CN115654469A - Energy-saving temperature control adjusting device - Google Patents

Abstract

The invention relates to the field of industrial temperature control equipment, in particular to an energy-saving temperature control adjusting device. The invention provides an energy-saving temperature control adjusting device, which comprises a temperature control cabin, a two-channel smoke exhaust pipe fitting and the like; the temperature control cabin is connected with the double-channel smoke exhaust pipe fitting. The invention describes an energy-saving temperature control adjusting device, when a single valve component is communicated with an upper channel and an annular pipeline of a double-channel smoke exhaust pipe, smoke is wrapped on the outer surface of a temperature control cabin to preserve heat of steam, and when the single valve component is communicated with a lower channel and the annular pipeline of the double-channel smoke exhaust pipe, the smoke generated in a main cabin body is matched with an air leakage component to carry out rapid cooling treatment on the steam along the lower channel of the double-channel smoke exhaust pipe. The technical problem that the temperature control efficiency of the steam temperature in the boiler is influenced due to the phenomenon that the temperature fluctuation amplitude in the boiler is large because the treatment time is long when the steam in the boiler is cooled is solved.

Description

Energy-saving temperature control adjusting device

Technical Field

The invention relates to the field of industrial temperature control equipment, in particular to an energy-saving temperature control adjusting device.

Background

As an energy conversion device, a boiler can convert chemical energy in fuel into heat energy using high-temperature steam as a carrier, the boiler continuously heats water to generate high-temperature and high-pressure steam during operation, when the temperature of the steam needs to be rapidly reduced, a method of directly cooling the steam by introducing condensed water into the boiler is commonly used, and also in a temperature controller for a high-temperature electric boiler described in patent CN216522435U, a method of controlling a motor by the temperature controller to deflate an air bleeder arranged on the outer wall of the electric boiler is used, so as to flexibly control the temperature and air pressure in the electric boiler.

However, the above-mentioned method of cooling using the introduced condensed water and the method of bleeding air as described in the patented temperature controller for electric boilers have the following problems:

when the method for cooling by using the condensed water is used, the temperature difference between steam and the condensed water in the boiler is too large, the steam in the boiler is rapidly cooled after heat exchange with the condensed water, so that low-temperature steam cooled by the condensed water and high-temperature steam not cooled by the condensed water exist in the boiler at the same time, and a certain time is needed in the mutual energy transfer process of the steam with the two different temperatures, so that the temperature in the boiler can greatly fluctuate, the time length for judging the time length for leading in the condensed water is not facilitated, when the method for cooling by using the air bleeding is used, the high-temperature steam needs to be slowly discharged in order to avoid that the temperature and the air pressure change amplitude in the boiler are too large due to once discharging of too much high-temperature steam, the treatment time is long in both cooling modes, the phenomenon that the temperature fluctuation amplitude in the boiler is large is caused, and the control efficiency of the temperature of the steam in the boiler is influenced.

Disclosure of Invention

The invention provides an energy-saving temperature control adjusting device, aiming at overcoming the defects that the temperature control efficiency of steam in a boiler is influenced due to the phenomenon of large temperature fluctuation amplitude in the boiler caused by long treatment time in two cooling modes of cooling the steam in the boiler by using a condensed water cooling method and cooling the steam in the boiler by using an air bleeding method.

The technical implementation scheme of the invention is as follows: an energy-saving temperature control adjusting device comprises a main cabin body, a heater, a temperature control cabin, an inner container, a double-channel smoke exhaust pipe fitting, an annular pipeline, a single valve assembly and an air leakage assembly; the lower side of the main cabin body is provided with a heater; the upper side of the main cabin body is fixedly connected with a temperature control cabin; the left end of the temperature control cabin is communicated with a water inlet pipe; the left end of the water inlet pipe penetrates through the main cabin body; an inner container is fixedly connected inside the temperature control cabin; the upper surface of the inner container is provided with two air inlets; the middle part of the upper side of the inner container is communicated with an air outlet pipe; the upper end of the air outlet pipe penetrates through the main cabin body and the temperature control cabin; the left side and the right side of the temperature control cabin are respectively connected with a double-channel smoke exhaust pipe fitting; the middle part of the upper side of the inner container is fixedly connected with an annular pipeline; the two double-channel smoke exhaust pipe fittings are respectively connected with the left side and the right side of the annular pipeline; the lower part of the left side and the lower part of the right side of the annular pipeline are respectively communicated with an air duct; the two double-channel smoke exhaust pipe fittings are respectively connected with the two air guide pipes; the rear side of the annular pipeline is communicated with an exhaust pipe; when the single valve component is communicated with the upper channel of the double-channel smoke exhaust pipe component and the annular pipeline, smoke generated in the main cabin body is directly sucked away, and the smoke wraps the outer surface of the temperature control cabin to insulate heat; the rear side of the inner container is connected with an air leakage assembly; the air leakage assemblies are connected with the main cabin body and the temperature control cabin; the left side and the right side of the annular pipeline are respectively connected with a single valve component; the two single valve components are connected with the main cabin body, the temperature control cabin and the inner container; when the single-valve component is communicated with the lower channel and the annular pipeline of the double-channel smoke exhaust pipe, smoke generated in the main cabin body is matched with steam in the temperature control cabin and the inner container through the air leakage component to cool down quickly and stably along the lower channel of the double-channel smoke exhaust pipe.

More preferably, the two-channel smoke exhaust pipe fitting comprises an upper pipeline, a gas collecting pipe, a lower pipeline and a bent pipe;

an upper pipeline is fixedly connected to the upper side of the temperature control cabin; the front side and the rear side of the upper pipeline are respectively communicated with a plurality of gas collecting pipes which are bent downwards; the gas collecting pipes are tightly attached to the outer surface of the temperature control cabin; the lower side of the upper pipeline is communicated with a lower pipeline; the lower pipeline is fixedly connected to the inner top of the temperature control cabin; a bent pipe is communicated between the lower pipeline and the air guide pipe on the same side; the middle part of the elbow passes through the air inlet hole of the inner container and enters the inner container; the upper pipeline is communicated with the annular pipeline.

More preferably, the single valve assembly comprises a motor, a rotating shaft and a three-way ball valve;

the rear side of the main cabin body is fixedly connected with a motor; the output shaft of the motor is fixedly connected with a rotating shaft; the middle part of the rotating shaft is rotatably connected with the main cabin body and the temperature control cabin; the front side of the rotating shaft penetrates through the inner container; the front end of the rotating shaft is fixedly connected with a three-way ball valve; the front side through hole and the rear side through hole of the three-way ball valve are both communicated with the annular pipeline; the through hole at the side part of the three-way ball valve is communicated with the upper pipeline at the same side; the communicating space between the air duct and the annular pipeline is disconnected by the three-way ball valve.

More preferably, the air release assembly comprises a blow-down pipe, a bulb and a first solenoid valve;

an emptying pipe penetrates through the main cabin body, the temperature control cabin and the rear side of the inner container; the front end of the emptying pipe is communicated with a bulb; the left side and the right side of the ball head are respectively provided with an air vent.

More preferably, a plurality of temperature sensors are respectively installed inside and outside the inner container.

More preferably, the lower end of each gas collecting pipe is communicated with a gas nozzle, and the lower end of each gas nozzle is transversely stretched towards the left and right directions.

More preferably, the middle portions of both the bent pipes are provided with non-closed O-shaped structures.

More preferably, the lower ends of the bending parts surrounding the two lower pipelines are respectively fixedly connected with a plurality of drainage sheets; the lower end of each drainage sheet is tightly attached to the outer surface of the inner container.

More preferably, each of the guide pieces is provided in a structure contracting from an upper end to a lower end.

More preferably, the upper sides of the two upper pipelines are respectively communicated with a second electromagnetic valve; the upper pipelines of the two second electromagnetic valves are respectively communicated with an air inlet pipe.

Compared with the prior art, the invention has the following advantages: the invention describes an energy-saving temperature control adjusting device, which is provided with an inner container, a temperature control cabin and a main cabin body which are sequentially sleeved from inside to outside, wherein the left side and the right side of the temperature control cabin are respectively provided with a double-channel smoke exhaust pipe fitting;

when single valve subassembly switch-on binary channels smoke exhaust pipe's upper portion passageway and annular duct, the flue gas that produces in the main cabin body is directly taken away by suction, the flue gas parcel is at the accuse temperature cabin surface this moment, improve the heat preservation effect of the main cabin body to steam, when single valve subassembly switch-on binary channels smoke exhaust pipe's lower part passageway and annular duct, the flue gas that produces in the main cabin body will follow the lower part passageway of binary channels smoke exhaust pipe, the cooperation subassembly that loses heart carries out rapid cooling to steam and handles, because the difference in temperature between steam and the flue gas, be far less than the difference in temperature between steam and the comdenstion water, therefore the cooling range of steam behind steam and the flue gas heat transfer, be less than the cooling range of steam behind steam and the comdenstion water heat transfer, therefore can rapid stabilization after the temperature variation in the boiler appears moving and swings.

Drawings

Fig. 1 is a schematic perspective view illustrating a first embodiment of the present disclosure;

FIG. 2 is a schematic perspective view illustrating a second embodiment of the present application, according to the present disclosure;

FIG. 3 is a cross-sectional view of the main nacelle illustrating the present application, according to an embodiment;

FIG. 4 is a cross-sectional view of a temperature controlled compartment according to the present application, according to an embodiment;

fig. 5 is a schematic diagram illustrating a three-dimensional structure of a temperature control cabin and a two-channel smoke evacuation pipe according to an embodiment of the present application;

FIG. 6 is a cross-sectional view of the liner illustrating the present application, according to an exemplary embodiment;

fig. 7 is a schematic diagram illustrating a partial three-dimensional structure of a dual-channel smoke evacuation pipe and a liner according to an embodiment of the present disclosure;

fig. 8 is a schematic perspective view illustrating a two-channel smoke evacuation tube according to an embodiment of the present application;

fig. 9 is a schematic partial perspective view of a dual-channel smoke evacuation tube according to an embodiment of the present application;

FIG. 10 is a cross-sectional view of an annular duct illustrating the present application according to an embodiment;

fig. 11 is a perspective view illustrating a single valve assembly according to an embodiment of the present application.

The parts are labeled as follows: 1-a main cabin body, 2-a heater, 3-a temperature control cabin, 31-a water inlet pipe, 4-an inner container, 41-an air outlet pipe, 42-a temperature sensor, 51-an upper pipeline, 52-an air collecting pipe, 521-an air faucet, 53-a lower pipeline, 54-an elbow pipe, 55-a drainage sheet, 6-an annular pipeline, 61-an air guide pipe, 62-an air exhaust pipe, 71-a motor, 72-a rotating shaft, 73-a three-way ball valve, 81-an air exhaust pipe, 82-a ball head, 83-a first electromagnetic valve, 9-a second electromagnetic valve and 91-an air inlet pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Examples

An energy-saving temperature control adjusting device is shown in figures 1-11 and comprises a main cabin body 1, a heater 2, a temperature control cabin 3, an inner container 4, a double-channel smoke exhaust pipe fitting, an annular pipeline 6, a single valve component and an air leakage component; a heater 2 is arranged at the lower side of the main cabin body 1; the upper side of the main cabin body 1 is connected with a temperature control cabin 3 through bolts; the left end of the temperature control cabin 3 is communicated with a water inlet pipe 31; the left end of the water inlet pipe 31 penetrates through the main cabin body 1; an inner container 4 is fixedly connected inside the temperature control cabin 3; the upper surface of the inner container 4 is provided with two air inlets; the middle part of the upper side of the inner container 4 is communicated with an air outlet pipe 41; a plurality of temperature sensors 42 are respectively arranged inside and outside the inner container 4; the upper end of the air outlet pipe 41 penetrates through the main cabin body 1 and the temperature control cabin 3; the left side and the right side of the temperature control cabin 3 are respectively connected with a double-channel smoke exhaust pipe fitting; the middle part of the upper side of the inner container 4 is fixedly connected with an annular pipeline 6; the two double-channel smoke exhaust pipe fittings are respectively connected with the left side and the right side of the annular pipeline 6; the lower part of the left side and the lower part of the right side of the annular pipeline 6 are respectively communicated with an air duct 61; the two double-channel smoke exhaust pipe fittings are respectively connected with the two air guide pipes 61; the rear side of the annular pipeline 6 is communicated with an exhaust pipe 62; the left side and the right side of the annular pipeline 6 are respectively connected with a single valve component; the two single valve components are connected with the main cabin body 1, the temperature control cabin 3 and the inner container 4.

As shown in fig. 5-9, the two-channel smoke exhaust pipe includes an upper pipe 51, a gas collecting pipe 52, a lower pipe 53, a bent pipe 54 and a flow guiding plate 55; an upper pipeline 51 is fixedly connected to the upper side of the temperature control cabin 3; the front side and the rear side of the upper pipeline 51 are respectively communicated with a plurality of downwards bent gas collecting pipes 52; the gas collecting pipes 52 are tightly attached to the outer surface of the temperature control cabin 3; the lower end of each air collecting pipe 52 is communicated with an air nozzle 521, and the lower end of each air nozzle 521 stretches transversely in the left-right direction; a lower duct 53 is connected to the lower side of the upper duct 51; the lower pipeline 53 is fixedly connected with the inner top of the temperature control cabin 3; a bent pipe 54 is communicated between the lower pipeline 53 and the gas-guide pipe 61 on the same side; the middle part of the elbow pipe 54 passes through the air inlet hole of the inner container 4 and enters the inner container 4; the middle part of the elbow 54 is provided with a non-closed O-shaped structure; the upper pipe 51 is communicated with the annular pipe 6; a plurality of drainage sheets 55 are fixedly connected to the lower end of the bending part surrounding the lower pipeline 53; the lower end of each drainage sheet 55 is tightly attached to the outer surface of the inner container 4; each of the drainage tabs 55 is provided in a structure that is contracted from the upper end to the lower end.

As shown in fig. 10 and 11, the single valve assembly includes a motor 71, a rotary shaft 72 and a three-way ball valve 73; the rear bolt of the main cabin body 1 is connected with a motor 71; a rotating shaft 72 is fixedly connected with an output shaft of the motor 71; the middle part of the rotating shaft 72 is rotatably connected with the main cabin body 1 and the temperature control cabin 3; the front side of the rotating shaft 72 penetrates through the inner container 4; the front end of the rotating shaft 72 is fixedly connected with a three-way ball valve 73; the front through hole and the rear through hole of the three-way ball valve 73 are both communicated with the annular pipeline 6; the through hole at the side part of the three-way ball valve 73 is communicated with the upper pipeline 51 at the same side; the communication space between the air duct 61 and the annular duct 6 is interrupted by a three-way ball valve 73.

As shown in fig. 6 and 7, the air release assembly comprises a vent pipe 81, a ball head 82 and a first solenoid valve 83; an emptying pipe 81 penetrates through the main cabin body 1, the temperature control cabin 3 and the rear side of the inner container 4; the front end of the emptying pipe 81 is communicated with a bulb 82; the left side and the right side of the ball head 82 are respectively provided with a vent hole.

The upper sides of the two upper pipelines 51 are respectively communicated with a second electromagnetic valve 9; the upper ducts 51 of the two second solenoid valves 9 are each connected to an air inlet duct 91.

The steam heating working steps of the energy-saving temperature control adjusting device are as follows:

before using this energy-conserving accuse temperature adjusting device, need be with the external water supply equipment of inlet tube 31, with the external steam collecting device of outlet duct 41, with the external flue gas suction equipment of blast pipe 62, with the external blast apparatus of two air-supply lines 91, pour into water in to accuse temperature cabin 3 by external water supply equipment through inlet tube 31, the heater 2 uses is the flame sprayer, the water of 2 blowout high temperature flames of heater in to accuse temperature cabin 3 heats, let the water evaporation in accuse temperature cabin 3 become steam, steam upwards gathers and gets into in inner bag 4 through the inlet port, discharge to external steam collecting device from outlet duct 41 again, carry out steam heating work, temperature sensor 42 carries out temperature monitoring to the steam inside and outside inner bag 4 simultaneously.

In the process of spraying high-temperature flame by the heater 2, a large amount of smoke is generated along with the combustion of the flame, the external smoke suction equipment sucks the smoke to the exhaust pipe 62, the smoke is captured by the air nozzle 521 and enters the gas collecting pipe 52 during the rising of the smoke, the smoke sequentially enters the annular pipeline 6 along the gas collecting pipe 52, the upper pipeline 51 and the three-way ball valve 73, and finally the smoke is sucked away from the exhaust pipe 62 by the external smoke suction equipment, in the process, the high-temperature flame sprayed by the heater 2 only heats the bottom of the temperature control cabin 3, the upper part of the temperature control cabin 3 is insulated by the smoke flowing in the gas collecting pipe 52, the smoke contains a large amount of heat and is attached to the upper surface of the temperature control cabin 3, and the insulation effect of the temperature control cabin 3 on the steam inside the smoke is improved.

The steam cooling working steps of the energy-saving temperature control adjusting device are as follows:

when the steam in the temperature control cabin 3 needs to be rapidly cooled, the output shaft of the motor 71 drives the rotating shaft 72 to rotate, the rotating shaft 72 drives the three-way ball valve 73 to rotate ninety degrees, a side through hole of the three-way ball valve 73 communicates the annular pipeline 6 with the air duct 61, and a communication space between the upper pipeline 51 and the annular pipeline 6 is disconnected by the three-way ball valve 73, so that the flue gas enters the upper pipeline 51, then flows through the lower pipeline 53 and the elbow 54 in a diversion manner, finally enters the annular pipeline 6 from the air duct 61, and is sucked away by external flue gas suction equipment.

In the process of flowing through the lower pipeline 53 and the elbow 54, when steam in the temperature control cabin 3 and the inner container 4 contacts the pipe walls of the lower pipeline 53 and the elbow 54, the steam and the flue gas in the lower pipeline 53 and the elbow 54 are subjected to heat exchange treatment, the temperature difference between the steam and the flue gas is far smaller than the temperature difference between the steam and condensed water, so that the cooling amplitude of the steam after the steam and the flue gas exchange is smaller than the cooling amplitude of the steam after the steam and the condensed water exchange, the steam is cooled and cooled in the process, the temperature change of the steam inside and outside the inner container 4 can be quickly and stably stabilized after the steam fluctuates, and the control efficiency of the steam temperature is improved.

During steam and flue gas heat transfer, first solenoid valve 83 is opened, lets blow-down pipe 81 and outside air intercommunication, and in the partial steam in the inner bag 4 passed through the left and right sides through-hole entering blow-down pipe 81 of bulb 82, the slow outside evacuation through first solenoid valve 83 of steam that gets into in the blow-down pipe 81 further accelerated the speed of cooling steam.

If the steam temperature in the inner bag 4 exceeds normal temperature, when needing to promptly cool down the steam in the inner bag 4 and handle, second solenoid valve 9 is opened, let upper portion pipeline 51 and external blast apparatus be linked together, external blast apparatus blows low-temperature air in the pipeline 51 of upper portion through second solenoid valve 9, after low-temperature air mixes with the flue gas in the pipeline 51 of upper portion, effectively reduce the temperature of flue gas, improve the difference in temperature of flue gas and steam, thereby improve the heat exchange efficiency of flue gas and steam, realize accelerating the cooling treatment work to steam.

In the process that steam in the temperature control cabin 3 enters the inner container 4 through the air inlet hole, part of the steam is intercepted by the drainage sheet 55, and moisture contained in the steam is also intercepted by the drainage sheet 55, so that the moisture contained in the steam flows to the outer surface of the inner container 4 along the drainage sheet 55, and the phenomenon that water enters the inner container 4 is reduced.

While the disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the disclosure as defined by the appended claims and their equivalents. Accordingly, the scope of the present disclosure should not be limited to the above-described embodiments, but should be defined not only by the appended claims, but also by equivalents thereof.

Claims (10)

1. An energy-saving temperature control adjusting device comprises:

the device comprises a main cabin body (1), a heater (2), a temperature control cabin (3) and an inner container (4); a heater (2) is arranged on the lower side of the main cabin body (1); the upper side of the main cabin body (1) is fixedly connected with a temperature control cabin (3); the left end of the temperature control cabin (3) is communicated with a water inlet pipe (31); an inner container (4) is fixedly connected inside the temperature control cabin (3); the upper surface of the inner container (4) is provided with two air inlets; the middle part of the upper side of the inner container (4) is communicated with an air outlet pipe (41); the upper end of the air outlet pipe (41) penetrates through the main cabin body (1) and the temperature control cabin (3);

the method is characterized in that: the device also comprises a double-channel smoke exhaust pipe fitting, an annular pipeline (6), a single valve component and an air leakage component; the left end of the water inlet pipe (31) penetrates through the main cabin body (1); the left side and the right side of the temperature control cabin (3) are respectively connected with a double-channel smoke exhaust pipe fitting; the middle part of the upper side of the inner container (4) is fixedly connected with an annular pipeline (6); the two double-channel smoke exhaust pipe fittings are respectively connected with the left side and the right side of the annular pipeline (6); the lower part of the left side and the lower part of the right side of the annular pipeline (6) are communicated with an air duct (61); the two double-channel smoke exhaust pipe fittings are respectively connected with two air guide pipes (61); an exhaust pipe (62) is communicated with the rear side of the annular pipeline (6); when the single-valve assembly is communicated with the upper channel of the double-channel smoke exhaust pipe fitting and the annular pipeline (6), smoke generated in the main cabin body (1) is directly sucked away, and the smoke wraps the outer surface of the temperature control cabin (3) and keeps warm; the rear side of the inner container (4) is connected with an air leakage assembly; the air leakage assemblies are connected with the main cabin body (1) and the temperature control cabin (3); the left side and the right side of the annular pipeline (6) are respectively connected with a single valve component; the two single valve components are connected with the main cabin body (1), the temperature control cabin (3) and the inner container (4); when the single-valve assembly is communicated with the lower channel of the double-channel smoke exhaust pipe fitting and the annular pipeline (6), smoke generated in the main cabin body (1) can be rapidly and stably cooled by matching the steam in the temperature control cabin (3) and the inner container (4) along the lower channel of the double-channel smoke exhaust pipe fitting.

2. An energy-saving temperature-control regulating device according to claim 1, characterized in that: the double-channel smoke exhaust pipe fitting comprises an upper pipeline (51), a gas collecting pipe (52), a lower pipeline (53) and a bent pipe (54);

an upper pipeline (51) is fixedly connected to the upper side of the temperature control cabin (3); the front side and the rear side of the upper pipeline (51) are respectively communicated with a plurality of downward bent gas collecting pipes (52); the gas collecting pipes (52) are tightly attached to the outer surface of the temperature control cabin (3); a lower pipeline (53) is communicated with the lower side of the upper pipeline (51); the lower pipeline (53) is fixedly connected with the inner top of the temperature control cabin (3); a bent pipe (54) is communicated between the lower pipeline (53) and the air guide pipe (61) on the same side; the middle part of the elbow (54) penetrates through the air inlet hole of the inner container (4) and enters the inner container (4); the upper pipe (51) is communicated with the annular pipe (6).

3. An energy-saving temperature-control regulating device according to claim 2, characterized in that: the single-valve component comprises a motor (71), a rotating shaft (72) and a three-way ball valve (73);

a motor (71) is fixedly connected to the rear side of the main cabin body (1); an output shaft of the motor (71) is fixedly connected with a rotating shaft (72); the middle part of the rotating shaft (72) is rotatably connected with the main cabin body (1) and the temperature control cabin (3); the front side of the rotating shaft (72) penetrates through the inner container (4); the front end of the rotating shaft (72) is fixedly connected with a three-way ball valve (73); the front side through hole and the rear side through hole of the three-way ball valve (73) are both communicated with the annular pipeline (6); the through hole at the side part of the three-way ball valve (73) is communicated with the upper pipeline (51) at the same side; the communicating space between the air duct (61) and the annular pipeline (6) is disconnected by a three-way ball valve (73).

4. An energy-saving temperature-control regulating device according to claim 1, characterized in that: the air leakage assembly comprises an emptying pipe (81), a ball head (82) and a first electromagnetic valve (83);

an emptying pipe (81) penetrates through the rear sides of the main cabin body (1), the temperature control cabin (3) and the inner container (4); the front end of the emptying pipe (81) is communicated with a bulb (82); the left side and the right side of the bulb (82) are respectively provided with a vent hole.

5. An energy-saving temperature-controlling and regulating device according to claim 1, wherein: a plurality of temperature sensors (42) are respectively arranged inside and outside the inner container (4).

6. An energy-saving temperature-controlling and regulating device according to claim 2, wherein: the lower end of each gas collecting pipe (52) is communicated with a gas nozzle (521), and the lower end of each gas nozzle (521) stretches transversely towards the left and right direction.

7. An energy-saving temperature-control regulating device according to claim 2, characterized in that: the middle parts of the two bent pipes (54) are both provided with non-closed O-shaped structures.

8. An energy-saving temperature-control regulating device according to claim 2, characterized in that: a plurality of drainage sheets (55) are fixedly connected to the lower ends of the bending parts surrounding the two lower pipelines (53); the lower end of each drainage sheet (55) is tightly attached to the outer surface of the inner container (4).

9. An energy-saving temperature-control regulating device according to claim 2, characterized in that: each of the drainage pieces (55) is provided in a structure that is contracted from an upper end to a lower end.

10. An energy-saving temperature-control regulating device according to claim 2, characterized in that: the upper sides of the two upper pipelines (51) are respectively communicated with a second electromagnetic valve (9); the upper pipelines (51) of the two second electromagnetic valves (9) are respectively communicated with an air inlet pipe (91).

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