CN219780786U - Unmanned on duty remote monitoring device in pump house - Google Patents

Abstract

The utility model discloses an unmanned remote monitoring device for a pump room, which comprises: a PLC control cabinet, a heat dissipation mechanism and an air cooling mechanism; a movable door is hinged to one side of the PLC control cabinet; the heat dissipation mechanism comprises S-shaped heat conduction vacuum tubes which are uniformly and fixedly embedded in the movable door, and diethyl ether is stored in the S-shaped heat conduction vacuum tubes; according to the unmanned remote monitoring device for the pump room, the heat dissipation mechanism and the air cooling mechanism are arranged on the PLC control cabinet, so that diethyl ether in the S-shaped heat conduction vacuum tube can be gasified along with the increase of the internal temperature of the PLC control cabinet, heat in the PLC control cabinet can be conveyed to the outside, after the motor drives the main shaft and the rotating shaft to rotate, wind power generated in the connecting hopper can conduct primary wind power heat dissipation on the heat in the PLC control cabinet, and wind power generated in the air outlet hopper can conduct blowing heat dissipation treatment on the heat absorbed by the heat conduction fins positioned on the outer side of the movable door; through the arrangement, the heat dissipation effect of the PLC control cabinet is improved.

Description

Unmanned on duty remote monitoring device in pump house

Technical Field

The utility model relates to the technical field of remote monitoring, in particular to an unmanned remote monitoring device for a pump room.

Background

As is well known, the existing unattended pump station generally adopts a PLC control cabinet to collect field device data, and can realize remote setting and modification of parameters after the field device data are transmitted to a central control room; in addition, the PLC control cabinet can also perform remote early warning and alarming functions after data are collected, so that maintenance personnel can overhaul the pump station at the first time conveniently.

Because main parameters in the PLC control cabinet are large, high-frequency oscillation can be caused, the magnetic core and the winding resistor generate heat, and then the problem that the temperature of the PLC control cabinet is overheated frequently occurs when in actual use is solved, the more effective radiating effect is difficult to achieve only through the mode of fan blowing in the prior art, and therefore, the unmanned remote monitoring device for the pump room is provided.

Disclosure of Invention

The utility model aims to provide an unmanned remote monitoring device for a pump room, which has an efficient heat dissipation effect.

The utility model solves the problems by adopting the following technical scheme: an unmanned on duty remote monitoring device of pump house includes: a PLC control cabinet, a heat dissipation mechanism and an air cooling mechanism;

a movable door is hinged to one side of the PLC control cabinet;

the heat dissipation mechanism comprises S-shaped heat conduction vacuum pipes which are uniformly and fixedly embedded in the movable door, diethyl ether is stored in the S-shaped heat conduction vacuum pipes, and heat conduction fins are uniformly and fixedly sleeved on the S-shaped heat conduction vacuum pipes;

the air cooling mechanism comprises a connecting hopper fixedly embedded at the top of the PLC control cabinet, the bottom of the connecting hopper is communicated with the PLC control cabinet, a hollow shell is communicated with the top of the connecting hopper, an air outlet hopper is communicated with one side of the hollow shell, a motor is fixedly arranged at the top of the hollow shell, a spindle is fixedly connected with an output shaft of the motor, a rotating shaft is rotatably connected to the inner side wall of the hollow shell, rotating blades are fixedly connected to the rotating shaft and the spindle, rotating wheels are fixedly sleeved on the rotating shaft and the spindle, and the rotating wheels are rotatably connected through belts.

Through the technical scheme, when the PLC control cabinet operates, the closed movable door can protect the internal elements of the PLC control cabinet; in addition, when the temperature inside the PLC control cabinet exceeds the boiling point of diethyl ether, the heat conducting fins can transfer heat to the S-shaped heat conducting vacuum tube, so that diethyl ether can move upwards inside the S-shaped heat conducting vacuum tube after being gasified, and then the diethyl ether can transfer heat to the outer side of the movable door; after the motor is started, the rotating blades can be driven to rotate through the main shaft to generate wind power, so that the wind power can be blown into the PLC control cabinet from the connecting hopper to perform air cooling and heat dissipation, and the main shaft rotates and simultaneously can rotate the rotating shaft through the rotating wheel and the belt, so that the wind power generated after the rotating blades are driven to rotate by the rotating shaft can blow off heat on the heat conducting fins located outside the movable door.

Preferably, an air inlet hopper is fixedly connected to one side of the hollow shell, and one side of the air inlet hopper is communicated with the hollow shell.

Through the technical scheme, external air can conveniently enter the hollow shell.

Preferably, the bottom of the PLC control cabinet is fixedly connected with a supporting leg.

Through above-mentioned technical scheme, can be convenient for promote the radiating effect of PLC switch board.

Preferably, ventilation grooves which are arranged at equal intervals are uniformly formed in the bottom of the PLC control cabinet.

Through the technical scheme, the motor drives the rotary blade to rotate through the main shaft to generate wind power, and heat in the PLC control cabinet can be primarily blown out of the ventilation groove.

Preferably, a thread groove is formed in one side of the PLC control cabinet, and a positioning bolt is connected with the inner thread of the movable door.

Through the technical scheme, the movable door can be kept stable when being closed by screwing the positioning bolt into the thread groove.

Preferably, a handle is fixedly connected to one side of the movable door.

Through the technical scheme, the movable door can be conveniently closed or opened.

Compared with the prior art, the utility model has the following advantages and effects:

according to the unmanned remote monitoring device for the pump room, the heat dissipation mechanism and the air cooling mechanism are arranged on the PLC control cabinet, so that diethyl ether in the S-shaped heat conduction vacuum tube can be gasified along with the increase of the internal temperature of the PLC control cabinet, heat in the PLC control cabinet can be conveyed to the outside, after the motor drives the main shaft and the rotating shaft to rotate, wind power generated in the connecting hopper can conduct primary wind power heat dissipation on the heat in the PLC control cabinet, and wind power generated in the air outlet hopper can conduct blowing heat dissipation treatment on the heat absorbed by the heat conduction fins positioned on the outer side of the movable door; through the arrangement, the heat dissipation effect of the PLC control cabinet is improved.

Drawings

Fig. 1 is a schematic structural view of an embodiment of the unmanned remote monitoring device for a pump house.

Fig. 2 is a schematic structural view of a movable door and an S-shaped heat conducting vacuum tube of an embodiment of the unmanned remote monitoring device for the pump room.

Fig. 3 is a schematic structural view of a spindle and a spindle of an embodiment of the unmanned remote monitoring device for the pump room.

Fig. 4 is a schematic structural view of an S-shaped heat conducting vacuum tube and heat conducting fin of an embodiment of the unmanned remote monitoring device for the pump room.

Fig. 5 is a schematic structural diagram of an S-shaped heat conducting vacuum tube and diethyl ether of an embodiment of the unmanned remote monitoring device for the pump room.

In the figure: 1. a PLC control cabinet; 10. a movable door; 11. a support leg; 12. a ventilation groove; 13. a thread groove; 14. positioning bolts; 15. a handle; 2. a heat dissipation mechanism; 20. s-shaped heat conducting vacuum tube; 21. a heat conduction fin; 22. diethyl ether; 3. an air cooling mechanism; 30. the connecting hopper; 31. a hollow housing; 32. an air outlet hopper; 33. an air inlet scoop; 34. a main shaft; 35. rotating leaves; 36. a rotating shaft; 37. a rotating wheel; 38. a belt; 39. and a motor.

Detailed Description

The present utility model will be described in further detail by way of examples with reference to the accompanying drawings, which are illustrative of the present utility model and not limited to the following examples.

Referring to fig. 1-5, the present embodiment provides an unmanned remote monitoring device for a pump room, including: an unmanned on duty remote monitoring device of pump house includes: a PLC control cabinet 1, a heat dissipation mechanism 2 and an air cooling mechanism 3;

firstly, in order that the closed movable door 10 can protect the internal elements of the PLC control cabinet 1 when the PLC control cabinet 1 is in operation, one side of the PLC control cabinet 1 is hinged with the movable door 10; in order to enable the diethyl ether 22 to move upward inside the S-shaped heat conductive vacuum tube 20 after gasification by transferring heat to the S-shaped heat conductive vacuum tube 20 when the temperature inside the PLC control cabinet 1 exceeds the boiling point of the diethyl ether 22 by 30-50 deg.c, and enable the diethyl ether 22 to transfer heat to the outside of the movable door 10, and enable the diethyl ether 22 to flow again to the inside of the PLC control cabinet 1 under the action of gravity after liquefaction due to the temperature decrease after the gasified diethyl ether 22 moves to the outside of the PLC control cabinet 1; the heat dissipation mechanism 2 comprises S-shaped heat conduction vacuum pipes 20 which are uniformly and fixedly embedded in the movable door 10, diethyl ether 22 is stored in the S-shaped heat conduction vacuum pipes 20, and heat conduction fins 21 are uniformly and fixedly sleeved on the S-shaped heat conduction vacuum pipes 20; in order to keep the movable door 10 stable when closed by screwing the positioning bolt 14 into the thread groove 13, one side of the PLC control cabinet 1 is provided with the thread groove 13, and the positioning bolt 14 is connected with the inner thread of the movable door 10; in order to be convenient for closing or opening the movable door 10, a handle 15 is fixedly connected to one side of the movable door 10;

secondly, in order to enable the motor 39 to start and then drive the rotary blade 35 to rotate through the main shaft 34 to generate wind power, so that the wind power can be blown into the PLC control cabinet 1 from the connecting hopper 30 to perform air cooling and heat dissipation, and the main shaft 34 can rotate and simultaneously enable the rotary shaft 36 to rotate through the rotary wheel 37 and the belt 38, so that the wind power generated after the rotary shaft 36 drives the rotary blade 35 to rotate can blow off heat on the heat conducting fins 21 positioned on the outer side of the movable door 10; the air cooling mechanism 3 comprises a connecting hopper 30 fixedly embedded at the top of the PLC control cabinet 1, the bottom of the connecting hopper 30 is communicated with the PLC control cabinet 1, the top of the connecting hopper 30 is communicated with a hollow shell 31, one side of the hollow shell 31 is communicated with an air outlet hopper 32, the top of the hollow shell 31 is fixedly provided with a motor 39, an output shaft of the motor 39 is fixedly connected with a main shaft 34, the inner side wall of the hollow shell 31 is rotationally connected with a rotating shaft 36, the rotating shaft 36 and the main shaft 34 are fixedly connected with rotating blades 35, the rotating shaft 36 and the main shaft 34 are fixedly sleeved with rotating wheels 37, and the two rotating wheels 37 are rotationally connected through a belt 38; in order to facilitate external air to enter the hollow shell 31, an air inlet hopper 33 is fixedly connected to one side of the hollow shell 31, and one side of the air inlet hopper 33 is communicated with the hollow shell 31; in order to be convenient for improving the heat dissipation effect of the PLC control cabinet 1, the bottom of the PLC control cabinet 1 is fixedly connected with a supporting leg 11; in order that the motor 39 drives the rotary blades 35 to rotate through the main shaft 34 to generate wind power which can primarily blow out heat in the PLC control cabinet 1 from the ventilation grooves 12, the bottom of the PLC control cabinet 1 is uniformly provided with the ventilation grooves 12 which are arranged at equal intervals;

it should be noted that: the model of the PLC control cabinet 1 is SJ-878SSW.

Working principle: when the temperature in the PLC control cabinet 1 is too high, the motor 39 is started, the motor 39 drives the rotary blade 35 to rotate through the main shaft 34 to generate wind power, and the wind power can be blown into the PLC control cabinet 1 from the connecting hopper 30 to perform air cooling and heat dissipation, so that heat in the PLC control cabinet 1 can be discharged from the ventilation groove 12; in addition, when the temperature inside the PLC control cabinet 1 exceeds the boiling point of the diethyl ether 22, the heat conducting fins 21 can transfer heat to the S-shaped heat conducting vacuum tube 20, so that the diethyl ether 22 can move upwards inside the S-shaped heat conducting vacuum tube 20 after gasification, and further the diethyl ether 22 can transfer heat to the outside of the movable door 10, and when the gasified diethyl ether 22 moves outside the PLC control cabinet 1, due to the temperature decrease, the diethyl ether 22 can flow again to the inside of the PLC control cabinet 1 under the action of gravity along the S-shaped heat conducting vacuum tube 20 after liquefaction; in addition, the main shaft 34 can rotate and simultaneously can rotate the rotating shaft 36 through the rotating wheel 37 and the belt 38, so that the wind power generated after the rotating shaft 36 drives the rotating blade 35 to rotate can blow off the heat on the heat conducting fins 21 positioned on the outer side of the movable door 10.

To sum up: according to the unmanned remote monitoring device for the pump house, the heat dissipation mechanism 2 and the air cooling mechanism 3 are arranged on the PLC control cabinet 1, so that diethyl ether 22 in the S-shaped heat conduction vacuum tube 20 can be gasified along with the increase of the internal temperature of the PLC control cabinet 1, heat in the PLC control cabinet 1 can be conveyed to the outside, after the motor 39 drives the main shaft 34 and the rotating shaft 36 to rotate, wind power generated in the connecting hopper 30 can conduct primary wind power heat dissipation on the heat in the PLC control cabinet 1, and wind power generated in the air outlet hopper 32 can conduct blowing and dissipation treatment on the heat absorbed by the heat conduction fins 21 positioned on the outer side of the movable door 10; through the above setting, the radiating effect of the PLC control cabinet 1 is improved.

The foregoing description of the utility model is merely exemplary of the utility model. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions, without departing from the scope of the utility model as defined in the accompanying claims.

Claims (6)

1. Unmanned on duty remote monitoring device in pump house, its characterized in that includes: a PLC control cabinet (1), a heat dissipation mechanism (2) and an air cooling mechanism (3);

a movable door (10) is hinged to one side of the PLC control cabinet (1);

the heat dissipation mechanism (2) comprises S-shaped heat conduction vacuum pipes (20) which are uniformly and fixedly embedded in the movable door (10), diethyl ether (22) is stored in the S-shaped heat conduction vacuum pipes (20), and heat conduction fins (21) are uniformly and fixedly sleeved on the S-shaped heat conduction vacuum pipes (20);

the utility model provides an air cooling mechanism (3) is including fixedly embedded connection fill (30) at PLC switch board (1) top, the bottom and the PLC switch board (1) intercommunication of connecting fill (30), the top intercommunication of connecting fill (30) has cavity casing (31), one side intercommunication of cavity casing (31) has air-out fill (32), the top fixed mounting of cavity casing (31) has motor (39), the output shaft fixedly connected with main shaft (34) of motor (39), the inside wall rotation of cavity casing (31) is connected with pivot (36), all fixedly connected with swivel vane (35) on pivot (36) and main shaft (34), all fixed cover is equipped with runner (37) on pivot (36) and main shaft (34), two runner (37) pass through belt (38) swivelling joint.

2. The pump house unattended remote monitoring apparatus according to claim 1, wherein: an air inlet hopper (33) is fixedly connected to one side of the hollow shell (31), and one side of the air inlet hopper (33) is communicated with the hollow shell (31).

3. The pump house unattended remote monitoring apparatus according to claim 1, wherein: the bottom of the PLC control cabinet (1) is fixedly connected with a supporting leg (11).

4. The pump house unattended remote monitoring apparatus according to claim 3, wherein: ventilating grooves (12) which are arranged at equal intervals are uniformly formed in the bottom of the PLC control cabinet (1).

5. The pump house unattended remote monitoring apparatus according to claim 4, wherein: a thread groove (13) is formed in one side of the PLC control cabinet (1), and a positioning bolt (14) is connected with the inner thread of the movable door (10).

6. The unmanned remote monitoring device for a pump house of claim 5, wherein: one side of the movable door (10) is fixedly connected with a handle (15).