CN115059955A

CN115059955A - Semiconductor temperature difference heat collection geothermal heater

Info

Publication number: CN115059955A
Application number: CN202210588018.2A
Authority: CN
Inventors: 袁鸣; 闵可可
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-05-26
Filing date: 2022-05-26
Publication date: 2022-09-16

Abstract

The invention relates to the technical field of heaters, in particular to a semiconductor temperature difference heat collection geothermal heater which comprises a semiconductor temperature difference sheet, a hot water tank fixedly arranged on one side of the hot end of the semiconductor temperature difference sheet, a cold water tank fixedly arranged on one side of the cold end of the semiconductor temperature difference sheet, wherein the two ends of the hot water tank and the cold water tank are respectively communicated through two water guide pipes, a radiating pipe is fixedly arranged in the water guide pipe in the hot water tank, a plurality of radiating fins are fixedly arranged on the outer portion of the radiating pipe at equal intervals, and a plurality of fixing rods which are vertically inserted are fixedly arranged in the radiating pipe. According to the invention, the chaos degree of fluid in the radiating pipe is improved through the fixing rod, so that the radiating fins can be uniformly heated, the heating efficiency of the warmer is improved, the indoor space is efficiently heated, the scale is not easy to accumulate in the water guide pipe, and the effect of reducing the scale is achieved.

Description

Semiconductor temperature difference heat collection geothermal heater

Technical Field

The invention relates to the technical field of heaters, in particular to a semiconductor temperature difference heat collection geothermal heater.

Background

The semiconductor temperature difference heat collection is to concentrate low-temperature heat energy in underground water into high-temperature heat energy which can be used, and according to the Peltier effect: when two different metal conductors are connected, and direct current is applied to two ends of the conductor, the residual heat in addition to Joule heat is absorbed or released in different directions of current at the joint, so that the semiconductor temperature difference plate formed by a plurality of semiconductor temperature difference elements connected in series and in parallel can transfer the heat from one side to the other side.

The heating of room mainly utilizes coal-fired, oil fired boiler and electric heater, and coal-fired, oil fired boiler heating will consume a large amount of non-renewable resources, the pollution that causes the environment again simultaneously, and the electric heater is in the heating, and only a small part of heat is utilized, and this in-process directly converts high quality electric energy into the heat in addition, leads to the use cost to be on the high side, and is not energy-conserving enough.

Therefore, a semiconductor temperature difference heat collection geothermal heater is provided.

Disclosure of Invention

The invention aims to provide a semiconductor temperature difference heat collection geothermal heater, which improves the chaos degree of fluid in a radiating pipe through a fixing rod, so that a plurality of radiating fins can be uniformly heated, thereby improving the heating efficiency of the heater, further efficiently heating the indoor space, preventing scale from being easily accumulated in the water guide pipe, further reducing the scale, and solving the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a semiconductor difference in temperature collection geothermal heater, includes the semiconductor difference in temperature piece, the hot-water tank, fixed mounting is in hot junction one side of semiconductor difference in temperature piece, the cold-water tank, fixed mounting are in cold junction one side of semiconductor difference in temperature piece, the both ends of hot-water tank and cold-water tank are linked together through two aqueducts respectively, two water pumps for drive two respectively the inside water of aqueduct flows, and the cooling tube, fixed mounting is in the inside aqueduct of hot-water tank, the equidistant fixed mounting in outside of cooling tube has a plurality of fin, the inside of cooling tube is fixed mounting still has a plurality of dead levers of inserting perpendicularly and establishing.

When the warmer works, the semiconductor temperature difference sheet and the two water pumps are powered by the controller, the two water pumps can respectively drive the water body inside the hot water tank and the underground low-temperature water body to circularly flow, the semiconductor temperature difference sheet can concentrate the low-temperature heat energy obtained by the cold end from the water to the hot end under the condition of electrifying, so that the temperature of the hot water tank is increased, the water flows back after warming in the radiating pipe, part of the heat water taken out of the cold water tank is discharged back to the ground, when the hot water circularly flows through the radiating pipe, a plurality of fixed rods inserted in the pipe can be impacted, then, two rows of line vortexes with opposite rotation directions and arranged in a regular way can periodically fall off from two sides of the fixed rods, when the warmer starts, the two rows of line vortexes respectively keep the movement of the two lines to advance, then the two lines of line vortexes mutually interfere with each other and mutually attract each other, the interference is more and more, after the nonlinear action, form karman vortex street, and then improve the fluidic chaotic degree in cooling tube for a plurality of fin can the thermally equivalent, thereby improve the heating efficiency of room heater.

Preferably, the one end of semiconductor difference in temperature piece is rotated and is installed the pivot, the outside fixed mounting of pivot has the disc, the annular chamber has been seted up to the inside of disc, equidistant fixed mounting has a plurality of inflation balls that are heated and expand, every the equal fixed mounting in inside of inflation ball has the counter weight ball.

When the room heater work, the hot-water tank is great with the outside difference in temperature of cold water storage cistern, the regional temperature that the disc front end is close to the hot-water tank is higher, the regional temperature that the disc rear end is close to the cold water storage cistern is lower, the inflation ball of disc front end is heated the inflation, make the inflation ball to the regional extrusion of cold water storage cistern, thereby make the inside counter weight ball of inflation ball remove to the region of cold water storage cistern, make the gravity of disc rear side be greater than the front side gravity, break original balance and drive disc anticlockwise rotation, then turn to the regional being heated of hot-water tank with the lower inflation ball of disc rear end temperature, and hotter inflation ball is cooled down by crowded region to the cold water storage cistern, with this reciprocal, can make disc and pivot continuously rotate, and then provide power for the rotation of disc.

Preferably, the disc is made of metal copper.

The metal copper has good heat-conducting property, so that the heat of the hot water tank and the cold water tank can be quickly transferred to the inside of the annular cavity.

Preferably, one side fixed mounting of hot-water tank has the rectangular plate, a plurality of rectangular chambeies have been seted up to the inside equidistant of rectangular plate, and is a plurality of the inside common rotation in rectangular chamber installs the transfer line, the outer fringe of pivot is fixed mounting still has first drive wheel, the one end of transfer line extends to the outside of rectangular plate and fixed mounting has the second drive wheel, be connected through transmission belt transmission between first drive wheel and the second drive wheel.

After the disc rotates, the rotating shaft can drive the first driving wheel to rotate, then the driving rod in the second driving wheel is driven to rotate through the driving belt, and further the driving rod can be driven to continuously rotate to provide power for follow-up.

Preferably, every the inside in rectangular chamber all rotates and installs the guide arm, the outer fringe of transfer line is fixed mounting respectively in the inside in a plurality of rectangular chambers has first conical gear, the one end of guide arm has second conical gear in the inside fixed mounting in rectangular chamber, first conical gear and second conical gear meshing, the other end of guide arm extends to the outside of rectangular plate and fixed mounting has the fan.

After the transfer line rotates, can drive the first conical gear rotation of a plurality of rectangle intracavity portions, a plurality of first conical gear can drive a plurality of guide arms through a plurality of second conical gear respectively afterwards and rotate, and a plurality of guide arms can drive a plurality of fans and rotate afterwards, and then drive gas flow to blow to the fin, blow away the heat of fin inside afterwards, and then heat indoor, improve the room heater and to indoor heating efficiency.

Preferably, the diameter ratio of the first transmission wheel to the second transmission wheel is 7: 1.

Because the diameter of the first driving wheel is far greater than that of the second driving wheel, the rotating speed of the output end of the first driving wheel is reduced, but the torque is increased, so that the second driving wheel can be driven to rotate more easily, and the condition that the driving rod cannot rotate is avoided.

Preferably, the shape of the drive belt is a "mobius strip".

The driving belt with the Mobius belt-shaped structure can not only increase the effective friction area of the belt, but also distribute stress to two surfaces, thereby prolonging the service cycle by one time.

Preferably, a plurality of magnets are fixedly arranged at the inner edge of the disc at equal intervals.

After the disc rotates, the magnets can rotate in the vertical direction of the two water guide pipes, the magnetic field inside the magnets can magnetize the water inside the water guide pipes, the covalent bond angle of the water is changed from 105 degrees to 103 degrees after the water is magnetized, the original 13-18 macromolecular groups are changed into 5-6 small molecular groups, the permeability and the solubility of the water are obviously improved, CaCO3 and MgCO3 in the water are dissolved and converted into softer CaHCO32 and MgHCO32, the water is not easy to accumulate inside the water guide pipes, and the effect of reducing scale is achieved.

Preferably, the controller is arranged outside the hot water tank, and the semiconductor temperature difference sheet and the two water pumps are electrically connected with the controller.

Preferably, the water pipes at both ends of the cold water tank are inserted into the ground for 10 m.

Because the underground temperature is lower, can cool off the aqueduct at cold water tank both ends fast, and then make the cold junction of semiconductor difference in temperature piece can continuously contact with cold water, and then improve the work efficiency of room heater.

Compared with the prior art, the invention has the following beneficial effects:

1. when the room heater worked, the inside fluidic chaos degree of cooling tube can be improved to inside a plurality of dead levers of cooling tube for a plurality of fin can the thermally equivalent, thereby improve the heating efficiency of room heater.

2. When the room heater works, the fan-type air-cooling air heater can drive the fans to rotate, further drives air to flow, blows the cooling fins, then blows away heat inside the cooling fins, further heats the indoor space, and improves the heating efficiency of the room heater to the indoor space.

3. After the disc rotates, the scale is not easy to accumulate in the water guide pipe, and the effect of reducing the scale is achieved.

Drawings

FIG. 1 is a top view of the internal structure of the present invention;

FIG. 2 is a schematic perspective view of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 1;

FIG. 4 is a top view of the inner structure of the heat sink tube of the present invention;

FIG. 5 is a schematic diagram illustrating the flow of fluid within the heat pipe of the present invention;

FIG. 6 is a view showing the inner structure of the disk of the present invention;

fig. 7 is a side view of the present invention.

In the figure: the device comprises a semiconductor temperature difference sheet 1, a hot water tank 2, a cold water tank 3, a water pump 4, a water guide pipe 5, a heat dissipation pipe 6, a heat dissipation sheet 7, a fixing rod 8, a rectangular plate 9, a rotating shaft 10, a circular disc 11, an annular cavity 12, an expansion ball 13, a counterweight ball 14, a transmission rod 15, a first transmission wheel 16, a second transmission wheel 17, a transmission belt 18, a rectangular cavity 19, a first bevel gear 20, a second bevel gear 21, a guide rod 22, a fan 23 and a magnet 24.

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 to 7, the present invention provides a semiconductor temperature difference heat collection geothermal heater, which has the following technical scheme:

the utility model provides a semiconductor difference in temperature collection geothermal heater, including semiconductor difference in temperature piece 1, hot-water tank 2, fixed mounting is in hot junction one side of semiconductor difference in temperature piece 1, cold-water tank 3, fixed mounting is in cold junction one side of semiconductor difference in temperature piece 1, the both ends of hot-water tank 2 and cold-water tank 3 are linked together through two aqueducts 5 respectively, two water pumps 4, a water flow for driving two aqueducts 5 inside respectively, cooling tube 6, fixed mounting is in the aqueduct 5 of hot-water tank 2 inside, the equidistant fixed mounting in outside of cooling tube 6 has a plurality of fin 7, the inside of cooling tube 6 is fixed mounting still that a plurality of perpendicular dead levers 8 of establishing of inserting.

When the warmer works, the semiconductor temperature difference sheet 1 and the two water pumps 4 are powered by the controller, the two water pumps 4 can respectively drive the water body inside the hot water tank 2 and the underground low-temperature water body to circularly flow, the semiconductor temperature difference sheet 1 can concentrate the low-temperature heat energy obtained by the cold end from the water to the hot end under the condition of electrifying, so that the temperature of the water in the hot water tank 2 is increased, the water flows back after being warmed in the radiating pipe 6, the water with partial heat taken out from the cold water tank 3 is discharged to the underground, when the hot water circularly flows through the radiating pipe 6, a plurality of fixing rods 8 inserted in the pipe are impacted, then two rows of line vortexes with opposite rotating directions and arranged in a regular way are periodically dropped out on two sides of the fixing rods 8, when the two rows of line vortexes start, the two rows of line vortexes respectively keep the movement of the two lines advancing, then the two lines of line vortexes interfere with each other and attract each other, and the interference is bigger and bigger, after the nonlinear action, a Karman vortex street (as shown in figure 5) is formed, and then the chaos degree of the fluid in the radiating pipe 6 is improved, so that the radiating fins 7 can be heated uniformly, and the heating efficiency of the warmer is improved.

As an embodiment of the present invention, referring to fig. 6, one end of a semiconductor temperature difference sheet 1 is rotatably mounted with a rotating shaft 10, a disk 11 is fixedly mounted outside the rotating shaft 10, an annular cavity 12 is opened inside the disk 11, a plurality of expansion balls 13 which expand when heated are fixedly mounted inside the annular cavity 12 at equal intervals, and a counterweight ball 14 is fixedly mounted inside each expansion ball 13.

When the warmer works, the temperature difference between the hot water tank 2 and the outside of the cold water tank 3 is large, the temperature of the area, close to the hot water tank 2, at the front end of the disc 11 is high, the temperature of the area, close to the cold water tank 3, at the rear end of the disc 11 is low, the expansion ball 13 at the front end of the disc 11 is heated and expanded, the expansion ball 13 is extruded to the area of the cold water tank 3, the balance ball 14 inside the expansion ball 13 moves to the area of the cold water tank 3, the gravity at the rear end of the disc 11 is larger than the gravity at the front end, the original balance is broken and the disc 11 is driven to rotate anticlockwise, the expansion ball 13 with the low temperature at the rear end of the disc 11 is turned to the area of the hot water tank 2 and the hotter expansion ball 13 is extruded to the area of the cold water tank 3 to be cooled, the reciprocating mode is adopted, the disc 11 and the rotating shaft 10 can continuously rotate, and power is provided for the rotation of the disc 11.

Referring to fig. 6, a material of the disc 11 is copper metal.

The copper metal has good heat conductivity, so that the heat of the hot water tank 2 and the cold water tank 3 can be rapidly transferred to the inside of the annular cavity 12.

6-7, a rectangular plate 9 is fixedly mounted on one side of the hot water tank 2, a plurality of rectangular cavities 19 are formed in the rectangular plate 9 at equal intervals, a transmission rod 15 is rotatably mounted in the rectangular cavities 19, a first transmission wheel 16 is further fixedly mounted on the outer edge of the rotating shaft 10, one end of the transmission rod 15 extends to the outside of the rectangular plate 9 and is fixedly mounted with a second transmission wheel 17, and the first transmission wheel 16 is in transmission connection with the second transmission wheel 17 through a transmission belt 18.

After the disc 11 rotates, the rotating shaft 10 drives the first driving wheel 16 to rotate, and then drives the driving rod 15 inside the second driving wheel 17 to rotate through the driving belt 18, so as to drive the driving rod 15 to rotate continuously, thereby providing power for the subsequent process.

As an embodiment of the present invention, referring to fig. 1 to 3, a guide rod 22 is rotatably installed inside each rectangular cavity 19, a first bevel gear 20 is fixedly installed on the outer edge of the transmission rod 15 inside each rectangular cavity 19, a second bevel gear 21 is fixedly installed on one end of the guide rod 22 inside the rectangular cavity 19, the first bevel gear 20 is engaged with the second bevel gear 21, and the other end of the guide rod 22 extends to the outside of the rectangular plate 9 and is fixedly installed with a fan 23.

After the transmission rod 15 rotates, the first bevel gears 20 inside the rectangular cavities 19 can be driven to rotate, then the first bevel gears 20 can drive the guide rods 22 to rotate through the second bevel gears 21 respectively, then the guide rods 22 can drive the fans 23 to rotate, and then the air is driven to flow and blow to the radiating fins 7, then the heat inside the radiating fins 7 is blown away, so that the indoor heating efficiency of the heater is improved.

Referring to fig. 7, as an embodiment of the present invention, the diameter ratio of the first transmission wheel 16 to the second transmission wheel 17 is 7: 1.

Because the diameter of the first transmission wheel 16 is far larger than that of the second transmission wheel 17, the rotating speed of the output end of the first transmission wheel 16 is reduced, but the torque is increased, so that the second transmission wheel 17 can be driven to rotate more easily, and the situation that the transmission rod 15 cannot rotate is avoided.

Referring to fig. 7, the shape of the transmission belt 18 is a "mobius strip" shape as an embodiment of the present invention.

The drive belt 18 of the "Mobius belt" like structure not only increases the effective friction area of the belt, but also distributes stress to both sides, thereby doubling the service life.

Referring to fig. 6, as an embodiment of the present invention, a plurality of magnets 24 are fixedly mounted at equal intervals on the inner edge of the disc 11.

After the disk 11 rotates, the magnets 24 can rotate in the vertical direction of the two water conduits 5, the magnetic field inside the magnets 24 can magnetize the water inside the water conduits 5, the covalent bond angle of the water is changed from 105 degrees to 103 degrees after the water is magnetized, the original 13-18 macromolecular groups are changed into 5-6 small molecular groups, the permeability and the solubility of the water are obviously improved, CaCO3 and MgCO3 in the water are dissolved and converted into softer CaHCO32 and MgHCO32, so that the water is not easy to accumulate inside the water conduits 5, and the scale is further reduced.

Referring to fig. 1, a controller is disposed outside a hot water tank 2, and a semiconductor temperature difference sheet 1 and two water pumps 4 are electrically connected to the controller.

Referring to fig. 1, as one embodiment of the present invention, water introduction pipes 5 at both ends of a cold water tank 3 are inserted into the ground by 10 m.

Because the underground temperature is lower, can cool off the aqueduct 5 at 3 both ends of cold water tank fast, and then make the cold junction of semiconductor difference in temperature piece 1 can contact with cold water continuously, and then improve the work efficiency of room heater.

The working principle is as follows: when the warmer works, the semiconductor temperature difference sheet 1 and the two water pumps 4 are powered by the controller, the two water pumps 4 can respectively drive the water body inside the hot water tank 2 and the underground low-temperature water body to circularly flow, the semiconductor temperature difference sheet 1 can concentrate the low-temperature heat energy obtained by the cold end from the water to the hot end under the condition of electrifying, so that the temperature of the water in the hot water tank 2 is increased, the water flows back after being warmed in the radiating pipe 6, the water with partial heat taken out from the cold water tank 3 is discharged to the underground, when the hot water circularly flows through the radiating pipe 6, a plurality of fixing rods 8 inserted in the pipe are impacted, then two rows of line vortexes with opposite rotating directions and arranged in a regular way are periodically dropped out on two sides of the fixing rods 8, when the two rows of line vortexes start, the two rows of line vortexes respectively keep the movement of the two lines advancing, then the two lines of line vortexes interfere with each other and attract each other, and the interference is increased more and more, after the nonlinear effect, a karman vortex street is formed, and further the chaos of the fluid in the radiating pipe 6 is improved, so that the radiating fins 7 can be heated uniformly, thereby improving the heating efficiency of the heater, when the heater works, the temperature difference between the outside of the hot water tank 2 and the outside of the cold water tank 3 is larger, the temperature of the region of the front end of the disc 11 close to the hot water tank 2 is higher, the temperature of the region of the rear end of the disc 11 close to the cold water tank 3 is lower, the expansion ball 13 of the front end of the disc 11 is heated and expanded, so that the expansion ball 13 is extruded to the region of the cold water tank 3, so that the counterweight ball 14 in the expansion ball 13 moves to the region of the cold water tank 3, the gravity of the rear side of the disc 11 is larger than the gravity of the front side, the original balance is broken, the disc 11 is driven to rotate anticlockwise, then the expansion ball 13 with the lower temperature of the rear end of the disc 11 is turned to the region of the hot water tank 2 to be heated, the hotter expansion ball 13 is squeezed to the area of the cold water tank 3 to be cooled, and the operation is repeated, so that the disc 11 and the rotating shaft 10 continuously rotate, and further the rotation of the disc 11 is provided with power, after the disc 11 rotates, the rotating shaft 10 drives the first driving wheel 16 to rotate, and then drives the driving rod 15 inside the second driving wheel 17 to rotate through the driving belt 18, and further can drive the driving rod 15 to continuously rotate, after the driving rod 15 rotates, the first bevel gears 20 inside the rectangular cavities 19 are driven to rotate, then the first bevel gears 20 drive the guide rods 22 to rotate through the second bevel gears 21, and then the guide rods 22 drive the fans 23 to rotate, so as to drive the gas to flow and blow to the radiating fins 7, and then the heat inside the radiating fins 7 is blown away, so as to heat the indoor space, and improve the indoor heating efficiency of the heater, after the disk 11 rotates, the magnets 24 can rotate in the vertical direction of the two water conduits 5, the magnetic field inside the magnets 24 can magnetize the water inside the water conduits 5, the covalent bond angle of the water is changed from 105 degrees to 103 degrees after the water is magnetized, the original 13-18 macromolecular groups are changed into 5-6 small molecular groups, the permeability and the solubility of the water are obviously improved, CaCO3 and MgCO3 in the water are dissolved and converted into softer CaHCO32 and MgHCO32, so that the water is not easy to accumulate inside the water conduits 5, and the scale is further reduced.

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. A semiconductor temperature difference heat collecting geothermal warmer comprises a semiconductor temperature difference sheet (1);

the hot water tank (2) is fixedly arranged on one side of the hot end of the semiconductor temperature difference sheet (1);

the cold water tank (3) is fixedly arranged on one side of the cold end of the semiconductor temperature difference sheet (1);

the two ends of the hot water tank (2) and the cold water tank (3) are respectively communicated through two water guide pipes (5);

the two water pumps (4) are used for respectively driving the water bodies in the two water guide pipes (5) to flow;

the radiating pipe (6) is fixedly arranged in the water guide pipe (5) in the hot water tank (2);

the method is characterized in that:

the outside equidistant fixed mounting of cooling tube (6) has a plurality of fin (7), the inside still fixed mounting of cooling tube (6) has a plurality of dead lever (8) of establishing of inserting perpendicularly.

2. The semiconductor temperature difference heat collection geothermal warmer according to claim 1, characterized in that: the one end of semiconductor difference in temperature piece (1) is rotated and is installed pivot (10), the outside fixed mounting of pivot (10) has disc (11), annular chamber (12) have been seted up to the inside of disc (11), equidistant fixed mounting has a plurality of inflation balls (13) of being heated inflation, every in the inside of annular chamber (12) the equal fixed mounting in inside of inflation ball (13) has counterweight ball (14).

3. The semiconductor temperature difference heat collection geothermal warmer according to claim 2, characterized in that: the disc (11) is made of metal copper.

4. The semiconductor temperature difference heat collection geothermal warmer according to claim 2, characterized in that: a rectangular plate (9) is fixedly installed on one side of the hot water tank (2), a plurality of rectangular cavities (19) are formed in the rectangular plate (9) at equal intervals, and transmission rods (15) are installed in the rectangular cavities (19) in a rotating mode;

a first driving wheel (16) is fixedly mounted at the outer edge of the rotating shaft (10), one end of the driving rod (15) extends to the outside of the rectangular plate (9) and is fixedly provided with a second driving wheel (17);

the first transmission wheel (16) is in transmission connection with the second transmission wheel (17) through a transmission belt (18).

5. The semiconductor temperature difference heat collection geothermal warmer of claim 4, wherein: every the inside of rectangle chamber (19) all rotates and installs guide arm (22), the outer fringe of transfer line (15) is fixed mounting respectively in the inside of a plurality of rectangle chambers (19) has first conical gear (20), the one end of guide arm (22) has second conical gear (21) in the inside fixed mounting of rectangle chamber (19), first conical gear (20) and second conical gear (21) meshing, the other end of guide arm (22) extends to the outside and fixed mounting of rectangular plate (9) has fan (23).

6. The semiconductor temperature difference heat collection geothermal warmer of claim 4, wherein: the diameter ratio of the first transmission wheel (16) to the second transmission wheel (17) is 7: 1.

7. The semiconductor temperature difference heat collection geothermal warmer of claim 4, wherein: the drive belt (18) is in the shape of a Mobius belt.

8. The semiconductor temperature difference heat collection geothermal warmer according to claim 2, characterized in that: and a plurality of magnets (24) are fixedly arranged at the inner edge of the disc (11) at equal intervals.

9. The semiconductor temperature difference heat collection geothermal warmer according to claim 1, characterized in that: the outside of hot-water tank (2) is equipped with the controller, semiconductor difference in temperature piece (1) and two water pumps (4) all with controller electric connection.

10. The semiconductor temperature difference heat collection geothermal warmer according to claim 1, characterized in that: the water guide pipes (5) at two ends of the cold water tank (3) are inserted into the ground for 10 m.