CN113398724A

CN113398724A - Northern turbidity monitoring gas circuit dehydrating unit

Info

Publication number: CN113398724A
Application number: CN202110757917.6A
Authority: CN
Inventors: 宋庆利; 靳军莉; 于大江; 孙俊英; 吴艳玲
Original assignee: Longfengshan Regional Atmospheric Background Station; CMA Meteorological Observation Centre
Current assignee: Longfengshan Regional Atmospheric Background Station; CMA Meteorological Observation Centre
Priority date: 2021-07-05
Filing date: 2021-07-05
Publication date: 2021-09-17
Anticipated expiration: 2041-07-05
Also published as: CN113398724B

Abstract

The invention relates to a dehumidifying device, in particular to a northern turbidity monitoring gas path dehumidifying device, which comprises a condensing mechanism, a water squeezing support, a squeezing mechanism, a driving gear ring, a dehumidifying support, a swinging mechanism, a transverse moving mechanism and a filter plate, cold water can be introduced between the condensing mechanism and a dehumidifying drum, further condensing the moisture in the air, in order to ensure the drying of the condensing mechanism and the recycling of the device, an extrusion mechanism and a water squeezing bracket are arranged, the moisture condensed in the condensing mechanism is absorbed through the reciprocating motion of a water absorption column, the water absorbed in the water absorption column is discharged under the action of the squeezing mechanism and the water squeezing bracket, so that the water absorption column can be used repeatedly, the position of the dehumidification support is adjusted through the swing mechanism, the position of the swing mechanism is adjusted through the transverse moving mechanism, and the passing air is filtered through the filter plate.

Description

Northern turbidity monitoring gas circuit dehydrating unit

Technical Field

The invention relates to a dehumidifying device, in particular to a dehumidifying device for a northern turbidity monitoring gas circuit.

Background

A fresh air dehumidification system in the prior art comprises a fresh air refrigeration system, a dehumidification system and a control valve pipeline system; the fresh air refrigerating system comprises a compressor, a main condenser, a refrigerating throttling device and a refrigerating evaporator; the compressor, the main condenser, the refrigeration throttling device and the refrigeration evaporator form a refrigeration circulation flow path; the dehumidification system comprises the compressor, a refrigeration evaporator, a dehumidification throttling device and a dehumidification evaporator; the compressor, the refrigeration evaporator, the dehumidification throttling device and the dehumidification evaporator form a dehumidification circulating flow path; the control valve pipeline system is communicated with the fresh air refrigerating system and the dehumidifying system and is used for controlling the operation or stop of the fresh air refrigerating system and the dehumidifying system; the prior art has the disadvantage that the air cannot be dehumidified circularly.

Disclosure of Invention

The invention aims to provide a northern turbidity monitoring gas path dehumidifying device which can circularly dehumidify air.

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

a northern turbidity monitoring gas circuit dehumidification device comprises a condensation mechanism, a water squeezing support, a squeezing mechanism, a driving gear ring, a dehumidification support, a swing mechanism, a transverse movement mechanism and a filter plate, wherein the dehumidification support comprises a dehumidification barrel, a water inlet pipeline, a water outlet pipeline and a drainage pipeline;

the condensation mechanism comprises two condensation side plates and two condensation pipelines, a plurality of condensation pipelines are fixedly connected between the two condensation side plates, the two condensation side plates are fixedly connected in the water inlet pipeline, the condensation pipelines are located in the condensation section, and the condensation pipelines are communicated with the dehumidification barrel;

the wringing support comprises wringing side plates, wringing pipelines and closed pipelines, two wringing side plates are arranged, a plurality of wringing pipelines are fixedly connected between the two wringing side plates, a plurality of wringing holes I are formed in the wringing pipelines, each wringing pipeline is rotatably connected with a closed pipeline, a plurality of wringing holes II are formed in the closed pipelines, the plurality of wringing holes II are respectively superposed with the plurality of wringing holes I, two driving gear rings are arranged, each driving gear ring is provided with a power mechanism I for driving the driving gear rings to rotate, the power mechanism I is preferably a servo motor, the two driving gear rings are rotatably connected in the dehumidification cylinder, the two driving gear rings are respectively positioned between the two wringing side plates, one driving gear ring is in meshing transmission with the plurality of closed pipelines positioned on the upper side, the other driving gear ring is in meshing transmission with the plurality of closed pipelines positioned on the lower side, the two wringing side plates are fixedly connected in the dehumidification cylinder, the wringing bracket is positioned at the front side of the condensing mechanism, and the drainage pipeline is positioned between the two wringing side plates;

the extrusion mechanism comprises two installation rings, a driving gear, sliding racks, extrusion side plates, extrusion rods and water absorption columns, wherein the two installation rings are respectively and fixedly connected to the front end and the rear end of the inner side of the dehumidification cylinder, the two installation rings are respectively and rotatably connected with the driving gear, the two driving gears are respectively provided with a power mechanism II for driving the two driving gears to rotate, the power mechanism II is preferably a servo motor, the two installation rings are respectively and slidably connected with the two sliding racks, the inner sides of the four sliding racks are respectively and fixedly connected with the extrusion side plates, the inner sides of the four extrusion side plates are respectively and fixedly connected with the extrusion rods, the extrusion rods on the two sides are respectively and fixedly connected with the water absorption columns, the number of the water absorption columns is the same as that of the condensation pipelines, the condensation pipelines and the water absorption pipelines are the same, the plurality of the water absorption columns are respectively and slidably connected in the plurality of water absorption columns, the plurality of water absorption columns are respectively connected in the plurality of condensation pipelines in a sliding manner;

the front end and the rear end of the dehumidification cylinder are fixedly connected with filter plates;

the swinging mechanism comprises a mechanical arm and two mounting rings, the mounting rings are rotatably connected to the mechanical arm, a power mechanism III for driving the mounting rings to rotate is arranged on the mounting rings, the power mechanism III is preferably a servo motor, the two mounting rings are both connected to the dehumidifying barrel in a sliding mode, and a compression spring is fixedly connected between the mounting rings and the dehumidifying barrel;

the transverse moving mechanism comprises a bottom support and transverse moving screw rods, the bottom support is rotatably connected with four transverse moving screw rods, every two of the four transverse moving screw rods are in transmission connection, the two mechanical arms are in sliding connection with the bottom support, and two sides of the two mechanical arms are respectively in threaded connection with the four transverse moving screw rods.

The northern turbidity monitoring gas path dehumidification device has the beneficial effects that:

the invention relates to a northern turbidity monitoring gas circuit dehumidifying device, which can be used for condensing moisture in air by introducing cold water between a condensing mechanism and a dehumidifying cylinder, and is provided with an extruding mechanism and a water squeezing support in order to ensure the drying of the condensing mechanism and the recycling of the device.

Drawings

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

FIG. 1 is a first schematic view of the connection structure of a condensing mechanism, a wringing bracket, a squeezing mechanism and a driving gear ring of the invention;

FIG. 2 is a schematic view of a connection structure of a condensing mechanism, a wringing bracket, a squeezing mechanism and a driving gear ring of the invention;

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

FIG. 4 is a first schematic view of the wringing bracket of the present invention;

FIG. 5 is a schematic view of a wringing bracket according to the present invention;

FIG. 6 is a third schematic view of the wringing bracket of the present invention;

FIG. 7 is a schematic view of the pressing mechanism of the present invention;

FIG. 8 is a schematic view of the dehumidifying rack of the present invention;

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

FIG. 10 is a schematic structural view of the traversing mechanism of the present invention;

FIG. 11 is a schematic view of the overall structure of the northern turbidity monitoring gas path dehumidifier of the present invention;

FIG. 12 is a schematic cross-sectional view of the northern turbidity monitoring gas path dehumidifier of the present invention.

In the figure: a condensing mechanism 20; a condensation side plate 21; a condensing duct 22; a wringing bracket 30; a wringing side plate 31; a wringing conduit 32; closing the duct 33; a pressing mechanism 40; a mounting ring 41; a drive gear 42; a slide rack 43; pressing the side plate 44; a pressing rod 45; a water absorption column 46; the driving ring gear 50; a dehumidifying support 60; a dehumidification cylinder 61; an inlet conduit 62; an outlet conduit 63; a water discharge pipe 64; a condensing section 65; a swing mechanism 70; a robot arm 71; a mounting ring 72; a traversing mechanism 80; a bottom bracket 81; a traversing screw rod 82; a filter plate 90.

Detailed Description

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

The embodiment is described below with reference to fig. 1 to 12, and a north turbidity monitoring gas path dehumidifying apparatus includes a condensing mechanism 20, a water squeezing bracket 30, a squeezing mechanism 40, a driving gear ring 50, a dehumidifying bracket 60, a swing mechanism 70, a traversing mechanism 80 and a filter plate 90, wherein the dehumidifying bracket 60 includes a dehumidifying cylinder 61, a water inlet pipe 62, a water outlet pipe 63 and a water discharge pipe 64, a condensing section 65 is disposed in the middle of the dehumidifying cylinder 61, the water inlet pipe 62 and the water outlet pipe 63 are fixedly connected to the left and right sides of the condensing section 65, the water inlet pipe 62 and the water outlet pipe 63 are both communicated with the dehumidifying cylinder 61, the water inlet pipe 62 is fixedly connected with the water discharge pipe 64, and the water discharge pipe 64 is communicated with the water inlet pipe 62;

the condensation mechanism 20 comprises two condensation side plates 21 and two condensation pipelines 22, the plurality of condensation pipelines 22 are fixedly connected between the two condensation side plates 21, the two condensation side plates 21 are fixedly connected in the water inlet pipeline 62, the plurality of condensation pipelines 22 are positioned in the condensation section 65, and the plurality of condensation pipelines 22 are communicated with the dehumidification barrel 61;

when in use, the front end of the dehumidifying cylinder 61 is connected with an air inlet mechanism, such as a fan, etc., the rear end of the dehumidifying cylinder 61 is connected with an air outlet mechanism, such as a fan, etc., so that air enters from the front end of the dehumidifying cylinder 61, is discharged from the rear end of the dehumidifying cylinder 61, when air enters the dehumidifying cylinder 61, the cold water pipeline is connected to the water inlet pipeline 62 in advance, cold water is introduced into the water inlet pipeline 62, the water inlet pipeline 62 is communicated with the dehumidifying cylinder 61, as shown in fig. 12, the cold water enters between the two condensation side plates 21, the cold water is divided between the two condensation side plates 21, the cold water is at the outer side of the plurality of condensation pipes 22 and the inner side of the condensation section 65, the cold water passes through the plurality of condensation pipes 22 and then is discharged from the water outlet pipe 63, when the air passes through the plurality of condensing pipes 22, moisture in the air is condensed on the inner walls of the plurality of condensing pipes 22, so that the moisture in the air is condensed, and the air is dehumidified;

the wringing bracket 30 comprises wringing side plates 31, wringing pipelines 32 and closed pipelines 33, two wringing side plates 31 are arranged, a plurality of wringing pipelines 32 are fixedly connected between the two wringing side plates 31, a plurality of wringing holes I are arranged on the wringing pipelines 32, each wringing pipeline 32 is rotatably connected with the closed pipeline 33, a plurality of wringing holes II are arranged on the closed pipelines 33, the plurality of wringing holes II are respectively superposed with the plurality of wringing holes I, two driving gear rings 50 are arranged, two power mechanisms I for driving the two driving gear rings 50 to rotate are arranged on the two driving gear rings 50, the power mechanisms I are preferably servo motors, the two driving gear rings 50 are rotatably connected in the dehumidification cylinder 61, the two driving gear rings 50 are respectively positioned between the two wringing side plates 31, one driving gear ring 50 is in meshing transmission with the plurality of closed pipelines 33 positioned on the upper side, the other driving gear ring 50 is in meshing transmission with the plurality of closed pipelines 33 positioned on the lower side, the two wringing side plates 31 are fixedly connected in the dehumidification barrel 61, the wringing bracket 30 is positioned at the front side of the condensation mechanism 20, and the drainage pipeline 64 is positioned between the two wringing side plates 31;

further, in order to ensure that when the water absorbing material 46 in the water squeezing pipeline 32 is squeezed, the water squeezing pipeline 32 without the water absorbing material 46 may have the problem of air leakage of the water squeezing hole i, and further, a closed pipeline 33 is provided, as shown in fig. 4, two driving gear rings 50 are both provided with a power mechanism i for driving the power mechanism i to rotate, the power mechanism i is preferably a servo motor, the power mechanism i is started, an output shaft of the power mechanism i drives the driving gear rings 50 to rotate, when the water absorbing material 46 exists in the three water squeezing pipelines 32 positioned at the upper side, the driving gear rings 50 meshed with the three closed pipelines 33 positioned at the lower side are started, the driving gear rings 50 rotate to drive the three closed pipelines 33 at the lower side to rotate, the three closed pipelines 33 at the lower side rotate, so that the water squeezing hole i and the water squeezing hole ii are dislocated, and further, the three water squeezing pipelines 32 at the lower side are closed, and further, the passing gas can only pass through the condensation pipeline 22, air leakage is avoided, and the treatment efficiency of water in the air is improved;

the extrusion mechanism 40 comprises two installation rings 41, two driving gears 42, sliding racks 43, extrusion side plates 44, extrusion rods 45 and water absorption columns 46, wherein the two installation rings 41 are respectively and fixedly connected to the front end and the rear end of the inner side of the dehumidification barrel 61, the two installation rings 41 are respectively and rotatably connected with the driving gears 42, the two driving gears 42 are respectively and rotatably provided with a power mechanism II for driving the two driving gears to rotate, the power mechanism II is preferably a servo motor, the two installation rings 41 are respectively and slidably connected with the two sliding racks 43, the inner sides of the four sliding racks 43 are respectively and fixedly connected with the extrusion side plates 44, the inner sides of the four extrusion side plates 44 are respectively and fixedly connected with a plurality of extrusion rods 45, the water absorption columns 46 are respectively and fixedly connected between the extrusion rods 45 at the two sides, the number of the water absorption columns 46 is the same as that of the condensation pipelines 22, and the number of the condensation pipelines 22 is the same as that of the water absorption columns 32, the plurality of water squeezing pipelines 32 are respectively communicated with the plurality of condensing pipelines 22, the plurality of water absorption columns 46 are respectively connected in the plurality of water squeezing pipelines 32 in a sliding manner, and the plurality of water absorption columns 46 are respectively connected in the plurality of condensing pipelines 22 in a sliding manner;

when water condensed in the plurality of condensing pipes 22 needs to be treated, further, in order to treat the water condensed inside the plurality of condensing pipes 22 and ensure that the dehumidification barrel 61 cannot be treated timely due to moisture, and further, the humidity inside the dehumidification barrel 61 is relatively high, as shown in fig. 1 and fig. 2, for convenience of illustration, six condensation pipes 22 are provided, six water squeezing pipes 32 are provided, six water absorbing materials 46 are provided, the six condensation pipes 22 are respectively communicated with the six water squeezing pipes 32, two driving gears 42 are respectively provided with a power mechanism ii for driving the two driving gears 42 to rotate, the power mechanism ii is preferably a servo motor and can be fixedly connected to the mounting ring 41, an output shaft of the power mechanism ii is in transmission connection with the driving gears 42, and when the power mechanism ii is started, the output shaft of the power mechanism ii drives the driving gear 42 to rotate, when the driving gear 42 rotates, the corresponding two sliding racks 43 are driven to move, so that the two sliding racks 43 draw on the corresponding mounting rings 41, the two sliding racks 43 on the same mounting ring 41 move forward under the driving of the driving gear 42, and the other sliding rack moves backward, as shown in fig. 7, the driving gears 42 on both sides rotate in the same direction, so that the three water absorbing materials 46 on the upper side move forward at the same time, the three water absorbing materials 46 on the lower side move backward at the same time, the water absorbing materials 46 are preferably materials capable of absorbing moisture, such as sponge, and the like, and when the three water absorbing materials 46 on the upper side pass through the three condensing pipes 22 on the upper side, the three water absorbing materials 46 on the upper side absorb moisture in the three condensing pipes 22 on the upper side, the three water absorbing materials 46 positioned on the upper side enter the three water squeezing pipelines 32, the three water absorbing materials 46 positioned on the lower side pass through the three condensing pipelines 22 positioned on the lower side, the three water absorbing materials 46 positioned on the lower side are not positioned in the three condensing pipelines 22 positioned on the lower side, so that the three condensing pipelines 22 positioned on the lower side can allow air to circulate, the driving gear 42 positioned on the front side is stopped to start, the driving gear 42 positioned on the rear side is continuously started, the driving gear 42 rotates to continuously drive the two corresponding sliding racks 43 to move, the two sliding racks 43 respectively drive the corresponding squeezing rods 45 to move, the three squeezing rods 45 positioned on the upper side continuously move forwards, the three squeezing rods 45 positioned on the lower side continuously move backwards, the three squeezing rods 45 positioned on the upper side squeeze the three water absorbing materials 46 on the upper side, and water in the three water absorbing materials 46 in the water squeezing pipelines 32 is squeezed, the condensed water is discharged through the drain holes I on the water squeezing pipelines 32, further, the three squeezing rods 45 on the lower side move backwards, the three water absorbing materials 46 in the squeezing state are pulled apart, the movement is repeated, the output shaft of the power mechanism II can rotate reversely, so that the three water absorbing materials 46 on the lower side penetrate through the three condensation pipelines 22 condensed on the lower side, the three water absorbing materials are squeezed in the three water squeezing pipelines 32 on the lower side, the three water absorbing materials 46 on the upper side in the squeezing state penetrate through the corresponding three condensation pipelines 22 which are not condensed, the condensed water in the six condensation pipelines 22 can be repeatedly treated after unfolding and moving repeatedly, and the squeezed water is discharged through the drain pipeline 64;

the front end and the rear end of the dehumidification barrel 61 are fixedly connected with a filter plate 90; further, in order to filter the passing air, filter plates 90 are disposed at the front and rear ends of the dehumidifying drum 61, so as to filter the passing air;

the swinging mechanism 70 comprises a mechanical arm 71 and two mounting rings 72, the mounting ring 72 is rotatably connected to the mechanical arm 71, a power mechanism III for driving the mounting ring 72 to rotate is arranged on the mounting ring 72, the power mechanism III is preferably a servo motor, the two swinging mechanisms 70 are arranged, the two mounting rings 72 are both slidably connected to the dehumidifying barrel 61, and a compression spring is fixedly connected between the mounting rings 72 and the dehumidifying barrel 61;

further, in order to increase the range of the dehumidifying support 60 for processing the air, a swing mechanism 70 is provided, as shown in fig. 11, the mechanical arms 71 may be mechanical arms in the prior art, and then the two mechanical arms 71 cooperate to move, so that the dehumidifying support 60 swings in different directions, and the swing mechanism 70 may adjust the height and the swing direction of the dehumidifying support 60, thereby increasing the range of the dehumidifying support 60 for processing the air;

the transverse moving mechanism 80 comprises a bottom bracket 81 and transverse moving screw rods 82, the bottom bracket 81 is rotatably connected with four transverse moving screw rods 82, every two of the four transverse moving screw rods 82 are in transmission connection, the two mechanical arms 71 are both connected onto the bottom bracket 81 in a sliding manner, two sides of the two mechanical arms 71 are respectively connected onto the four transverse moving screw rods 82 through threads, as shown in fig. 10, the transverse moving mechanism 80 is further arranged, and the transverse moving mechanism 80 can adjust the transverse position of the dehumidifying bracket 60; it should be noted that the above embodiments may be spliced with each other or all may be combined together for use.

Claims

1. The utility model provides a north turbidity monitoring gas circuit dehydrating unit, includes dehumidification support (60) and condensation mechanism (20), its characterized in that: the middle part of dehumidification support (60) is provided with condensation segment (65), and condensation mechanism (20) fixed connection is in dehumidification support (60), and condensation mechanism (20) are located condensation segment (65).

2. The northern turbidity monitoring gas path dehumidification device according to claim 1, characterized in that: dehumidification support (60) are including dehumidification section of thick bamboo (61), and condensation segment (65) set up in the middle part of dehumidification section of thick bamboo (61), and the left and right sides of condensation segment (65) is fixedly connected with inlet channel (62) and outlet conduit (63) respectively, fixedly connected with drainage pipe (64) on inlet channel (62).

3. The northern turbidity monitoring gas path dehumidification device according to claim 2, characterized in that: condensation mechanism (20) include two condensation curb plates (21), a plurality of condensing duct (22) of fixedly connected with between two condensation curb plates (21), and a plurality of condensing duct (22) all are located condensation section (65), and the equal fixed connection of two condensation curb plates (21) is in dehumidification section of thick bamboo (61).

4. The northern turbidity monitoring gas path dehumidification device according to claim 3, characterized in that: still include crowded water support (30), crowded water support (30) include two crowded water curb plates (31), a plurality of crowded water pipelines of fixedly connected with (32) between two crowded water curb plates (31), a plurality of crowded water pipelines (32) communicate with a plurality of condensation duct (22) respectively, are provided with a plurality of crowded water holes I on crowded water pipeline (32).

5. The northern turbidity monitoring gas circuit dehumidification device according to claim 4, characterized in that: all rotate on a plurality of crowded water pipeline (32) and be connected with closed pipeline (33), be provided with a plurality of water holes II of squeezing on closed pipeline (33), a plurality of water holes II of squeezing coincide with a plurality of water holes I of squeezing respectively.

6. The northern turbidity monitoring gas path dehumidification device according to claim 5, characterized in that: the dehumidifying drum is characterized by further comprising two driving gear rings (50), the two driving gear rings (50) are connected in the dehumidifying drum (61) in a rotating mode, one driving gear ring (50) is in meshing transmission with the closed pipelines (33) located on the upper side, and the other driving gear ring (50) is in meshing transmission with the closed pipelines (33) located on the lower side.

7. The northern turbidity monitoring gas circuit dehumidification device according to claim 6, characterized in that: still include extrusion mechanism (40), extrusion mechanism (40) are including extrusion stem (45) and water absorption post (46), the equal fixedly connected with extrusion stem (45) of the left and right sides of water absorption post (46), and a plurality of water absorption post (46) are sliding connection respectively in a plurality of water absorption pipeline (32), and a plurality of water absorption post (46) are sliding connection respectively in a plurality of condensation duct (22).

8. The northern turbidity monitoring gas path dehumidification device according to claim 7, characterized in that: both ends are all fixedly connected with filter (90) around dehumidification support (60).

9. The northern turbidity monitoring gas path dehumidification device according to claim 7, characterized in that: the dehumidifying device also comprises a swinging mechanism (70) for adjusting the position of the dehumidifying bracket (60).

10. The northern turbidity monitoring gas circuit dehumidification device according to claim 9, characterized in that: and a transverse moving mechanism (80) for adjusting the transverse position of the swinging mechanism (70).