JP2002111078A - Thermoelectric power-generating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thermoelectric power-generating device for efficient recovery of a generated electric power by allowing a temperature difference between a part to be heated and a part to be cooled of a thermoelectric conversion unit which uses a thermoelectric conversion element. SOLUTION: A thermoelectric power-generating device 100 is provided which comprises a thermoelectric conversion unit provided with a part to be heated and a part to be cooled, a heating air path where a heating air passes which heats the part to be heated, and a cooling air path where a cooling air passes which cools the part to be cooled. Here, a ventilation pipe 40 is provided which communicates with an air outlet 31 of the cooling air path and guides, upward, the cooling air which has passed the cooling air path. Since the density of the cooling air which has passed the cooling air path is lower compared with the outside air, the speed at which the cooling air passes the cooling air path is raised by guiding upward the cooling air of lower density by a ventilation force using the ventilation pipe 40.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a thermoelectric generator. More specifically, the present invention relates to a thermoelectric generator having a thermoelectric conversion unit configured using thermoelectric conversion elements, a cooling air passage, and a heated air passage.

[0002]

2. Description of the Related Art Thermoelectric power generation is a closed circuit in which two different metals are joined together, and if there is a temperature difference between one joint and the other, an electromotive force is generated between the two joints. This is a power generation method that utilizes the Seebeck effect in which a current is generated. In this thermoelectric power generation, it is general that the ends of a large number of thermoelectric conversion elements are connected in series to constitute a thermoelectric conversion unit. In this case, the connected ends of the thermoelectric conversion element are alternately used as a cooled portion and a heated portion, and the cooled portion is cooled with a low-temperature fluid, and the heated portion is heated with a high-temperature fluid. A temperature difference is applied between the cooling section and the heated section, and the generated power is recovered. Therefore, the thermoelectric generator generally includes a passage through which a low-temperature fluid that cools the cooled portion of the thermoelectric conversion unit and a passage through which a high-temperature fluid that heats the heated portion of the thermoelectric conversion unit pass.

[0003]

In this thermoelectric generator, a temperature difference is applied between the cooled portion and the heated portion of the thermoelectric conversion unit, and power generated by the temperature difference is recovered. The greater the temperature difference between the heating unit and the heating unit, the more power can be recovered. Therefore, it is necessary to increase the temperature difference between the heated part and the cooled part.

In this case, a high-temperature exhaust gas discharged from an internal combustion engine, a fuel furnace, an incinerator or the like is used as a high-temperature fluid for heating the heated portion, and a natural outside air is used as a low-temperature fluid for cooling the cooled portion. Was used. In this case, it has been customary to form an air passage through which natural outside air flows upward from below to cool the cooled portion. In the process of cooling the cooled part heated by the heat conduction from the heated part, the natural outside air receives heat from the cooled part, and the temperature rises and flows upward. However, in the method utilizing the natural convection, the speed of the air for cooling the cooled portion is not so high, and there is a problem that the cooled portion is not sufficiently cooled.

In order to further increase the cooling efficiency of the part to be cooled, there has conventionally been a method of using a cooling fan to increase the speed of natural outside air. However, the method of using a cooling fan to increase the cooling efficiency of the cooled part consumes the power collected by thermoelectric generation for the cooling fan, so that the power that can be effectively used among the collected power becomes small, There has been a problem that the power recovery efficiency is deteriorated.

SUMMARY OF THE INVENTION An object of the present invention is to provide a thermoelectric generator capable of increasing the temperature difference between a heated portion and a cooled portion of a thermoelectric conversion unit using a thermoelectric conversion element and efficiently recovering generated power. It is to provide a device.

[0007]

The inventor of the present invention has proposed that when air outside the thermoelectric conversion device, that is, natural outside air, is used as the air for cooling the portion to be cooled of the thermoelectric conversion unit, the outside air used for cooling is cooled. In the course of cooling the cooling part, the heat received from the part to be cooled was received, and the point that the temperature became higher than the outside air and the density became smaller was noticed. Then, it was considered that air having a density lower than that of the outside air by passing through the portion to be cooled can be led upward using wind power.

As a result of further studies, the inventor of the present invention has found that a thermoelectric conversion unit including a thermoelectric conversion element and having a heated portion and a cooled portion, and a heating device through which heated air for heating the heated portion passes. In a thermoelectric generator having an air passage and a cooling air passage through which cooling air for cooling the portion to be cooled passes, the cooling air passing through the cooling air passage communicating with an air outlet of the cooling air passage is led upward. A thermoelectric power generation device characterized by having a ventilating pipe that performs the same is invented.

In the thermoelectric generator of the present invention, the thermoelectric conversion unit constituted by using the thermoelectric conversion elements has a heated portion and a cooled portion, and the heated air passing through the heated air passage heats the heated portion. Then, the cooling air passing through the cooling air passage cools the portion to be cooled. In this case, the cooling air passing through the cooling air passage deprives the cooled portion of the thermoelectric conversion unit of heat, thereby cooling the cooled portion. Higher temperature and lower density.

[0010] The thermoelectric generator of the present invention utilizes the ventilation air generated by the density difference between the cooling air having the reduced density and the outside air, and the ventilation pipe communicates with the air outlet of the cooling air passage. The cooling air having a reduced density is guided upward by wind power. As a result, the speed of the cooling air passing through the cooling air passage becomes faster than that without the ventilation pipe, and the amount of the cooling air passing through the cooling air passage increases.

As a result of the increase in the speed of the cooling air, heat transfer from the portion to be cooled to the cooling air is increased, and the cooling efficiency is improved. Therefore, the thermoelectric generator of the present invention can make the temperature difference between the heated part and the cooled part of the thermoelectric conversion unit larger, and can collect more electric power.

Since the ventilation pipe provided at the air outlet of the cooling air passage is used, it is not necessary to use electric power unlike a cooling fan for increasing the speed of cooling air passing through the cooling air passage. Therefore, the thermoelectric generator of the present invention can efficiently recover generated power.

The inventor has noticed that high-temperature exhaust gas is forcibly discharged from a combustion furnace or the like through an exhaust passage by a discharge means such as an exhaust duct. Utilizing the high-temperature exhaust gas that is forcibly exhausted through the exhaust passage by exhaust means such as an exhaust duct as air for heating the heated portion of the thermoelectric conversion unit, the air that has cooled the cooled portion is used as the heated portion. Was considered to be forced to be discharged as the high-temperature exhaust is discharged if the air cooled by the cooled part is discharged.

Therefore, the present inventor has proposed a thermoelectric conversion unit comprising a thermoelectric conversion element and having a heated portion and a cooled portion, a heated air passage through which heated air for heating the heated portion passes, and a heated air passage. A thermoelectric generator having a cooling air passage through which cooling air for cooling the cooling section passes; exhaust means having an exhaust passage through which exhaust gas is passed and the middle of which is used as the heating air passage; and an air outlet of the cooling air passage. And a ventilation pipe that leads cooling air that has passed through the cooling air passage to the exhaust passage downstream of the heating air passage.

In the thermoelectric generator of the present invention, the thermoelectric conversion unit constituted by using the thermoelectric conversion elements includes a heated portion and a cooled portion, and the heated air passing through the heated air passage heats the heated portion. Then, the cooling air passing through the cooling air passage cools the portion to be cooled. In this case, the exhaust passage of the exhaust means is used as a heated air passage through which the heated air for heating the heated portion of the thermoelectric conversion unit passes, and the exhaust air, which is the heated air passing through the heated air passage, is forcibly forced by the exhaust means. Will be discharged.

The thermoelectric generator of the present invention utilizes the fact that the exhaust gas that has passed through the heated air passage is forcibly discharged by the discharge means. By having the ventilation pipe opened to the exhaust passage on the downstream side, the cooling air passing through the cooling air passage enters the exhaust passage of the discharge means through the ventilation pipe, merges with the exhaust gas, and is discharged. . As a result, the speed of the cooling air passing through the cooling air passage becomes faster than that without the ventilation pipe, and the amount of the cooling air passing through the cooling air passage increases. The amount of cooling air passing through the cooling air passage can be increased as the exhaust force of the exhaust means increases.

As a result of the increase in the speed of the cooling air, the heat transfer of the portion to be cooled is increased, and the cooling efficiency can be improved. Therefore, the thermoelectric generator of the present invention can make the temperature difference between the heated part and the cooled part of the thermoelectric conversion unit larger, and can collect more electric power.

Since the exhaust force of the exhaust means is used to increase the flow rate of the cooling air passing through the cooling air passage, it is not necessary to use electric power unlike a cooling fan. Therefore, the thermoelectric generator of the present invention can efficiently recover generated power.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the thermoelectric generator of the present invention will be described below. (Embodiment 1) The thermoelectric generator of the present embodiment
A thermoelectric conversion unit that is configured using an electric conversion element and includes a heated part and a cooled part, a heated air passage through which heated air that heats the heated part passes, and cooling through which cooling air that cools the cooled part passes In a thermoelectric generator having an air passage, a ventilation pipe is provided which communicates with an air outlet of the cooling air passage and guides the cooling air having passed through the cooling air passage upward.

The thermoelectric conversion unit is constituted by using a thermoelectric conversion element and has a heated portion and a cooled portion. As this thermoelectric conversion unit, a normal type thermoelectric conversion unit in which many thermoelectric conversion elements are connected in series can be used. For example, it is possible to use a thermoelectric conversion unit configured by alternately connecting a large number of P-type thermoelectric conversion elements and N-type thermoelectric conversion elements in series.

The connection of the thermoelectric conversion element is performed by connecting the ends of the thermoelectric conversion element, and the connected end is used as a cooled portion or a heated portion. In the thermoelectric conversion elements connected in series, the connected ends are used alternately as a heated portion and a cooled portion. In this case, the end to be heated is the portion to be heated, and the end to be cooled is the portion to be cooled.
By heating the heated portion in this way and cooling the cooled portion, a temperature difference is provided between the heated portion and the cooled portion,
Generate power.

As the thermoelectric conversion element, a known thermoelectric conversion element can be used. For example, bismuth-tellurium (Bi-T
e), lead-tellurium (Pb-Te), (lead-tin) -tellurium ((Pb-S
n) -Te), iron - silicide (Fe-Si ₂₎ can be used thermoelectric conversion element such.

In the thermoelectric conversion unit, it is necessary to secure a temperature difference between the heated part and the cooled part. Therefore, in order to prevent heat conduction from the heated part of the thermoelectric conversion unit to the cooled part. Generally, a heat insulating wall is provided between the heated portion and the cooled portion. In other words, the thermoelectric conversion element is embedded in the heat insulation wall, and the heated and cooled portions, which are the joined ends of the thermoelectric conversion element, are configured to be exposed from the heat insulation wall. Therefore, the heat insulation wall prevents the air from moving through the inside of the thermoelectric conversion unit. Known materials can be used for the heat insulating material used for the heat insulating wall.

The number of thermoelectric conversion units is not particularly limited, and a plurality of thermoelectric conversion units can be used. If a plurality of thermoelectric conversion units are used, the shape of the thermoelectric conversion unit that can recover a correspondingly large amount of power is not particularly limited, and can be made an appropriate shape. For example, it can be formed in a cylindrical shape. Further, it can be formed in a plate shape. Furthermore, shapes other than these shapes can be adopted.

When the thermoelectric conversion unit has a cylindrical shape,
In general, a cylindrical shape is formed by using a heat insulating material, and the inner peripheral surface of the cylindrical shape is a side where the portion to be cooled is located, and the outer peripheral surface is a side where the portion to be heated is located. However, it is also possible to set the reverse.

When the thermoelectric conversion unit is formed in a plate shape, it is general that one surface is used as a surface on which a portion to be heated is located, and the other surface is a surface on which a portion to be cooled is located. By setting one surface as a heated portion and the other surface as a cooled portion, the heated portion can be efficiently heated and the cooled portion can be cooled.

In any case, the thermoelectric conversion unit is generally formed in a shape such that the surface on which the portion to be heated is located is opposite to the surface on which the portion to be cooled is located. With this configuration, the thermoelectric conversion unit having the heated part and the cooled part, the cooling air passage, and the heated air passage can be efficiently arranged.

The heating air passage is a passage through which heating air for heating the heated portion of the thermoelectric conversion unit passes, and the cooling air passage is a passage through which cooling air cooling the cooled portion of the thermoelectric conversion unit passes. . Therefore, the heated air passage is arranged so that the heated portion of the thermoelectric conversion unit is exposed,
A thermoelectric generator can be configured by arranging a cooling air passage where the cooled portion is exposed.

The heating air passage is not particularly limited as long as it allows the heated air to pass therethrough so as to heat the portion to be heated. Similarly, the cooling air passage passes through the cooling air so as to cool the portion to be cooled. There is no particular limitation as long as it has such a shape.
The heating air passage and the cooling air passage can be appropriately arranged in consideration of the shape of the thermoelectric conversion unit, the positions of the heated portion and the cooled portion, and the like.

For example, when a thermoelectric generator is formed using a cylindrical thermoelectric conversion unit, a duct is used to form a heated air passage through which the heated air passes through the internal space of the duct. A plurality of cylindrical thermoelectric conversion units are arranged so as to penetrate at substantially right angles, and the internal space of the cylindrical thermoelectric conversion unit can be used as a cooling air passage. In this case, the heated portion is located on the outer peripheral surface of the cylindrical thermoelectric conversion unit, and the cooled portion is located on the inner peripheral surface.

In this case, the duct is horizontal, the heating air passage is configured to allow the heating air to pass in the horizontal direction, and the cylindrical thermoelectric conversion units are arranged vertically so that the cooling air passage is arranged in the vertical direction. Is preferred. The temperature of the cooling air rises in the process of passing through the cooling air passage, and is discharged upward.

When a plurality of plate-shaped thermoelectric conversion units are used, the portion to be heated of one thermoelectric conversion unit faces the portion to be heated of another thermoelectric conversion unit.
It is preferable that a plurality of thermoelectric conversion units be arranged in layers so that the cooled portion faces the cooled portion of another thermoelectric conversion unit. When a plurality of plate-shaped thermoelectric conversion units are arranged in layers as described above, a space sandwiched between the surfaces of the thermoelectric conversion units on the side where the heated portion is located is configured as a heated air passage, and The space sandwiched between the surfaces on the side where the portion to be cooled is located can be configured as a cooling air passage.

In this case, a plurality of plate-shaped thermoelectric conversion units are erected vertically and arranged in layers, and horizontal passage walls are provided above and below a space sandwiched by the thermoelectric conversion units, and the upper and lower thermoelectric conversion units are provided. The space surrounded by the horizontal passage wall and the thermoelectric conversion unit is a heated air passage, and vertical passage walls are provided on both sides of the space sandwiched by the thermoelectric conversion units, and the vertical passage walls on both sides and the thermoelectric conversion unit are used. It is preferable that the enclosed space be a cooling air passage.

When the cooling air passage is formed as a passage through which the cooling air passes in the vertical direction, the cooling air enters through the lower passage opening, that is, the air inlet, and is cooled in the process of cooling the cooled portion. As a result, the temperature of the cooling air rises and the cooling air is led upward, passes through the cooling air passage, and exits from the upper air outlet.

As the heated air passing through the heated air passage, high-temperature exhaust gas or the like can be used. The air inlet of the heated air passage communicates with the exhaust duct through which the exhaust air flows, so that the high-temperature exhaust gas can pass through the heated air passage. There is no extra cost if you use the exhaust that is normally dumped into the atmosphere. In this case, the thermoelectric conversion unit can be disposed inside the exhaust duct, and the internal space in the exhaust duct through which the exhaust flows can be used as a heated air passage.

As the cooling air passing through the cooling air passage,
Natural air existing outside the thermoelectric generator, that is, outside air, can be used. Since the temperature of the outside air is lower than that of the above-described exhaust air, it can be used as cooling air for cooling the portion to be cooled. If natural air is used as cooling air, there is no particular cost.

The thermoelectric generator of the present embodiment is characterized in that it has a ventilation pipe communicating with the air outlet of the cooling air passage and leading the cooling air passing through the cooling air passage upward. That is, one port of the ventilation pipe is connected to the cooling air passage so as to communicate with the air outlet of the cooling air passage, and the other port, that is, the air outlet of the ventilation pipe is located at a point higher than the air outlet of the cooling air passage. Can be installed in

The temperature of the cooling air that has passed through the cooling air passage is higher than the temperature of the outside air, and the density of the cooling air is lower than the density of the outside air. It will pass upward and be led out, and can go out through the air outlet of the ventilation tube. That is, the cooling air whose temperature has increased is guided upward by using the ventilation wind generated from the difference between the density of the outside air and the density of the air inside the ventilation pipe.

Compared with the case where natural convection is used in which cooling air simply passes from the bottom to the top without using a ventilation pipe, the speed of the cooling air passing through the cooling air passage increases, and The efficiency of cooling the section has improved.

In this case, the wind power of the ventilation pipe is given by the pressure difference between the bottom of the ventilation pipe and the outside. In this case, the pressure difference between the bottom of the ventilation tube and the outside is determined by the density of the outside air as ρ ₀ (kg /
m ³ ), the density of the cooling air whose temperature has increased through the cooling air passage is ρ (kg / m ³ ), and the height of the ventilation pipe is H
(M), assuming that the gravitational acceleration is g (m / s ² ), it is approximately given by (ρ ₀ −ρ) gH (N / m ² ).

Therefore, the higher the height (H) of the ventilation pipe, the greater the wind power. As a result, if the height of the ventilation tube is increased, it is possible to allow the cooling air to pass at a higher speed than when the cooling fan is forced to pass the cooling air.

As the ventilation pipe, a duct, pipe or the like having two openings and having a hollow inside can be used.
In this case, it is preferable to use a material having heat insulating properties as a material of the ventilation tube. This is because the temperature of the cooling air having an increased temperature existing inside the ventilation pipe is not reduced.

As described above, the thermoelectric generator of the present invention can improve the cooling efficiency of the portion to be cooled by utilizing the wind generated by the ventilation pipe. As a result, the temperature difference between the heated part and the cooled part becomes large, and it becomes possible to recover more electric power.

A discharge pipe through which the heated air that has passed through the heating air passage is led upward is connected to the air outlet of the heating air passage, and the air outlet of the ventilation pipe that leads the cooling air upward is connected to the discharge pipe. Can be opened. The discharge pipe is provided so as to extend upward because the discharge pipe guides the heated air upward. Therefore, the heated air passing through the exhaust pipe extending upward has a density difference from the outside air, and is also led upward using the wind power. The velocity of the heated air is usually higher than the velocity of the cooling air flowing through the ventilation pipe, because the discharge pipe draws out the hot heated air upward.

Accordingly, the cooling air flowing upward through the ventilation pipe for leading out the cooling air also flows upward at a certain speed by using the ventilation wind, but the cooling air is discharged by opening the air outlet of the ventilation pipe to this discharge pipe. The tube will be sucked into the heated air flowing at a high speed, merged with the heated air, and discharged upward. As a result, the speed of the cooling air passing through the cooling air passage is increased, and the cooling efficiency is improved.

Accordingly, the temperature difference between the cooled part and the heated part increases accordingly, and a larger amount of power can be recovered. For this discharge pipe, a heat-resistant ordinary material used for an exhaust duct or the like can be used.

For example, a thermoelectric conversion unit is arranged inside an exhaust duct, an exhaust duct is used as a heating air passage, and an exhaust duct located downstream of the heating air passage is used as an exhaust pipe to extend upward. The air outlet of the ventilation pipe can be opened to an exhaust duct extending upward. (Embodiment 2) The thermoelectric generator of the present embodiment
A thermoelectric conversion unit that is configured using a thermoelectric conversion element and includes a heated portion and a cooled portion, a heated air passage through which heated air that heats the heated portion passes, and cooling through which cooling air that cools the cooled portion passes In a thermoelectric generator having an air passage, an exhaust means that has an exhaust passage through which exhaust gas passes and is used as a heating air passage in the middle thereof, and an exhaust passage downstream of the heating air passage communicating with an air outlet of the cooling air passage. And a ventilation pipe for drawing out cooling air that has passed through the cooling air passage.

The description of the thermoelectric conversion unit is basically the same as that of the first embodiment, and will not be repeated. The description of the heating air passage and the cooling air passage is basically basically the same. Therefore, embodiments of the present invention will be described focusing on different points.

The thermoelectric generator of the present embodiment is different from the thermoelectric generator described in the first embodiment in that an exhaust means having an exhaust passage through which exhaust gas passes and which is used as a heated air passage in the middle thereof, The difference is that an air passage communicating with the air outlet of the air passage and an exhaust passage downstream of the heating air passage is provided with a ventilation pipe for leading out the cooling air passed through the cooling air passage.

The exhaust means having an exhaust passage for passing exhaust gas is not particularly limited as long as it is an exhaust means for discharging high-temperature exhaust gas to the outside and has an exhaust passage for passing exhaust gas. An internal combustion engine such as an engine having an exhaust passage such as a muffler can also be used as the discharging means. By the operation of the internal combustion engine, exhaust gas is forcibly discharged to the outside through the exhaust passage. Further, an exhaust duct such as a chimney which extends high-temperature exhaust gas discharged from an incinerator or a combustion furnace upward and discharges the air into the air can be used as the discharging means.

In the thermoelectric generator of the present embodiment,
The middle of the exhaust passage is used as a heated air passage.
For example, a plurality of plate-shaped thermoelectric conversion units can be arranged in the exhaust passage so that the exhaust gas flowing through the exhaust passage flows into the heated air passage. Alternatively, the cylindrical thermoelectric conversion unit can be arranged so as to penetrate at substantially right angles to the exhaust passage.

By using the exhaust passage as the heating air passage, high-temperature exhaust gas can pass through the heating air passage at a high speed. For example, an exhaust passage of a muffler of an automobile may be used as a heated air passage, and exhaust gas may be forcibly discharged to the outside through the heated air passage by the operation of the engine.

Further, an exhaust duct such as a chimney for discharging high-temperature exhaust gas discharged from an incinerator or a combustion furnace into the sky can be used as an exhaust passage. An exhaust duct such as a chimney that discharges exhaust gas to the sky is also a discharge unit that generates a passing wind due to a density difference between high-temperature exhaust present inside the exhaust duct and the outside air, and discharges the high-temperature exhaust to the sky by the wind. In this case, the exhaust duct only needs to have a height difference between the air inlet and the air outlet of the exhaust duct, and may have a horizontally extending portion. This is because the passing wind generated in the exhaust duct extending upward is generated by a height difference between the air inlet and the air outlet. Therefore, the exhaust duct such as the chimney does not need to be installed vertically, and may be horizontal or oblique on the way. What is necessary is just to install so that a height difference may arise between the air inlet and the air outlet of the exhaust duct.

In the thermoelectric generator of this embodiment,
The ventilation pipe can be arranged so as to communicate with the air outlet of the cooling air passage and open to the exhaust passage downstream of the heating air passage. In other words, one port of the ventilation pipe may be connected to the cooling air passage so as to communicate with the air outlet of the cooling air passage, and the other port may be opened to the downstream exhaust passage.

The exhaust gas flowing through the exhaust passage is forcibly discharged at a high speed through the exhaust passage. The cooling air that has passed through the cooling air passage is drawn into the exhaust gas that flows through the exhaust passage at high speed through the ventilation pipe and merges. Therefore, the cooling air passing through the cooling air passage is forcibly discharged together with the exhaust gas passing through the exhaust passage.

As described above, the thermoelectric generator according to the present embodiment utilizes the exhaust force of the exhaust means to allow the cooling air to pass through the cooling air passage at a higher speed, thereby improving the cooling efficiency. Therefore, the temperature difference between the cooled portion and the heated portion increases accordingly, and more power can be recovered.

[0057]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the thermoelectric generator of the present invention will be described below with reference to the drawings. (Embodiment 1) A thermoelectric conversion device according to Embodiment 1 is configured using a thermoelectric conversion element and includes a thermoelectric conversion unit including a heated portion and a cooled portion, and heated air through which heated air for heating the heated portion passes. A cooling air passage through which the cooling air for cooling the portion to be cooled passes from below to above, and which communicates with an air outlet of the cooling air passage to lead the cooling air passing through the cooling air passage upward; It is characterized by having a ventilation tube.

FIG. 1 is a view schematically showing a thermoelectric converter according to Embodiment 1, and FIG. 2 is a view schematically showing a part of a cross section taken along line AA in FIG.

In the thermoelectric generator 100 of the present embodiment, the thermoelectric conversion unit 10 has a rectangular plate shape, and the cooling target 13 and the cooling target 13 face each other with the cooling air passage 30 interposed therebetween. A plurality of thermoelectric conversion units 10 are vertically arranged in layers so that the heated portions 12 face each other with the air passage 20 interposed therebetween. The thermoelectric conversion unit 10 has a heat insulating wall 14 for preventing heat transfer between the heated part 12 and the cooled part 13. The thermoelectric conversion element 11 is embedded in the heat insulation wall 14, and the heated part 12 and the cooled part 13, which are the joined ends of the thermoelectric conversion element 11, are configured to be exposed from the heat insulation wall 14.

A horizontal passage wall 21 is provided above and below the space sandwiched by the plate-like thermoelectric conversion units 10 which are vertically arranged in layers, and the upper and lower horizontal passage walls 21 are connected to the thermoelectric conversion unit. The space surrounded by the unit 10 is
And The heated air passage 20 is provided in the middle of the exhaust duct 60, and is configured so that heated air passes in the horizontal direction.

Further, a vertical passage wall (not shown) is provided on both sides of the space sandwiched by the thermoelectric conversion units 10, and the space surrounded by the vertical passage walls on both sides and the thermoelectric conversion unit 10 is formed into a cooling air passage 30. The cooling air is configured to pass upward from below.

The portion composed of the plurality of plate-like thermoelectric conversion units 10, the cooling air passages 30 and the heating air passages 20 of this embodiment is collectively called a unit portion 40. Accordingly, the air inlet (not shown) of the cooling air passage 30 is provided on the lower surface of the unit 40 in FIG. 1, and the air outlet 31 of the cooling air passage is provided on the upper surface of the unit 40.

The ventilation tube 50 is disposed vertically on the upper surface of the unit 40, and the lower end of the ventilation tube 50 is
It is open to the upper surface of. The ventilation pipe 50 extends vertically upward, and the upper end is an air outlet 51.

Exhaust gas passing through exhaust duct 60 (heated air)
Flows from the right hand to the left hand direction in FIG. 1, passes through the heating air passage 20 of the thermoelectric generator 100 on the way, and
Heat. The exhaust gas that has passed through the heated air passage 20 passes through the exhaust duct 60 and is discharged to the outside.

As the cooling air passing through the cooling air passage 30, natural outside air is used. The cooling air that has entered the cooling air passage 30 from an air inlet (not shown) opened below the unit 40 is cooled by the cooling target 1 in the process of cooling the cooling target 13.
3 receives heat conduction. As a result, the cooling air rises in temperature and is guided upward, passes through the cooling air passage 30, passes through the air outlet 31, and enters the ventilation pipe 50. Cooling air passage 30
The temperature of the cooling air passing through rises above the temperature of the outside air,
Since the density of the cooling air is smaller than the density of the outside air, the cooling air is guided upward inside the ventilation pipe 50,
The air is discharged outside from the air outlet 51 of the ventilation pipe 50.

As described above, the thermoelectric generator of the present embodiment can improve the cooling efficiency of the portion to be cooled by utilizing the wind generated by the ventilation pipe. As a result, the temperature difference between the heated part and the cooled part becomes large, and it becomes possible to efficiently collect a larger amount of power.

In this way, the temperature difference between the heated part and the cooled part is greater than in the case of the conventional thermoelectric generator in which the cooling air is simply passed from the bottom to the top without using the ventilation pipe. Can be increased.

Further, in the case of a thermoelectric generator using a cooling fan, the temperature difference between the heated portion and the cooled portion can be increased, but power for operating the cooling fan is required, and power recovery efficiency is accordingly reduced. Will decrease. However, since power for operating the cooling fan of the present embodiment is not required, the power recovery efficiency is improved accordingly.

(Embodiment 2) The thermoelectric generator of Embodiment 2
A thermoelectric conversion unit that is configured using a thermoelectric conversion element and includes a heated part and a cooled part, a heated air passage through which heated air that heats the heated part passes, and cooling air that cools the cooled part is from above to below. A cooling air passage that passes through the cooling air passage, and communicates with an air outlet of the heating air passage that communicates with an air outlet of the cooling air passage and leads cooling air that has passed through the cooling air passage upward. And a discharge pipe for guiding heated air that has passed through the heated air passage upward, and an air outlet of the ventilation pipe is open to the discharge pipe.

This discharge pipe is constituted by using a part of an exhaust duct having an exhaust passage for discharging exhaust gas from a combustion furnace through a heated air passage and discharging it to the sky. The exhaust duct extends upward so that exhaust gas from the combustion furnace passes through the heated air passage, and the exhaust gas that has passed through is exhausted upward.

FIG. 2 is a schematic diagram of a thermoelectric generator 200 according to the second embodiment. The thermoelectric conversion unit, the heating air passage, and the cooling air passage are collectively shown as a unit 110, and the thermoelectric conversion unit, the heating air passage, and the like. The cooling air passage is not shown.

In this embodiment, the unit section 110 is disposed in the middle of an exhaust duct 120 for discharging exhaust gas from the combustion furnace 140 upward. The heated exhaust gas discharged from the combustion furnace 140 passes through the internal space of the exhaust duct 120 and is discharged to the outside, but passes through the heated air passage of the unit 110 on the way. This exhaust duct 1
Numeral 20 extends upward downstream of the unit 110 and discharges exhaust gas that has passed through the heated air passage of the unit 110 to the sky. Since the exhaust duct 120 extends upward, the exhaust gas flowing through the exhaust duct 120 is discharged upward at a high speed by utilizing the wind power.

Further, in this embodiment, the ventilation pipe 130 for leading the cooling air passing through the cooling air passage upwardly is opened to the exhaust duct 120 downstream of the unit 110, and the cooling air passing through the cooling air passage is opened. Air exhaust duct 12
0 is derived. Cooling air is in unit 1
10 enters the cooling air passage, passes through the cooling air passage, and enters the ventilation pipe 130. The cooling air passes upward through the ventilation pipe, is taken into the exhaust duct 120, and joins the exhaust flowing through the exhaust duct 120. Since the exhaust duct 120 extends upward, the cooling air heated by passing through the cooling air passage flows upward by using the passing wind, but the cooling air merges with the exhaust flowing at a high speed and the high speed. Will flow upward.

In the present embodiment, it is possible to prevent the cooling air from flowing at a high speed and cooling the portion to be cooled too much, so that the portion to be heated is also cooled and the power recovery efficiency is reduced. In order to do so, it is possible to provide a ventilation adjusting valve (not shown) for adjusting the ventilation wind in the middle of the ventilation pipe 130.

In this embodiment, the ventilation pipe extends upward. However, since the cooling air is discharged by joining the exhaust gas flowing through the exhaust duct at a high speed, the ventilation pipe itself does not necessarily need to extend upward. . The ventilation pipe can be attached in consideration of the exhaust power of the exhaust gas flowing through the exhaust duct.

The thermoelectric generator of the present invention is not limited to the above embodiment, but can be variously modified within the scope of the invention described in the claims.

[0077]

According to the thermoelectric generator of the present invention, the cooled portion of the thermoelectric conversion unit can be cooled without requiring extra power, and as a result, the temperature difference between the cooled portion and the heated portion is reduced. Can be made larger, and larger electric power can be efficiently collected.

[Brief description of the drawings]

FIG. 1 is a diagram schematically illustrating a thermoelectric generator according to a first embodiment.

FIG. 2 is a diagram schematically showing a part of a cross section taken along line AA of FIG. 1;

FIG. 3 is a diagram schematically illustrating a thermoelectric generator according to a second embodiment.

[Explanation of symbols]

 10: Thermoelectric conversion unit 11: Thermoelectric conversion element 12: Heated portion 13: Cooled portion 14: Insulated wall 20: Heated air passage 21: Passage wall 30: Cooling air passage 31: Air outlet 40: Unit portion 50: Ventilation tube 51: Air outlet 60: Exhaust duct 100: Thermoelectric converter 110: Unit part 120: Exhaust duct 130: Ventilation tube 140: Combustion furnace 200: Thermoelectric generator

Claims (9)

[Claims] 1. A thermoelectric conversion unit comprising a thermoelectric conversion element, comprising a heated portion and a cooled portion, a heated air passage through which heated air for heating the heated portion passes, and cooling the cooled portion. A cooling air passage through which the cooling air passes.The thermoelectric generator has a ventilation pipe that communicates with an air outlet of the cooling air passage and leads the cooling air that has passed through the cooling air passage upward. Thermoelectric generator. 2. The thermoelectric generator according to claim 1, wherein the thermoelectric conversion unit has a cylindrical shape. 3. The thermoelectric conversion unit has a plate shape, and the cooled portion and the cooled portion face each other with the cooling air passage interposed therebetween, and the thermoelectric conversion unit and the heated portion are sandwiched with the heated air passage interposed therebetween. 2. The thermoelectric generator according to claim 1, wherein a plurality of the thermoelectric conversion units are arranged in a layer so as to face the portion to be heated. 3. 4. The thermoelectric generator according to claim 1, wherein the cooling air passage is configured to allow cooling air to pass upward from below. 5. An exhaust pipe which communicates with an air outlet of the heating air passage to lead out heated air passing through the heating air passage upward, wherein the air outlet of the ventilation pipe is opened to the exhaust pipe. The thermoelectric generator according to claim 4. 6. A thermoelectric conversion unit comprising a thermoelectric conversion element, comprising a heated portion and a cooled portion, a heated air passage through which heated air for heating the heated portion passes, and cooling the cooled portion. A thermoelectric generator having a cooling air passage through which cooling air passes, comprising: an exhaust unit having an exhaust passage through which exhaust gas is passed and the middle of which is used as the heating air passage; and a cooling air passage communicating with an air outlet of the cooling air passage. A thermoelectric generator including a ventilation pipe for leading cooling air passing through the cooling air passage to the exhaust passage downstream of the heating air passage. 7. The thermoelectric generator according to claim 6, wherein the thermoelectric conversion unit has a cylindrical shape. 8. The thermoelectric conversion unit has a plate shape, and the cooled portion and the cooled portion face each other with the cooling air passage interposed therebetween. 7. The thermoelectric generator according to claim 6, wherein a plurality of the thermoelectric conversion units are arranged in a layer so that the heated unit faces each other. 9. An exhaust duct having an exhaust passage which extends upward and exhausts exhaust gas upward.
9. The thermoelectric generator according to 7 or 8.