CN217274408U - Medium-deep geothermal energy heating standard simulation device - Google Patents
Medium-deep geothermal energy heating standard simulation device Download PDFInfo
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- CN217274408U CN217274408U CN202220279637.9U CN202220279637U CN217274408U CN 217274408 U CN217274408 U CN 217274408U CN 202220279637 U CN202220279637 U CN 202220279637U CN 217274408 U CN217274408 U CN 217274408U
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/10—Geothermal energy
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Abstract
The utility model relates to a middle and deep geothermal energy technical field just discloses a middle and deep geothermal energy heating standard analogue means, including simulation geothermal layer, the inside detection device that is provided with of simulation geothermal layer, simulation geothermal layer left side is provided with reflux unit, detection device includes fixed connection at the inside left inlet tube of simulation geothermal layer, the inside right side fixed connection right outlet pipe of simulation geothermal layer, the first temperature controller of simulation geothermal layer top fixed connection, simulation geothermal layer right side fixedly connected with seal shell, the inside third temperature sensor that is provided with of seal shell, the outside positive fixedly connected with second temperature controller of seal shell. This well deep geothermal energy heating standard analogue means carries out temperature detection to simulation geothermal layer through detection device, and the rethread reflux unit carries out the water backward flow, accomplishes the operation of temperature detection and the recovery rivers of well deep geothermal energy heating.
Description
Technical Field
The utility model relates to a middle and deep geothermal energy technical field specifically is a middle and deep geothermal energy standard analogue means that heats.
Background
The deep geothermal resource is a three-in-one resource of heat, mine and water, is also a clean environment-friendly energy source, and can be widely applied to the fields of power generation, heat supply and heating, medical care, hot spring bathing, planting and breeding, tourism, real estate development and the like. Geothermal resources are renewable resources, can be comprehensively recycled, have the characteristics of no pollution, convenient development and utilization (direct utilization), high development value and the like, have important significance for improving urban grade, urban environment, energy structure adjustment and improving living conditions of people, and can obtain remarkable economic benefit, social benefit and environmental benefit.
The middle-deep geothermal energy heating device in the existing market is not convenient for detecting temperature data when in use, so that the heating device heating standard is not enough, and the heating efficiency is reduced.
SUMMERY OF THE UTILITY MODEL
Technical problem to be solved
Not enough to prior art, the utility model provides a well deep geothermal energy heating standard analogue means possesses the advantage that detects the temperature, has solved the detection temperature data of being not convenient for that mentions in the above-mentioned background art, leads to heating system heating standard not enough, reduces the heating efficiency problem.
(II) technical scheme
In order to achieve the above purpose, the utility model provides a following technical scheme: a middle-deep geothermal energy heating standard simulation device comprises a simulation geothermal layer, wherein a detection device is arranged in the simulation geothermal layer, and a reflux device is arranged on the right side of the simulation geothermal layer;
when the staff need simulate, carry out the temperature through detection device centering deep geothermal energy this moment and detect, rethread reflux unit carries out the water backward flow, accomplishes the temperature detection of centering deep geothermal energy heating and the operation of retrieving rivers.
The heat taking device comprises a water inlet pipe fixedly connected to the left side inside the simulated geothermal layer, the right side inside the simulated geothermal layer is fixedly connected with a right water outlet pipe, a first temperature sensor is fixedly connected inside the water inlet pipe, a second temperature sensor is fixedly connected inside the water outlet pipe, the top of the simulated geothermal layer is fixedly connected with a first temperature controller, the right side of the simulated geothermal layer is fixedly connected with a sealing shell, a third temperature sensor is arranged inside the sealing shell, and the front side outside the sealing shell is fixedly connected with a second temperature controller;
when the staff need simulate and examine time measuring, this moment through opening the motor and drive the heater and heat the inlet tube, the first temperature sensor of rethread detects the temperature, the temperature is looked over to the rethread temperature controller, after up to standard, rethread outlet pipe discharge heat energy, rethread second temperature sensor detects exhaust temperature, detect the heat energy of dissipation, the further heating of rethread heat exchanger, keep warm to the heating pipe through the heat preservation this moment, and then convey heat energy in the sealing shell through the heating pipe again, detect through third temperature sensor this moment, the rethread second temperature controller is looked over the temperature and is contrasted the heat energy of dissipation, accomplish the temperature detection of the heating of the deep geothermal energy of centering, reach the effect of accurate detection temperature.
Preferably, the water inlet pipe is fixedly connected with a water delivery pipe on the left side, and the top of the water outlet pipe is fixedly connected with a heat exchanger.
In the above scheme, in carrying rivers into the water pipe through the raceway, the rethread heat exchanger is to the water heating in the outlet pipe, prevents that the water process can dispel the heat.
Preferably, the water pipe is fixedly connected with a water tank on the left side, and a water suction pump is fixedly connected inside the water tank.
In the above scheme, the water in the water tank can be pumped and conveyed to the water inlet pipe by the water pump.
Preferably, the simulated geothermal layer is internally and fixedly connected with a heater, and the left side of the heater is fixedly connected with a motor.
Preferably, the right side of the heat exchanger is fixedly connected with a heating pipe, and a heat preservation layer is fixedly connected inside the heating pipe.
Preferably, the backflow device comprises a drain pipe fixedly connected to the left side of the water outlet pipe, and a valve is fixedly connected to the left side of the drain pipe.
Preferably, the bottom of the simulated geothermal layer is fixedly connected with a base, and the bottom of the base is fixedly connected with a universal wheel.
Compared with the prior art, the utility model provides a well deep geothermal energy standard analogue means that heats possesses following beneficial effect:
1. the middle-deep geothermal energy heating standard simulation device is provided with a first temperature sensor, a second temperature sensor, a third temperature sensor and the like which are matched with each other, and particularly comprises a step of driving a heater to heat a water inlet pipe by turning on a motor when simulation detection is needed, a step of detecting the temperature by the first temperature sensor, a step of checking the temperature by a temperature controller, a step of discharging heat energy by a water outlet pipe when the simulation detection is up to standard, a step of detecting the discharged temperature by the second temperature sensor, a step of detecting dissipated heat energy, a step of further heating by a heat exchanger, a step of detecting the heated temperature by the fourth temperature sensor, a step of preserving the heat of a heating pipe by a heat preservation layer, a step of transmitting the heat energy into a sealed shell by the heating pipe, a step of detecting by the third temperature sensor, and a step of checking the temperature by the second temperature sensor for contrasting the dissipated heat energy, the temperature detection of the heating of the middle and deep geothermal energy is completed, and the problems that the heating standard of a heating device is not enough and the heating efficiency is reduced due to the fact that the temperature data is not convenient to detect in the background technology are solved.
2. This well deep geothermal energy heating standard analogue means mutually supports through being provided with devices such as water tank, drain pipe and valve, specifically for having detected the back at the temperature, through opening the valve, with rivers from the drain pipe discharge, in the rethread drain pipe discharges rivers to the water tank, accomplishes the operation of retrieving rivers, reaches the effect of avoiding extravagant.
Drawings
FIG. 1 is a schematic view of the present invention;
FIG. 2 is a schematic view of the inner layer of the present invention;
FIG. 3 is a schematic view of the structure of the detecting device of the present invention;
fig. 4 is a schematic structural view of the reflow apparatus of the present invention.
Wherein: 1. simulating a geothermal layer; 2. a detection device; 3. a reflux device; 4. a water tank; 5. a heater; 6. a heating pipe; 7. a drain pipe; 11. a base; 12. a universal wheel; 21. a water inlet pipe; 22. a water outlet pipe; 23. a first temperature sensor; 24. a second temperature sensor; 25. a first temperature controller; 26. sealing the housing; 27. a third temperature sensor; 28. a second temperature controller; 201. a water delivery pipe; 202. a heat exchanger; 41. a water pump; 51. a motor; 61. a heat-insulating layer; 71. and (4) a valve.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1-4, a middle-deep geothermal energy heating standard simulator comprises a simulated geothermal layer 1, a detection device 2 arranged inside the simulated geothermal layer 1, and a reflux device 3 arranged on the right side of the simulated geothermal layer 1;
when the staff need simulate, carry out temperature detection to simulation geothermal layer 1 through detection device 2 this moment, the rethread reflux unit 3 carries out the water backward flow, accomplishes the operation of temperature detection and the recovery rivers of well deep geothermal energy heating.
The detection device 2 comprises a water inlet pipe 21 fixedly connected to the left side inside the simulated geothermal layer 1, a right water outlet pipe 22 fixedly connected to the right side inside the simulated geothermal layer 1, a first temperature sensor 23 fixedly connected to the inside of the water inlet pipe 21, a second temperature sensor 24 fixedly connected to the inside of the water outlet pipe 22, a first temperature controller 25 fixedly connected to the top of the simulated geothermal layer 1, a sealing shell 26 fixedly connected to the right side of the simulated geothermal layer 1, a third temperature sensor 27 arranged inside the sealing shell 26, and a second temperature controller 28 fixedly connected to the front side of the outside of the sealing shell 26;
when the staff need carry out the simulation and examine time measuring, drive heater 5 through opening motor 51 this moment and heat inlet tube 21, rethread first temperature sensor 23 detects the temperature, the temperature is looked over to rethread first temperature controller 25, after up to standard, rethread outlet pipe 22 heat energy, rethread second temperature sensor 24 detects the temperature of discharge, detect the heat energy of dissipation, rethread heat exchanger 202 further heats, keep warm to heating pipe 6 through heat preservation 61 this moment, and then rethread heating pipe 6 conveys heat energy in seal shell 26, detect through third temperature sensor 27 this moment, rethread second temperature controller 28 looks over the heat energy that the temperature contrasts the dissipation, accomplish the temperature detection of the heating of centering deep geothermal energy, reach the effect of accurate detection temperature.
Specifically, the left side of the water inlet pipe 21 is fixedly connected with a water pipe 201, and the top of the water outlet pipe 22 is fixedly connected with a heat exchanger 202.
Through the technical scheme, water flow is conveyed into the water inlet pipe 21 through the water conveying pipe 201, and then the water in the water outlet pipe 22 is heated through the heat exchanger 202, so that heat dissipation in the water outlet process is prevented.
Specifically, the water pipe 201 is fixedly connected with the water tank 4 on the left side, and the water pump 41 is fixedly connected inside the water tank 4.
Through the technical scheme, the water in the water tank 4 can be pumped and conveyed into the water inlet pipe 21 by arranging the water suction pump 41.
Specifically, the heater 5 is fixedly connected inside the simulated geothermal layer 1, and the motor 51 is fixedly connected to the left side of the heater 5.
Through the technical scheme, the heater 5 can be driven to heat by the motor 51, and the temperature of the geothermal energy in the middle and deep layers can be simulated.
Specifically, the right side of the heat exchanger 202 is fixedly connected with a heating pipe 6, and the inside of the heating pipe 6 is fixedly connected with a heat preservation layer 61.
Through above-mentioned technical scheme, through being provided with heating pipe 6, can carry heat energy through heating pipe 6, the rethread heat preservation 61 prevents that heat energy dissipates too fast.
Specifically, the backflow device 3 includes a water discharge pipe 7 fixedly connected to the left side of the water outlet pipe 22, and a valve 71 is fixedly connected to the left side of the water discharge pipe 7.
Through the technical scheme, the water flow can be recovered after simulation through the water discharge pipe 7, and the time for recovering the water flow can be freely controlled through the valve 71.
Specifically, the bottom of the simulated geothermal layer 1 is fixedly connected with a base 11, and the bottom of the base 11 is fixedly connected with a universal wheel 12.
Through the technical scheme, the simulated geothermal layer 1 is stable through the base 11, and the simulated geothermal layer 1 can be moved through the universal wheels 12.
When the device is used, the temperature of the simulated geothermal layer 1 is detected through the detection device 2, and then water backflow is carried out through the backflow device 3, so that the temperature detection of the heating of the geothermal energy of the middle and deep layers and the operation of water flow recovery are completed.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (7)
1. The utility model provides a middle-deep geothermal energy heating standard analogue means, includes simulation geothermal layer (1), its characterized in that: a detection device (2) is arranged in the simulated geothermal layer (1), and a reflux device (3) is arranged on the left side of the simulated geothermal layer (1);
detection device (2) are including fixed connection at inside left inlet tube (21) of simulation geothermal floor (1), inside right side fixed connection right outlet pipe (22) of simulation geothermal floor (1), the first temperature sensor (23) of the inside fixedly connected with of inlet tube (21), the inside fixedly connected with second temperature sensor (24) of outlet pipe (22), the first temperature controller (25) of simulation geothermal floor (1) top fixed connection, simulation geothermal floor (1) right side fixedly connected with seal housing (26), the inside third temperature sensor (27) that is provided with of seal housing (26), the outside positive fixedly connected with second temperature controller (28) of seal housing (26).
2. A mid-deep geothermal energy heating specification simulation device according to claim 1, wherein: the water inlet pipe (21) is fixedly connected with a water delivery pipe (201) on the left side, and the heat exchanger (202) is fixedly connected with the top of the water outlet pipe (22).
3. A mid-deep geothermal energy heating specification simulation device according to claim 2, wherein: the water delivery pipe (201) is characterized in that a water tank (4) is fixedly connected to the left side of the water delivery pipe, and a water suction pump (41) is fixedly connected to the inner portion of the water tank (4).
4. A mid-deep geothermal energy heating specification simulation device according to claim 1, wherein: the simulated geothermal layer (1) is internally and fixedly connected with a heater (5), and the left side of the heater (5) is fixedly connected with a motor (51).
5. A mid-deep geothermal energy heating specification simulation device according to claim 2, wherein: the heat exchanger (202) right side fixedly connected with heating pipe (6), heating pipe (6) inside fixedly connected with heat preservation (61).
6. A mid-deep geothermal energy heating specification simulation device according to claim 1, wherein: reflux unit (3) include outlet pipe (22) left side fixed connection's drain pipe (7), drain pipe (7) left side fixedly connected with valve (71).
7. A mid-deep geothermal energy heating specification simulation device according to claim 1, wherein: the bottom of the simulated geothermal layer (1) is fixedly connected with a base (11), and the bottom of the base (11) is fixedly connected with a universal wheel (12).
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CN202220279637.9U CN217274408U (en) | 2022-02-11 | 2022-02-11 | Medium-deep geothermal energy heating standard simulation device |
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CN202220279637.9U CN217274408U (en) | 2022-02-11 | 2022-02-11 | Medium-deep geothermal energy heating standard simulation device |
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