CN216557916U - Multi-pipeline isolation temperature regulating device - Google Patents

Abstract

The utility model discloses multi-pipeline isolation temperature adjusting equipment, which comprises an air cooler and a transport box, wherein the air cooler is arranged on one side of the transport box, the transport box comprises a first transport chamber and a second transport chamber, a partition plate is arranged between the first transport chamber and the second transport chamber, a first chamber door is arranged between the first transport chamber and the transport box, a second chamber door is arranged between the second transport chamber and the transport box, a sliding assembly is arranged between the partition plate and the transport box, a first air supply assembly is arranged between the air cooler and the first transport chamber, and a second air supply assembly is arranged between the air cooler and the second transport chamber; the temperature in the first transport chamber and the second transport chamber is controlled through the first air supply assembly and the second air supply assembly, so that the temperature of the first transport chamber and the temperature of the second transport chamber are monitored, the first transport chamber and the second transport chamber are always maintained at the required temperature, and the freezing and freshness-keeping effects of the first transport chamber and the second transport chamber are improved.

Description

Multi-pipeline isolation temperature regulating device

Technical Field

The utility model relates to the technical field of vegetable transportation, in particular to a multi-pipeline isolation temperature regulating device.

Background

Vegetables need sell to many places after planting in the plant site, sorts and sells, and vegetables need to carry out the loading and handle usually in the transportation process.

At present, in the existing transportation process, the preservation and the freezing are separated, meanwhile, the temperature monitoring is needed to be carried out on the preservation area and the freezing area, meanwhile, the existing preservation area and the freezing area cannot be rapidly adjusted, so that when the vegetables needing preservation/freezing are too few, the waste of space is easily caused, when the vegetables needing preservation/freezing are too many, a transportation vehicle is needed to be added, and the transportation cost is increased.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide a multi-pipeline isolation temperature regulating device to solve the problems.

In order to achieve the purpose, the utility model provides the following technical scheme: a multi-pipeline isolation temperature adjusting device comprises an air cooler and a transport case, wherein the air cooler is arranged on one side of the transport case, the transport case comprises a first transport room and a second transport room, the first transport room and the second transport room are arranged along the length direction of the transport case, and the first transport chamber is arranged on one side of the transport box close to the air cooler, a partition plate is arranged between the first transport chamber and the second transport chamber, a first door is arranged between the first transport chamber and the transport box, a second door is arranged between the second transport chamber and the transport box, a sliding assembly is arranged between the partition plate and the transport box, a first air supply assembly is arranged between the air cooler and the first transport chamber, the first air supply assembly is used for cooling the first transport chamber, a second air supply assembly is arranged between the air cooler and the second transport chamber, the second air supply assembly is used for cooling the second transport chamber, and the temperature of the first transport chamber is lower than that of the second transport chamber.

Preferably, the sliding assembly comprises a C-shaped groove, rollers and a double-shaft motor, the C-shaped groove is formed in the joint of the two sides of the transport case and the partition plate, the rollers are arranged in the two C-shaped grooves, the double-shaft motor is arranged at the bottom of the partition plate, the two rotating shafts of the double-shaft motor are respectively connected with the rollers on the two sides of the transport case, and sealing sleeves are arranged on the outer side walls of the two rotating shafts of the double-shaft motor.

Preferably, the first air supply assembly comprises a first air supply pipeline, a first temperature control valve and a first temperature sensing controller, one end of the first air supply pipeline is connected with one air outlet of the air cooler, the other end of the first air supply pipeline is communicated with the first transport chamber, the first temperature sensing valve is arranged at the joint of the first air supply pipeline and the first transport chamber, the first temperature sensing controller is arranged in the first transport chamber, and the first temperature sensing controller is electrically connected with the first temperature sensing valve.

Preferably, the junction of first transport chamber and first supply air duct still is provided with first filter screen, and one side that first filter screen deviates from first temperature control valve is provided with the heating net, is provided with the heating switch on the first room door, and the heating switch is connected with the heating net electricity.

Preferably, the second air supply assembly comprises a second air supply pipeline, a second temperature control valve and a second temperature sensing controller, one end of the second air supply pipeline is connected with the other air outlet of the air cooler, the other end of the second air supply pipeline is communicated with the second transport chamber, the second temperature control valve is arranged at the joint of the second air supply pipeline and the second transport chamber, the second temperature sensing controller is arranged in the second transport chamber, and the second temperature sensing controller is electrically connected with the second temperature control valve.

Preferably, a second filter screen is further arranged at the joint of the second transport chamber and the second air supply pipeline.

Preferably, radiator nets are arranged on the front side face and the rear side face of the air cooler.

The utility model has the beneficial technical effects that: the temperature in the first transport chamber and the second transport chamber is controlled through the first air supply assembly and the second air supply assembly, so that the temperature of the first transport chamber and the temperature of the second transport chamber are monitored and maintained at the required temperature all the time, and the freezing and fresh-keeping effects of the first transport chamber and the second transport chamber are improved; the size of the first conveying chamber/the second conveying chamber is changed rapidly, fresh-keeping/frozen vegetables are adjusted according to needs, waste of space is reduced, and meanwhile when the number of the fresh-keeping/frozen vegetables is too large, no conveying vehicle needs to be added, and conveying cost is reduced.

Drawings

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

FIG. 2 is a schematic overall structure of the present invention;

FIG. 3 is a schematic view of the sliding assembly of the present invention;

FIG. 4 is a rear elevational view of the overall construction of the present invention;

fig. 5 is a schematic view of the first blowing duct structure of the present invention.

Reference numerals: 1. an air cooler; 11. a heat-dissipating web; 2. a transport case; 21. a first transport chamber; 211. a first door; 22. a second transport chamber; 221. a second door; 23. a partition plate; 3. a sliding assembly; 31. a C-shaped groove; 32. a roller; 33. a double-shaft motor; 34. sealing sleeves; 4. a first air supply assembly; 41. a first air supply duct; 42. a first temperature control valve; 43. a first temperature sensing controller; 44. a first filter screen; 45. heating the net; 46. a heating switch; 5. a second air supply assembly; 51. a second supply air duct; 52. a second temperature control valve; 53. a second temperature sensing controller; 54. a second filter.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

In this embodiment:

referring to fig. 1-5, a multi-duct isolation temperature adjustment apparatus includes an air cooler 1 and a transport box 2, wherein: the transport case 2 is in a cuboid shape, the air cooler 1 is arranged on the left side of the transport case 2, the air cooler 1 is provided with double air outlets, the front side surface and the back side surface of the air cooler 1 are both provided with radiating nets 11, the double air outlets comprise a first air outlet and a second air outlet, the first air outlet is arranged at the front end of the second air outlet, the transport case 2 comprises a first transport room 21 and a second transport room 22, the first transport room 21 and the second transport room 22 are arranged along the length direction of the transport case 2, the first transport room 21 is arranged on one side of the transport case 2 close to the air cooler 1, the first transport room 21 is arranged on the left side of the second transport room 22, the first transport room 21 is a freezing room, the internal temperature of the first transport room 21 is-10 ℃, the second transport room 22 is a fresh keeping room, the internal temperature of the second transport room 22 is 4 ℃, a first room door 211 is arranged between the first transport room 21 and the transport case 2, and the first room door 211 is hinged with the first transport room 21 through a hinge, a second door 221 is arranged between the second transport chamber 22 and the transport box 2, the second door 221 is hinged with the second transport chamber 22 through a hinge, and the first door 211 and the second door 221 are both provided with door handles.

Be provided with baffle 23 between first transport chamber 21 and the second transport chamber 22, be provided with sliding assembly 3 between baffle 23 and the transport case 2, sliding assembly 3 includes "C" type groove 31, gyro wheel 32, double-shaft motor 33, "C" type groove 31 sets up in the junction of the both sides of transport case 2 and baffle 23, "C" type groove 31 imbeds the bottom of transport case 2, and the length of "C" type groove 31 equals with the length of transport case 2, gyro wheel 32 slidable sets up in the "C" type groove 31 of both sides, double-shaft motor 33 sets up in the bottom of baffle 23, two pivots of double-shaft motor 33 are connected with the gyro wheel 32 of the both sides of transport case 2 respectively, the lateral wall of two pivots of double-shaft motor 33 all is provided with seal cover 34.

A first air supply assembly 4 is arranged between the air cooler 1 and the first transport chamber 21, the first air supply assembly 4 is used for cooling the first transport chamber 21, the first air supply assembly 4 comprises a first air supply pipeline 41, a first temperature control valve 42 and a first temperature sensing controller 43, the first air supply pipeline 41 is in an L shape, one end of the first air supply pipeline 41 is inserted into a first air outlet of the air cooler 1, the other end of the first air supply pipeline 41 is communicated with the back surface of the first transport chamber 21, the first temperature control valve 42 is arranged at the joint of the first air supply pipeline 41 and the first transport chamber 21, the first temperature sensing controller 43 is arranged in the first transport chamber 21, the first temperature sensing controller 43 is electrically connected with the first temperature control valve 42, the first temperature sensing controller 43 is used for detecting the temperature in the first transport chamber 21, when the first temperature sensing controller 43 detects that the temperature in the first transport chamber 21 is higher than-10 ℃, the first temperature sensing controller 43 controls the first temperature control valve 42 to rotate, so that the first air supply pipeline 41 is communicated with the first transport room 21, cold air in the first air supply pipeline 41 enters the first transport room 21 to be cooled until the first temperature sensing controller 43 detects that the temperature in the first transport room 21 is equal to-10 ℃, the first temperature sensing controller 43 controls the first temperature control valve 42 to rotate, so that the first air supply pipeline 41 and the first transport room 21 are sealed, the cold air generated by the air cooler 1 does not enter the first transport room 21, a first filter screen 44 is further arranged at the joint of the first transport room 21 and the first air supply pipeline 41, a heating net 45 is arranged on one side, away from the first temperature control valve 42, of the first filter screen 44, a heating switch 46 is arranged on the first door 211, and the heating switch 46 is electrically connected with the heating net 45.

A second air supply assembly 5 is arranged between the air cooler 1 and the second transport room 22, the second air supply assembly 5 is used for cooling the second transport room 22, the temperature of the first transport room 21 is lower than that of the second transport room 22, the second air supply assembly 5 comprises a second air supply pipeline 51, a second temperature control valve 52 and a second temperature sensing controller 53, one end of the second air supply pipeline 51 is connected with a second air outlet of the air cooler 1, the other end of the second air supply pipeline 51 is communicated with the second transport room 22, the second temperature control valve 52 is arranged at the connection part of the second air supply pipeline 51 and the second transport room 22, the second temperature sensing controller 53 is arranged in the second transport room 22, the second temperature sensing controller 53 is electrically connected with the second temperature control valve 52, the second temperature sensing controller 53 is used for detecting the temperature in the second transport room 22, when the second temperature sensing controller 53 detects that the temperature in the second transport room 22 is higher than 4 ℃, the second temperature sensing controller 53 controls the second thermostatic valve 52 to rotate, so that the second air supply pipeline 51 is communicated with the second transport chamber 22, cold air in the second air supply pipeline 51 enters the second transport chamber 22 to be cooled until the second temperature sensing controller 53 detects that the temperature in the second transport chamber 22 is equal to 4 ℃, the second temperature sensing controller 53 controls the second thermostatic valve 52 to rotate, so that the second air supply pipeline 51 and the second transport chamber 22 are sealed, the cold air generated by the air cooler 1 does not enter the second transport chamber 22, and a second filter screen 54 is further arranged at the joint of the second transport chamber 22 and the second air supply pipeline 51.

When the air cooler is used, when the first transport room 21 and the second transport room 22 need to be cooled, the first temperature sensing controller 43 controls the first temperature control valve 42 to rotate, the first air supply pipeline 41 is communicated with the first transport room 21, cold air in the first air supply pipeline 41 enters the first transport room 21 to be cooled until the first temperature sensing controller 43 detects that the temperature in the first transport room 21 is equal to-10 ℃, the first temperature sensing controller 43 controls the first temperature control valve 42 to rotate, the first air supply pipeline 41 and the first transport room 21 are sealed, cold air generated by the air cooler 1 does not enter the first transport room 21, meanwhile, the second temperature sensing controller 53 controls the second temperature control valve 52 to rotate, the second air supply pipeline 51 is communicated with the second transport room 22, and the cold air in the second air supply pipeline 51 enters the second transport room 22 to be cooled, until the second temperature sensing controller 53 detects that the temperature in the second transport chamber 22 is equal to 4 ℃, the second temperature sensing controller 53 controls the second temperature control valve 52 to rotate, so that the second air supply pipeline 51 and the second transport chamber 22 are sealed, cold air generated by the air cooler 1 does not enter the second transport chamber 22, the temperatures in the first transport chamber 21 and the second transport chamber 22 are controlled through the first air supply assembly 4 and the second air supply assembly 5, the monitoring of the temperatures of the first transport chamber 21 and the second transport chamber 22 is realized, the temperatures of the first transport chamber 21 and the second transport chamber 22 are always maintained at required temperatures, and the freezing and fresh-keeping effects of the first transport chamber 21 and the second transport chamber 22 are improved;

when the size of the first transport chamber 21/the second transport chamber 22 needs to be adjusted, the switch of the double-shaft motor 33 is turned on, so that the double-shaft motor 33 drives the rollers 32 on the two sides to rotate and move along the direction of the C-shaped groove 31, the size of the first transport chamber 21/the second transport chamber 22 is rapidly changed, the fresh-keeping/freezing vegetables are adjusted according to needs, the waste of space is reduced, and meanwhile, when the number of the fresh-keeping/freezing vegetables is too large, no transport vehicle needs to be added, and the transport cost is reduced;

when the junction of first transport chamber 21 and first supply air duct 41 need to be defrosted, press heating switch 46 on first room door 211, make heating network 45 turn into heat energy with the electric energy, and make self generate heat, get rid of condensing at the air outlet department of first filter screen 44 and/or first supply air duct 41, prevent that the ice-cube that condenses from blockking up first supply air duct 41, lead to unable cooling to first transport chamber 21, improve overall structure stability in the operation.

The above is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above-mentioned embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the utility model may occur to those skilled in the art without departing from the principle of the utility model, and are considered to be within the scope of the utility model.

Claims (7)

1. A multi-pipeline isolation temperature regulating device is characterized in that: comprises an air cooler (1) and a transport case (2), wherein the air cooler (1) is arranged on one side of the transport case (2), the transport case (2) comprises a first transport chamber (21) and a second transport chamber (22), the first transport chamber (21) and the second transport chamber (22) are arranged along the length direction of the transport case (2), the first transport chamber (21) is arranged on one side, close to the air cooler (1), of the transport case (2), a partition plate (23) is arranged between the first transport chamber (21) and the second transport chamber (22), a first chamber door (211) is arranged between the first transport chamber (21) and the transport case (2), a second chamber door (221) is arranged between the second transport chamber (22) and the transport case (2), a sliding assembly (3) is arranged between the partition plate (23) and the transport case (2), and a first air supply assembly (4) is arranged between the air cooler (1) and the first transport chamber (21), first air supply subassembly (4) are used for doing the cooling to first transport chamber (21), be provided with second air supply subassembly (5) between air-cooler (1) and second transport chamber (22), second air supply subassembly (5) are used for doing the cooling to second transport chamber (22), the temperature of first transport chamber (21) is less than the temperature of second transport chamber (22).

2. A multi-pipe isolated tempering device according to claim 1 characterized in that: slide subassembly (3) are including "C" type groove (31), gyro wheel (32), double-shaft motor (33), "C" type groove (31) set up in the both sides of transport case (2) and the junction of baffle (23), gyro wheel (32) set up in two in "C" type groove (31), double-shaft motor (33) set up in the bottom of baffle (23), two pivots of double-shaft motor (33) are connected with gyro wheel (32) of the both sides of transport case (2) respectively, the lateral wall of two pivots of double-shaft motor (33) all is provided with seal cover (34).

3. A multi-pipe isolated tempering device according to claim 1 characterized in that: the first air supply assembly (4) comprises a first air supply pipeline (41), a first temperature control valve (42) and a first temperature sensing controller (43), one end of the first air supply pipeline (41) is connected with one air outlet of the air cooler (1), the other end of the first air supply pipeline (41) is communicated with the first transport chamber (21), the first temperature control valve (42) is arranged at the joint of the first air supply pipeline (41) and the first transport chamber (21), the first temperature sensing controller (43) is arranged in the first transport chamber (21), and the first temperature sensing controller (43) is electrically connected with the first temperature control valve (42).

4. A multi-pipe isolated tempering device according to claim 3 wherein: the junction of first transport chamber (21) and first supply air duct (41) still is provided with first filter screen (44), one side that first filter screen (44) deviate from first temperature control valve (42) is provided with heating net (45), be provided with on first room door (211) and heat switch (46), heating switch (46) are connected with heating net (45) electricity.

5. A multi-pipe isolated tempering device according to claim 1 characterized in that: the second air supply assembly (5) comprises a second air supply pipeline (51), a second temperature control valve (52) and a second temperature sensing controller (53), one end of the second air supply pipeline (51) is connected with the other air outlet of the air cooler (1), the other end of the second air supply pipeline (51) is communicated with the second transport chamber (22), the second temperature control valve (52) is arranged at the joint of the second air supply pipeline (51) and the second transport chamber (22), the second temperature sensing controller (53) is arranged in the second transport chamber (22), and the second temperature sensing controller (53) is electrically connected with the second temperature control valve (52).

6. A multi-pipe isolated tempering device according to claim 5 characterized in that: and a second filter screen (54) is also arranged at the joint of the second transport chamber (22) and the second air supply pipeline (51).

7. A multi-pipe isolated tempering device according to claim 1 characterized in that: and heat radiating nets (11) are arranged on the front side face and the rear side face of the air cooler (1).

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