive rod, heat generated by electrical components in the optical control equipment is led out by utilizing an air guide mechanism to carry out rapid heat exchange operation, air with static electricity can be humidified and then dried, the air with static electricity can be largely eliminated after being humidified, the electrical appliances in the optical control equipment are prevented from working in the environment of static electricity and high drying temperature, and therefore, the electricity utilization potential safety hazard of the electrical components in the optical control equipment and the occurrence probability of circuit faults are reduced.

Drawings

FIG. 1 is a schematic view of the main structure of the present invention;

FIG. 2 is a schematic diagram of the dehumidifier housing of the present invention;

FIG. 3 is a cross-sectional view of the docking mechanism of the present invention;

FIG. 4 is an exploded view of the static discharge mechanism of the present invention;

fig. 5 is an exploded view of a local mechanism of the air guiding mechanism of the present invention;

FIG. 6 is a cross-sectional view of the dehumidifier housing of the present invention;

fig. 7 is a partial cross-sectional view of the present invention.

In the figure: 1. a dehumidifier housing; 11. jacking the column; 12. a placement groove; 13. an air outlet pipe; 14. an air inlet pipe; 15. an air guide sleeve; 16. a communicating pipe; 2. a docking mechanism; 21. butting the sleeves; 22. copper butt joint pipe; 23. a threaded sleeve; 24. a divider disk; 25. copper limiting discs; 26. a copper bellows; 3. a static electricity removing mechanism; 31. a sealing block; 32. a liquid storage box; 33. an L-shaped butt joint pipe; 34. a connecting pipe; 35. a rubber gasket; 36. a catheter; 37. cylindrical filter cotton; 4. an air guide mechanism; 41. a cooling tube; 42. heat dissipation holes; 43. a motor; 44. a second fan blade; 45. a first fan blade; 46. a wind storage box; 47. an air guide pipe.

Detailed Description

The following will clearly and completely describe the technical solutions in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Referring to fig. 1, 2, 4, 5, 6 and 7, this embodiment provides a dehumidifier for an optical control device with an anti-static structure and a method for using the same, including a dehumidifier casing 1, a static electricity removing mechanism 3 and an air guiding mechanism 4, an air inlet pipe 14 and an air outlet pipe 13 are respectively embedded in the dehumidifier casing 1, ends of the air inlet pipe 14 and the air outlet pipe 13 extend to left and right side walls of the dehumidifier casing 1, the air inlet pipe 14 and the air outlet pipe 13 are used for butting a space in which electrical components are installed inside the optical control device, high-temperature air with static electricity generated in an internal space of the optical control device is guided out through the air inlet pipe 14, and finally, the high-temperature air with static electricity generated in the internal space of the optical control device can be guided back to the internal space of the optical control device through the air outlet pipe 13, so as to facilitate the static electricity removing operation of the static electricity removing mechanism 3 and the heat exchanging operation of the air guiding mechanism 4.

In the daily work process of electrical appliances in the optical control equipment, static electricity can be generated and distributed in the cabinet, the electricity utilization safety of the electrical appliances in the cabinet is seriously influenced, in order to lead out the static electricity in the optical equipment, the static electricity removing mechanism 3 comprises cylindrical filter cotton 37 and a sealing block 31, a copper air guide sleeve 15 is embedded in a dehumidifier shell 1, one end of the air guide sleeve 15 is of a sealing structure, the other end of the air guide sleeve is of an opening structure, an air inlet pipe 14 is made of copper, one end, close to the opening structure, of the air guide sleeve 15 is connected with the end portion of the air inlet pipe 14, a copper conductive rod 17 capable of being grounded is embedded in the dehumidifier shell 1, the end portion of the copper conductive rod 17 is connected with the outer wall of the air guide sleeve 15, the dehumidifier shell 1 is installed on the outer side wall of the optical control equipment, then the copper air inlet pipe 14 made of copper extends into the inner space of the optical control equipment, the air inlet pipe 14, the air guide sleeve 15 and the copper conductive rod 17 form a conductor for conducting static electricity, the copper air inlet pipe 14 made of copper material serves as the conductive component for conducting static electricity in the air guide sleeve 15, and the copper conductive rod 17 are prevented from influencing the static electricity.

The air guide mechanism 4 comprises a motor 43 and an air guide pipe 47, a placing groove 12 is formed in the left side wall of the dehumidifier shell 1, the air guide pipe 47 is located inside the placing groove 12, two ends of the air guide pipe 47 are respectively connected with air storage boxes 46, the side wall of one air storage box 46 is connected with the end portion of an air outlet pipe 13, one end, close to a closed structure, of the air guide sleeve 15 is connected with a communicating pipe 16, the communicating pipe 16 is communicated with the side wall of the other air storage box 46, high-temperature and static air inside the optical control equipment is led out from the internal space of the optical control equipment through an air inlet pipe 14 and enters the air guide sleeve 15, then the high-temperature and static air is led into one air storage box 46 through the communicating pipe 16, is cooled through the air guide pipe 47, then is led out from the other air storage box 46 and led out through the air outlet pipe 13 and enters the internal space of the optical control equipment again, the air guide pipe 47 is located in the placing groove 12, namely the air guide pipe 47 is exposed to the outside air, and is favorable for carrying out heat exchange operation on the high-temperature air passing through the air guide pipe 47.

Meanwhile, the air guide pipe 47 can be set to be of an S-shaped structure or a spiral structure, so that the time of high-temperature air flowing through the air guide pipe 47 is prolonged in a limited space, and the heat exchange efficiency is improved.

The motor 43 is fixed to be set up at 1 rear side lateral wall of dehumidifier casing, the power shaft of motor 43 rotates and runs through behind the dehumidifier casing 1 and extends to inside one of them wind storage box 46, and the tip fixedly connected with of power shaft is located the inside first flabellum 45 of wind storage box 46, utilize motor 43 to provide power and drive first flabellum 45 and rotate, first flabellum 45 rotates and produces wind-force, the direction that blows is blown to the wind storage box 46 that first flabellum 45 was located from communicating pipe 16 one side in, make the high temperature air of taking out in the follow optical control equipment carry out the heat transfer operation through the cooling of guide duct 47.

The open structure one end of air guide sleeve 15 extends to dehumidifier casing 1 front side lateral wall, cylindricality filter pulp 37 is fixed to be set up at sealed piece 31 lateral wall, spray the running water on cylindricality filter pulp 37, make cylindricality filter pulp 37 be in moist state, then fill in cylindricality filter pulp 37 inside air guide sleeve 15 from air guide sleeve 15 open structure, after cylindricality filter pulp 37 inserts air guide sleeve 15 inside completely, with sealed piece 31 through external screw thread and air guide sleeve 15 opening inner wall female connection, the opening of air guide sleeve 15 is plugged up in, avoid passing through the inside air of air guide sleeve 15 and blow out from air guide sleeve 15's opening.

The high-temperature air containing static electricity passing through the air guide sleeve 15 can contact with the wet cylindrical filter cotton 37 to be cooled through the wet cylindrical filter cotton 37, meanwhile, the cylindrical filter cotton 37 can also filter impurities doped in the air, more importantly, the static electricity can be eliminated through the wet cylindrical filter cotton 37, the air led into the communicating pipe 16 is prevented from being doped with the static electricity to enter the cooling pipe 41, and finally, the static electricity is led back to the inner space of the optical control device again.

After passing through the moist cylindrical filter cotton 37, the high-temperature air with static electricity is eliminated, but the static electricity is eliminated, the air becomes moist, if the high-temperature air is directly led back to the internal space of the optical control equipment, the moist air still can bring potential safety hazards to circuits of electrical components inside the optical control equipment, and lines are easy to be connected in series and parallel.

After high-temperature air circulates through the wet cylindrical filter cotton 37, water sprinkled on the surface of the cylindrical filter cotton 37 can be dried, so that static electricity cannot be further eliminated after the cylindrical filter cotton 37 is dried, the sealing block 31 is frequently disassembled to sprinkle water for the cylindrical filter cotton 37, and is troublesome.

The outer wall of the sealing block 31 is provided with a rubber gasket 35, and the sealing performance of the sealing block 31 for sealing the opening of the air guide sleeve 15 can be enhanced by additionally arranging the rubber gasket 35.

In order to make the cylindricality filter pulp 37 go up quick adsorbed moisture, the one end of keeping away from connecting pipe 34 at sealed piece 31 is connected with the catheter 36 with the connecting pipe 34 intercommunication, a plurality of drain hole has been seted up to the outer wall of catheter 36, cylindricality filter pulp 37 axial lateral wall sets up the spliced eye of pegging graft with catheter 36, water in the liquid storage box 32 pours into in pipe 33 and the connecting pipe 34 injection catheter 36 into through the L type, the running water sees through in the excessive cylindricality filter pulp 37 of drain hole, make the cylindricality filter pulp 37 go up quick adsorbed moisture, thereby can filter impurity and eliminate static.

Example two

Please refer to fig. 1, fig. 5, fig. 6 and fig. 7, which are further improved based on embodiment 1:

in order to further reduce the temperature of the air heated by the heating wire, the air guiding mechanism 4 further comprises a cooling pipe 41, the cooling pipe 41 is located inside the placing groove 12, two ends of the cooling pipe 41 are respectively and fixedly connected with two side walls inside the placing groove 12, the air guiding pipe 47 and two air storage boxes 46 are located inside the cooling pipe 41, one of the air storage boxes 46 is fixedly connected with one axial end inside the cooling pipe 41, one of the air storage boxes 46 is fixed at one end inside the cooling pipe 41, and thus the air guiding pipe 47 and the other air storage box 46 can be raised inside the cooling pipe 41.

The fixed cover of the power shaft outer wall of motor 43 has been connected with the second flabellum 44 that is located the inside one end of cooling tube 41, motor 43 provides power and drives first flabellum 45 pivoted and can drive second flabellum 44 synchronous revolution simultaneously, and the direction that second flabellum 44 provided the wind force is for blowing to the one end of keeping away from motor 43 from the inside one end that is close to motor 43 of cooling tube 41, and cooling tube 41 is as the cooling place, the wind that second flabellum 44 blown up can be along the inside axial direction conveying of cooling tube 41, can also play the effect of short time wind storage simultaneously, wind can flow in cooling tube 41, be convenient for cool off guide duct 47, the wind that is heated in the guide duct 47 is carried out the heat exchange operation to the wind that separates guide duct 47, realize effective cooling operation.

Through the louvre 42 of seting up a plurality of even interval distribution at the outer wall of cooling tube 41, the wind that second flabellum 44 was blown up can be derived from louvre 42 when along the inside flow of cooling tube 41, avoids the inside high temperature of cooling tube 41.

EXAMPLE III

Referring to fig. 1-3, a further improvement is made on the basis of embodiment 2:

the right side wall of the dehumidifier shell 1 is connected with the docking mechanism 2, and the docking mechanism 2 is docked with the inner space of the optical control equipment to realize quick disassembly and assembly.

Docking mechanism 2 includes docking sleeve 21 and threaded sleeve 23, docking sleeve 21 fixed welding is at the right side lateral wall of dehumidifier casing 1, docking sleeve 21 slides through T type spliced eye and pegs graft and has copper butt joint pipe 22, copper butt joint pipe 22 is located the one end fixedly connected with of docking sleeve 21 can be along the spacing dish 25 of the copper of T type spliced eye inner wall horizontal slip, copper butt joint pipe 22 can slide along the inside horizontal slip of T type spliced eye of docking sleeve 21, avoid copper butt joint pipe 22 to break away from docking sleeve 21 through the spacing dish 25 of copper, by docking sleeve 21, copper butt joint pipe 22 and the spacing dish 25 constitution butt joint pipeline of copper.

The axial direction of copper butt joint pipe 22 and copper spacing dish 25 has seted up inlet port and venthole, with all being connected with copper bellows 26 between inlet port and the intake pipe 14 and between venthole and the outlet duct 13, utilize copper bellows 26 to connect intake pipe 14 and outlet duct 13 respectively as copper butt joint pipe 22, realize switching on the route of gaseous intercommunication.

The threaded sleeve 23 is fixedly and rotatably sleeved at one end, located outside the butt joint sleeve 21, of the copper butt joint pipe 22, a separation disc 24 located inside the threaded sleeve 23 is fixedly adjusted on the outer wall of the copper butt joint pipe 22, an air inlet hole and an air outlet hole of the copper butt joint pipe 22 are in butt joint with the air inlet pipe 14 and the air outlet pipe 13 through copper corrugated pipes 26 respectively, then the other ends of the air inlet hole and the air outlet hole in the copper butt joint pipe 22 are opposite to two through holes formed in the butt joint pipe preset in the outer wall of the optical control equipment, then the threaded sleeve 23 is rotated to rotate the threaded sleeve 23 to the outer wall of the butt joint pipe until the air inlet hole and the air outlet hole are in seamless fit with the two through holes formed in the butt joint pipe respectively.

The four jacking columns 11 are fixedly arranged at the four corner positions of the right end face of the dehumidifier shell 1, so that the four jacking columns 11 are utilized to enhance the installation stability of the dehumidifier shell 1 and the stability of the docking mechanism 2 during docking.

In addition, the sum of the lengths of the abutting sleeve 21 and the copper abutting pipe 22 is equal to the length of the jacking column 11, the end portion of the jacking column 11 abuts against the outer wall of the optical control device, feeding is continuously performed along with rotation of the threaded sleeve 23, the copper abutting pipe 22 horizontally slides along the inner wall of the T-shaped inserting hole, when the air inlet hole and the air outlet hole are respectively and seamlessly attached to two through holes formed in the abutting pipeline, the threaded sleeve 23 cannot rotate and feed along the outer wall of the abutting pipeline, and meanwhile the end portion of the jacking column 11 can stably abut against the outer wall of the optical control device.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a dehumidifier for optical control equipment with prevent static structure, includes dehumidifier casing (1), destatics mechanism (3) and air guide mechanism (4), inside respectively embedded intake pipe (14) and outlet duct (13) of having of dehumidifier casing (1), intake pipe (14) are the copper material, the tip of intake pipe (14) and outlet duct (13) extends to lateral wall about dehumidifier casing (1), its characterized in that: the static electricity removing mechanism (3) comprises cylindrical filter cotton (37) and a sealing block (31), a copper air guide sleeve (15) is embedded in the dehumidifier shell (1), a copper conducting rod (17) capable of being grounded is embedded in the dehumidifier shell (1), and the end part of the copper conducting rod (17) is connected with the outer wall of the air guide sleeve (15);

one end of the air guide sleeve (15) is of a sealing structure, the other end of the air guide sleeve is of an opening structure, one end of the opening structure of the air guide sleeve (15) extends to the side wall of the front side of the dehumidifier shell (1), the cylindrical filter cotton (37) is fixedly arranged on the side wall of the sealing block (31), the cylindrical filter cotton (37) is plugged into the air guide sleeve (15) from the opening structure of the air guide sleeve (15), the sealing block (31) is connected with the inner thread of the opening inner wall of the air guide sleeve (15) through an external thread, and one end, close to the opening structure, of the air guide sleeve (15) is connected with the end part of the air inlet pipe (14);

the air guide mechanism (4) comprises a motor (43) and an air guide pipe (47), a placing groove (12) is formed in the side wall of the left side of the dehumidifier shell (1), the air guide pipe (47) is located inside the placing groove (12), two ends of the air guide pipe (47) are respectively connected with air storage boxes (46), the side wall of one air storage box (46) is connected with the end part of an air outlet pipe (13), one end, close to a closed structure, of the air guide sleeve (15) is connected with a communicating pipe (16), and the communicating pipe (16) is communicated with the side wall of the other air storage box (46);

a heating wire is embedded in the inner wall of the communicating pipe (16);

the motor (43) is fixedly arranged on the side wall of the rear side of the dehumidifier shell (1), a power shaft of the motor (43) penetrates through the dehumidifier shell (1) in a rotating mode and extends into one of the air storage boxes (46), and the end portion of the power shaft is fixedly connected with a first fan blade (45) located inside the air storage box (46).

2. The dehumidifier having an antistatic structure for optical control equipment according to claim 1, wherein: the air guide mechanism (4) further comprises a cooling pipe (41), the cooling pipe (41) is positioned inside the placing groove (12), and two ends of the cooling pipe (41) are fixedly connected with the side walls of two sides inside the placing groove (12) respectively;

the air guide pipe (47) and the two air storage boxes (46) are located inside the cooling pipe (41), and one of the air storage boxes (46) is fixedly connected with one axial end inside the cooling pipe (41).

3. The dehumidifier having an antistatic structure for optical control equipment according to claim 2, wherein: and a second fan blade (44) positioned at one end inside the cooling pipe (41) is fixedly sleeved on the outer wall of a power shaft of the motor (43).

4. A dehumidifier having an antistatic structure for optical control equipment according to claim 3, wherein: the outer wall of the cooling pipe (41) is provided with a plurality of heat dissipation holes (42) which are uniformly distributed at intervals.

5. The dehumidifier having an antistatic structure for optical control equipment according to claim 1, wherein: the outer wall of the sealing block (31) is connected with a connecting pipe (34), the end part of the connecting pipe (34) is connected with an L-shaped butt joint pipe (33) through external threads, and the end part of the L-shaped butt joint pipe (33) is connected with a liquid storage box (32);

and a rubber sealing gasket (35) is arranged on the outer wall of the sealing block (31).

6. The dehumidifier having an antistatic structure according to claim 5, wherein: one end, far away from the connecting pipe (34), of the sealing block (31) is connected with a liquid guide pipe (36) communicated with the connecting pipe (34), the outer wall of the liquid guide pipe (36) is provided with a plurality of liquid guide holes, and the axial side wall of the cylindrical filter cotton (37) is provided with inserting holes inserted with the liquid guide pipe (36).

7. The dehumidifier having an antistatic structure for optical control equipment according to claim 1, wherein: the right side wall of the dehumidifier shell (1) is connected with a docking mechanism (2);

the butt joint mechanism (2) comprises a butt joint sleeve (21) and a threaded sleeve (23), the butt joint sleeve (21) is fixedly welded on the right side wall of the dehumidifier shell (1), the butt joint sleeve (21) is provided with a copper butt joint pipe (22) in a sliding and inserting mode through a T-shaped inserting hole, one end, located on the butt joint sleeve (21), of the copper butt joint pipe (22) is fixedly connected with a copper limiting disc (25) capable of horizontally sliding along the inner wall of the T-shaped inserting hole, an air inlet hole and an air outlet hole are formed in the copper butt joint pipe (22) and the copper limiting disc (25) in the axial direction, and copper corrugated pipes (26) are connected between the air inlet hole and the air inlet pipe (14) and between the air outlet hole and the air outlet pipe (13);

the threaded sleeve (23) is fixedly sleeved at one end, located outside the butt joint sleeve (21), of the copper butt joint pipe (22) in a rotating mode, and a separation disc (24) located inside the threaded sleeve (23) is fixedly adjusted on the outer wall of the copper butt joint pipe (22).

8. The dehumidifier having an antistatic structure for optical control equipment according to claim 7, wherein: four corner positions of the right end face of the dehumidifier shell (1) are respectively fixedly provided with a jacking column (11).

9. The dehumidifier having an antistatic structure for optical control equipment according to claim 8, wherein: the sum of the lengths of the butting sleeve (21) and the copper butting pipe (22) is equal to the length of the jacking column (11).

10. A method for using a dehumidifier for optical control equipment having an antistatic structure, which comprises the steps of:

a1, an air inlet pipe (14), an air guide sleeve (15) and a copper conducting rod (17) form a conductor for conducting static electricity, the copper air inlet pipe (14) serving as a conducting piece can conduct static electricity in air, and the static electricity is prevented from affecting a circuit by the conducting piece (15) and the copper conducting rod (17) which are made of copper;

a2, the high-temperature air containing static electricity passing through the air guide sleeve (15) can contact with the wet cylindrical filter cotton (37) to be cooled through the wet cylindrical filter cotton (37), meanwhile, the cylindrical filter cotton (37) can filter impurities doped in the air, and more importantly, the static electricity can be eliminated through the wet cylindrical filter cotton (37).

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