CN111609577A

CN111609577A - Efficient geothermal energy recycles device

Info

Publication number: CN111609577A
Application number: CN202010495154.8A
Authority: CN
Inventors: 于丽丽
Original assignee: Individual
Current assignee: Shaanxi Sixin New Energy Technology Co.,Ltd.
Priority date: 2020-06-03
Filing date: 2020-06-03
Publication date: 2020-09-01
Anticipated expiration: 2040-06-03
Also published as: CN111609577B

Abstract

The invention provides an efficient geothermal energy recycling device, wherein a pressure pump is installed on the left side of a liquid storage chamber, an exchange chamber is arranged on the right side of the liquid storage chamber, exchange pipes are installed inside the exchange chamber, heat exchange pipes are fixedly connected to the front surface and the rear surface of the exchange chamber, a heat conduction plate is installed on the outer side surface of each exchange pipe, a supplement chamber is arranged on the left side of the pressure pump, a feeding pipe is fixedly connected to the left side of a second valve, a flow dividing pipe is fixedly connected to the lower end of the feeding pipe, a heat conduction pipe is fixedly connected to the inner side of the flow dividing pipe, a discharging pipe is fixedly connected to the right side of the flow dividing pipe. External wind power can automatically drive the cleaning plate to reciprocate, and the right side surface of the filter plate can be cleaned without manual work, so that the filtering effect is kept, the service life of the filter plate is prolonged, heat supply can be controlled at regular time according to actual conditions, the accuracy is increased while the labor is saved, and the practicability is improved.

Description

Efficient geothermal energy recycles device

Technical Field

The invention relates to the technical field of geothermal energy recycling, in particular to a high-efficiency geothermal energy recycling device.

Background

The geothermal energy is natural heat energy extracted from the earth crust, the energy comes from lava in the earth and exists in the form of heat power, the utilization of the geothermal energy is rapidly developed along with the development of the society, the utilization of the geothermal energy is mainly a geothermal energy emitting point, and besides, geothermal water can be directly utilized for building heating, greenhouse agriculture and hot spring tourism.

However, the existing geothermal energy recycling device still has some disadvantages, for example, the exchange fluid of the existing geothermal energy recycling device is easy to be mixed with the impurities attached to the inner wall of the pipeline when flowing in the pipeline, and the impurities are generally filtered by a filter screen, but the impurities attached to the surface of the filter screen after long-time use are difficult to clean, so that the filtering effect is affected, and the circulation of the liquid inside the existing geothermal energy recycling device is generally controlled by a manual switch, so that the existing geothermal energy recycling device is quite inconvenient.

Disclosure of Invention

In order to solve the above technical problems, the present invention provides an efficient geothermal energy recycling device, which is achieved by the following specific technical means:

the utility model provides a device is recycled to efficient geothermal energy, includes the liquid reserve room, the force pump is installed in the left side of liquid reserve room, and the right side of liquid reserve room is provided with the exchange room, the internally mounted of exchange room has the exchange tube, and the equal fixedly connected with heat exchange tube in surface around the exchange room, the outside surface mounting of exchange tube has the heat-conducting plate, the left side of force pump is provided with supplyes the room, first valve is installed on the right side of supplyes the room, the second valve is installed in the left side of force pump, the left side fixedly connected with inlet pipe of second valve, the lower extreme fixedly connected with shunt tubes of inlet pipe, the inboard fixedly connected with heat pipe of shunt tubes, and the right side fixedly connected with discharging pipe of shunt tubes, the upper end fixedly connected with air-lift room of discharging pipe, the circulating pump is installed in the left side of, the utility model discloses a solar energy collecting device, including photosensitive resistor, connecting rack, connecting box, connecting board, fan, filter, connecting board, fan.

Preferably, the replenishing chamber, the liquid storage chamber, the exchange chamber and the gas lift chamber are connected through pipelines, and the heat conduction pipe is a member made of stainless steel.

As optimization, the lower extreme fixedly connected with rubber material of baffle seals up, and baffle and circulating pump and airlift chamber between the inner wall of pipeline closely laminate, and the clearance of baffle lower extreme and pipeline can be filled to sealed the pad, increases the leakproofness of junction.

As optimization, the aerofoil is the component of PVC material, and the aerofoil is evenly installed at the outside surface of connecting axle, and the aerofoil is the fan shape, drives the connecting axle rotation when receiving external wind-force influence.

As optimization, the left side surface of the cleaning plate is fixedly provided with a metal wire, and the left side surface of the heat conducting plate is covered with activated carbon.

As optimization, first belt pulley and second belt pulley are same perpendicular line, and first belt pulley and second belt pulley are connected through the belt.

The invention has the following beneficial effects:

1. this efficient geothermal energy recycles device, promote the aerofoil clockwise or anticlockwise rotation through external wind-force, then drive the connecting axle and rotate, when the connecting axle clockwise rotation, drive first belt pulley clockwise, the rethread conveyer belt drives second belt pulley clockwise, drive gear clockwise at last, promote connection rack and cleaning plate downstream, when the connecting axle anticlockwise, drive first belt pulley anticlockwise, the rethread conveyer belt drives second belt pulley anticlockwise, drive gear anticlockwise at last, promote connection rack and cleaning plate rebound, the impurity of striking off falls into inside the collection box, external wind-force can the automatic drive cleaning plate reciprocate, it can clean the right side surface of filter to need not the manual work, keep its filter effect, prolong its life.

2. This efficient geothermal energy recycles device, one side and the external power supply electricity of photo resistance are connected, and photo resistance's opposite side and coil electricity are connected, in the daytime, photo resistance's resistance is little, external power supply is to the coil power supply, make the subsidiary magnetic force of iron core, the magnetic pole of iron core lower extreme repels with the magnetic pole of magnetic path upper end, promote the sealed pipeline of baffle, stop the circulation of exchange liquid, at night, photo resistance's resistance is big, external power supply is neglected to the electric current of coil, make the iron core lose magnetic force, the iron core is adsorbed by the magnetic path, it shifts up to drive the baffle, exchange liquid gets into the inside heat supply of exchange room, can be according to actual conditions timing control heat supply, the labour is practiced thrift and the accuracy has been increased.

Drawings

FIG. 1 is a front view of the present invention.

Fig. 2 is a cross-sectional view of the present invention.

Fig. 3 is a top sectional view of the heat conductive pipe of the present invention.

FIG. 4 is a cross-sectional view of an exchange chamber of the present invention.

FIG. 5 is a cross-sectional view of a reservoir of the present invention.

FIG. 6 is a cross-sectional view of the liquid storage chamber side of the present invention.

Fig. 7 is an enlarged view of a in fig. 2.

FIG. 8 is a side cross-sectional view of a baffle of the present invention.

In the figure: 1. a replenishing chamber; 2. a first valve; 3. a second valve; 4. a pressure pump; 5. a liquid storage chamber; 6. an exchange chamber; 7. a circulation pump; 8. an airlift chamber; 9. a discharge pipe; 10. a feed pipe; 11. a heat conducting pipe; 12. a filter plate; 13. a heat conducting plate; 14. a shunt tube; 15. a heat exchange pipe; 16. a photoresistor; 17. exchanging pipes; 18. an iron core; 19. cleaning the plate; 20. connecting the racks; 21. a gear; 22. a collection box; 23. a wind plate; 24. a connecting shaft; 25. a baffle plate; 26. a first pulley; 27. a belt; 28. a second pulley; 29. a coil; 30. a magnetic block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, a high-efficiency geothermal energy recycling device comprises a liquid storage chamber 5, a pressure pump 4 is installed on the left side of the liquid storage chamber 5, an exchange chamber 6 is installed on the right side of the liquid storage chamber 5, an exchange tube 17 is installed inside the exchange chamber 6, heat exchange tubes 15 are fixedly connected to the front and rear surfaces of the exchange chamber 6, a heat conduction plate 13 is installed on the outer surface of the exchange tube 17, a supplement chamber 1 is installed on the left side of the pressure pump 4, the supplement chamber 1, the liquid storage chamber 5, the exchange chamber 6 and the air lift chamber 8 are all connected through a pipeline, the heat conduction tube 11 is a stainless steel member, a first valve 2 is installed on the right side of the supplement chamber 1, a second valve 3 is installed on the left side of the pressure pump 4, a feeding tube 10 is fixedly connected to the left side of the second valve 3, a shunt tube 14 is fixedly connected to the, a discharge pipe 9 is fixedly connected to the right side of the shunt pipe 14, an air lift chamber 8 is fixedly connected to the upper end of the discharge pipe 9, a circulating pump 7 is installed on the left side of the air lift chamber 8, a photoresistor 16 is installed on the upper surface of the circulating pump 7, an iron core 18 is arranged below the photoresistor 16, a coil 29 is wound on the surface of the iron core 18, a magnetic block 30 is arranged below the iron core 18, a baffle plate 25 is fixedly connected to the lower surface of the magnetic block 30, a sealing gasket made of rubber is fixedly connected to the lower end of the baffle plate 25, the baffle plate 25 is tightly attached to the inner wall of a pipeline between the circulating pump 7 and the air lift chamber 8, a filter plate 12 is installed inside the liquid storage chamber 5, connecting shafts 24 are installed on the left side and the right side of the liquid storage chamber 5, a collecting box 22 is arranged on the right side of the filter plate 12, aerofoil 23 is the component of PVC material, and aerofoil 23 evenly installs the outside surface at connecting axle 24, first belt pulley 26's below is provided with second belt pulley 28, and first belt pulley 26's outside surface mounting has belt 27, first belt pulley 26 and second belt pulley 28 are same perpendicular line, and first belt pulley 26 and second belt pulley 28 are connected through belt 27, second belt pulley 28's inboard fixedly connected with gear 21, the equal meshing of the rear surface of gear 21 is connected with connection rack 20, the equal fixed mounting of the last lower extreme of connecting rack 20 has cleaning plate 19, cleaning plate 19's left side fixed surface installs the wire, the left side surface covering of heat-conducting plate 13 has active carbon.

When the device is used, the pressure pump 4 and the second valve 3 are firstly opened, the exchange liquid in the liquid storage chamber 5 is sent into the heat conduction pipes 11 through the feeding pipes 10 by the pressure pump 4, the heat conduction pipes 11 are uniformly arranged among the shunt pipes 14, the exchange speed of the exchange liquid and terrestrial heat can be increased, the exchange liquid is heated to be gas, the gas enters the air lifting chamber 8 from the discharging pipes 9 and is then conveyed into the exchange pipes 17 in the exchange chamber 6 by the circulating pump 7, the heat conduction plates 13 are arranged on the surfaces of the exchange pipes 17, water is injected from the heat exchange pipes 15, the high-temperature gas in the exchange pipes 17 exchanges heat with the water and is changed into liquid again, the heated water flows out from the heat exchange pipes 15 at the front end, and the liquid returns to the liquid storage chamber 5 through the pipes and is filtered by the filter plates.

The wind board 23 is pushed by the external wind to rotate clockwise or anticlockwise, and then the connecting shaft 24 is driven to rotate, when the connecting shaft 24 rotates clockwise, the first belt pulley 26 is driven to rotate clockwise, the second belt pulley 28 is driven to rotate clockwise by the conveyor belt, finally the gear 21 is driven to rotate clockwise, the connecting rack 20 and the cleaning plate 19 are pushed to move downwards, when 24 anticlockwise rotations of connecting axle, drive first belt pulley 26 anticlockwise rotations, rethread conveyer belt drives second belt pulley 28 anticlockwise rotations, drives gear 21 anticlockwise rotation at last, promotes connecting rack 20 and cleaning plate 19 rebound, and the impurity of striking off falls into inside collecting box 22, and external wind-force can drive cleaning plate 19 automatically and reciprocate, need not the manual work and can clean the right side surface of filter 12, keeps its filter effect, prolongs its life.

One side through photo resistance 16 is connected with external power supply electricity, and photo resistance 16's opposite side and coil 29 electricity are connected, in the daytime, photo resistance 16's resistance is little, external power supply supplies power to coil 29, make iron core 18 attach magnetic force, the magnetic pole of iron core 18 lower extreme repels with the magnetic pole of the magnetic path 30 upper end mutually, promote baffle 25 seal tube, stop the circulation of exchange liquid, at night, photo resistance 16's resistance is big, external power supply ignores the electric current of coil 29, make iron core 18 lose magnetic force, iron core 18 is adsorbed by magnetic path 30, it moves up to drive baffle 25, exchange liquid gets into the inside heat supply of exchange room 6, can be according to actual conditions timing control heat supply, the accuracy has been increased when practicing thrift the labour, the practicality has been improved.

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

1. An efficient geothermal energy recycling device, comprising a liquid storage chamber (5), characterized in that: the utility model discloses a heat exchanger, including liquid storage chamber (5), heat exchange chamber (6), exchange chamber (6) internally mounted has exchange pipe (17), and the equal fixedly connected with heat exchange tube (15) in surface around exchange chamber (6), the outside surface mounting of exchange pipe (17) has heat-conducting plate (13), the left side of heat pump (4) is provided with supplyes room (1), first valve (2) are installed on the right side of supplyes room (1), second valve (3) are installed in the left side of heat pump (4), the left side fixedly connected with inlet pipe (10) of second valve (3), the lower extreme fixedly connected with shunt tubes (14) of inlet pipe (10), the inboard fixedly connected with heat pipe (11) of shunt tubes (14), and the right side fixedly connected with discharging pipe (9) of shunt tubes (14), the upper end fixedly connected with air-lift chamber (8) of discharging pipe (9), circulating pump (7) is installed in the left side of air-lift chamber (8), the last surface mounting of circulating pump (7) has photo resistance (16), the below of photo resistance (16) is provided with iron core (18), the surface winding of iron core (18) has coil (29), and the below of iron core (18) is provided with magnetic block (30), the lower fixed surface of magnetic block (30) is connected with baffle (25), the internally mounted of stock solution chamber (5) has filter (12), and the connecting axle (24) is all installed to the left and right sides of stock solution chamber (5), the inside of stock solution chamber (5) is located the right side of filter (12) and is provided with collection box (22), the outside surface mounting of connecting axle (24) has aerofoil (23), and the inboard equal fixedly connected with first belt pulley (26) of connecting axle (24), the below of first belt pulley (26) is provided with second belt pulley (28), and the outside surface mounting of first belt pulley (26) has belt (27), inboard fixedly connected with gear (21) of second belt pulley (28), the equal meshing of rear surface of gear (21) is connected with connecting rack (20), the equal fixed mounting in upper and lower end of connecting rack (20) has cleaning plate (19).

2. A highly efficient geothermal energy recycling apparatus according to claim 1, wherein: the supplementing chamber (1), the liquid storage chamber (5), the exchange chamber (6) and the air lift chamber (8) are connected through pipelines, and the heat conduction pipe (11) is a stainless steel component.

3. A highly efficient geothermal energy recycling apparatus according to claim 1, wherein: the lower extreme fixedly connected with rubber material of baffle (25) seals up, and baffle (25) and circulating pump (7) and airlift room (8) between the inner wall of pipeline closely laminate.

4. A highly efficient geothermal energy recycling apparatus according to claim 1, wherein: the wind plates (23) are made of PVC materials, and the wind plates (23) are uniformly arranged on the outer side surface of the connecting shaft (24).

5. A highly efficient geothermal energy recycling apparatus according to claim 1, wherein: the left side fixed surface of cleaning plate (19) installs the wire, the left side surface covering of heat-conducting plate (13) has active carbon.

6. A highly efficient geothermal energy recycling apparatus according to claim 1, wherein: the first belt pulley (26) and the second belt pulley (28) are in the same vertical line, and the first belt pulley (26) and the second belt pulley (28) are connected through a belt (27).