JPH07166957A - Stirling engine - Google Patents

Abstract

PURPOSE:To enhance heat collection efficiency by using a heat pipe type solar heat collecting device as a heat source device. CONSTITUTION:A fan-shaped displacer piston 2 is provided and a low- temperature side displacer chamber 22 and a high-temperature side displacer chamber 21 are provided respectively on the upper and lower sides of the displacer piston 2. A water jacket 5 into which cooling water is introduced is provided on the side of the low-temperature side displacer chamber 22. A heat source device 1 comprising a heat pipe type solar heat collecting device for raising the temperature of a heating medium is provided on the side of the high- temperature side displacer chamber 21. The heat pipe type solar heat collecting device comprises a doubled vacuum glass pipe 11, a heat pipe 12 the major part of which is enclosed in the doubled vacuum glass pipe 11, and a heat exchanging chamber 25 provided between a regenerative heat exchanger 4 and the high-temperature side displacer chamber 21. The heat pipe 12 comprises a heat receiving portion 122 enclosed in the doubled vacuum glass pipe and a heat releasing portion (heat sink) 121 consisting of a plurality of fins 123 enclosed in the heat exchanging chamber 25.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a Stirling engine, and more particularly to a heat source device including a double vacuum glass pipe and a heat pipe housed in the double vacuum glass pipe. The present invention relates to a Stirling engine that employs a pipe-type solar heat collector and has a water-cooling type cooling device in which a water jacket into which cooling water is introduced is provided on the low temperature side.

[0002]

2. Description of the Related Art A conventional Stirling engine, in particular, a type that utilizes solar heat for a heat source device, has a condenser lens or the like on a cylinder head portion forming the heat source device, as disclosed in, for example, JP-A-64-36952. Is mainly used to concentrate the solar heat and heat the working gas (heat medium).

[0003]

By the way, in the Stirling engine, in order to increase the efficiency as a heat engine, the temperature (T) on the high temperature side that gives heat to the working gas is increased.
The larger the value of the temperature difference (T−T ₀ ) between the temperature of the working gas and the temperature (T ₀ ) on the low temperature side for cooling the working gas, the better. However, in the conventional heat source device using the condensing lens system, due to the area of the cylinder head, etc.,
There is a limit to the amount of solar thermal energy that can be collected in a unit of time. SUMMARY OF THE INVENTION It is an object (problem) of the present invention to provide a solar heat collecting type Stirling engine having an excellent heat collecting efficiency, which solves the problems related to the solar heat energy collecting ability.

[0004]

In order to solve the above problems, the present invention takes the following measures. That is, regarding a Stirling engine having a solar heat collector as a heat source device, it has a high-temperature side displacer chamber and a low-temperature side displacer chamber formed by displacer pistons, and a heat medium (working gas) that reciprocates between these displacer chambers is generated. A water jacket containing cooling water for cooling is provided on the low temperature side displacer chamber side, and a heat source device is connected to the high temperature side displacer chamber into which a high temperature heat medium (working gas) is introduced. Between the low temperature side displacer chamber and the low temperature side displacer chamber, a regenerative heat exchanger for preheating a low temperature heat medium (working gas) flowing from the low temperature side displacer chamber is adopted, and the heat source device is also provided. And a plurality of double type vacuum glass pipes, and the heat receiving part is housed in the double type vacuum glass pipes. , The heat radiation member was thereby formed at the heat collecting apparatus comprising a heat pipe is accommodated in the heat exchange chamber connected to the hot side displacer chamber.

[0005]

By adopting the above construction, the following effects are exhibited in the present invention. First, in FIG. 1, when the flywheel 6 is rotated as shown by the arrow A, the connecting link 67 connected to the flywheel 6 via the crank 61 moves upward, and the connecting link 67 and O _{76 are connected.} The yoke 7, which is connected at a point, performs a swinging motion about its mounting point O ₇ . As a result, the fork portion 7 of the yoke 7 concerned
The displacer piston 2 starts a swinging motion downward with the attachment point O ₂ as a fulcrum via the pin 29 engaged with the pin 1. By the downward swing motion of the displacer piston 2, the heat medium such as helium gas contained in the high temperature side displacer chamber 21 is pushed downward, and the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1 is pushed. Sent to. Then, the heat medium introduced into the heat exchange chamber 25 is radiated in the heat exchange chamber 25 by the heat radiating portion (heat sink) 1 of the heat pipe 12 forming the solar heat collecting device.
It is heated (heated) to a high temperature by receiving heat from 21.

On the other hand, with the above operation, the connecting rod 86 connected to the flywheel 6 through the crank 61 also moves in the left-right direction as shown by the arrow in FIG. The movement of the connecting rod 86 in the left-right direction is transmitted via the bell crank 8 to the power piston 3
And the power piston 3 moves downward.
Due to the downward movement of the power piston 3, the low-temperature heat medium stored in the space 33 between the power piston 3 and the airtight bellows 31 is cooled by the low-temperature side distributor chamber 2
2 is extruded.

From the above state, the flywheel 6 further makes a rotary motion, and the displacer piston 2 operates,
When the heat medium in the high temperature side displacer chamber 21 is moved to the position of the bottom dead center, most of the heat medium in the high temperature side displacer chamber 21 is activated by the operation of the displacer piston 2.
1 is discharged into the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1 (discharging process). And here,
The heat medium is warmed by the heat sink (heat radiation part) 121 of the heat pipe 12 which is warmed by receiving the solar heat. At the same time, the heated heat medium is sent to the regenerative heat exchanger 4 via the heat exchange chamber 25,
The regenerative heat exchanger 4 is warmed (heated).

When the displacer piston 2 reaches the position of the bottom dead center in this way, next, the high temperature side displacer chamber 21 is connected to the heat exchange chamber 25 side of the heat source device (solar heat collecting device) 1. A high temperature heat medium is introduced from the heat medium, and the heat medium expands. As a result, the displacer piston 2 is pushed upward (expansion stroke).

At the same time, the yoke 7, connecting link 67, and
The power piston 3, which is connected via the connecting rod 86 and the bell crank 8, is also pushed upward.
In the latter half of the upward swinging motion of the displacer piston 2, the power piston 3 moves downward, and the displacer piston 2 and the power piston 3 jointly operate in the low temperature side displacer chamber 22. The low-temperature heat medium stored in is sent to the regenerative heat exchanger 4 side. Here, the heat medium in the low temperature state is warmed (preheated) by the regenerative heat exchanger 4 which has already been heated by the high temperature heat medium from the heat source device (solar heat collecting device) 1 in the previous discharge stroke. , To the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1. The heat medium preheated in the regenerative heat exchanger 4 is heated in the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1 by the heat of the heat pipe 1
The heat is further heated by the heat radiating section (heat sink) 121 of No. 2 and is supplied into the high temperature side displacer chamber 21 to contribute to the expansion stroke.

As described above, the heat medium is reciprocally moved between the high temperature side displacer chamber 21 and the low temperature side displacer chamber 22 by the interaction between the displacer piston 2 and the power piston 3 in the state where the phase difference is 90 °. Moreover, during that time, the heat source device (solar heat collecting device) 1 and the regenerative heat exchanger 4 are used to exert a recuperative action on the heat medium, whereby power is supplied from the power piston 3 and the flywheel 6 side. It is supposed to be taken out (outputted).

In such an operation, the heat source device 1 formed by the solar heat collecting device has an existing double type vacuum glass pipe 11 and the double type vacuum glass, as shown in FIGS. 1 to 3. The heat receiving part 122 is housed in the pipe 11, and the heat dissipation part 121 is composed of the heat pipe 12 housed in the heat exchange chamber 25 connected to the high temperature side displacer chamber 21. The heat medium introduced into the side displacer chamber 21 is
Due to the heat exchange action with the heat sink (heat dissipation part) 121 including the plurality of fins 123 installed in the heat exchange chamber 25, the heat can be quickly and uniformly warmed to a high temperature state. Further, as shown in FIG. 3, a plurality of double-type vacuum glass pipes 11 having such a configuration are arranged in parallel and surrounded by a reflector 91 via a stand 95. Since it is configured to face the sun, the heat collection efficiency of solar heat will be greatly enhanced. Therefore, the heat medium introduced into the high temperature side displacer chamber 21 is sent at a high temperature (T).

On the other hand, since the water jacket 5 into which the cooling water supplied by the water pump 51 is introduced is provided on the low temperature side displacer chamber 22 side, the heat medium accommodated on the low temperature side displacer chamber 22 side is provided. Is cooled by the cooling water and is kept at a low temperature (T ₀ ). For these reasons, in the present invention, so that the value of the temperature difference of the heat medium (T-T ₀₎ is maintained in a large state. As a result, in the Stirling engine of the present invention, high output and high efficiency can be obtained.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment of the present invention will be described with reference to FIGS. The configuration of the present embodiment relates to a Stirling engine having a fan-shaped displacer piston 2 as shown in FIG. 1, and a high temperature side displacer chamber 21 formed by the displacer piston 2 is provided.
And a low temperature side displacer chamber 22, a water jacket 5 for cooling a heat medium, such as helium gas, introduced into the low temperature side displacer chamber 22 on the low temperature side displacer chamber 22, and the high temperature side displacer chamber. Heat source device 1 comprising a heat pipe type solar heat collecting device for warming (heating) a heat medium introduced into 21.
With the regenerative heat exchanger 4 preheating the low temperature heat medium flowing from the low temperature side displacer chamber 22 and the phase difference of 90 ° between the displacer piston 2 and the power piston 3, The link mechanism for actuating the displacer piston 2 and the power piston 3, and further a flywheel 6 are basically used.

In such a basic structure, the fan-shaped displacer piston 2, the power piston 3 which operates in a state having a 90 ° phase difference with the displacer piston 2, and the relative movement so as to have a phase difference of 90 ° between them. The link mechanism for transmission, the flywheel 6, the high temperature side displacer chamber 21 and the low temperature side displacer chamber 2 formed by the fan-shaped displacer piston 2 described above.
2. Regenerative heat exchanger 4 for preheating the low temperature heat medium (helium gas) from the low temperature side displacer chamber 22.
Is a known one.

In such a basic structure, low temperature cooling water is supplied to the water jacket 5 provided on the low temperature side displacer chamber 22 side by the water pump 51 or the like. Such a low temperature heat medium (helium gas) in the low temperature side displacer chamber 22
To the regenerative heat exchanger 4, the power piston 3 having a cone shape has a base portion having a phase difference of 90 ° with respect to the displacer piston 2. It is connected to a bell crank 8 which is a part of a link mechanism which is connected to operate. A flywheel 6 for smoothly taking out the output from the power piston 3 or the like is provided in a part of the link mechanism formed to have the phase difference of 90 °.

The center of rotation O of the flywheel 6
Crank 6 is coaxial with the flywheel 6 at ₆ points.
1, a crank rod 61 is provided at a tip O _{61 of the} crank 61, and a connecting rod 86 connected to a bell crank 8 for operating the power piston 3 and a yoke 7 for operating the displacer piston 2 are provided.
The connecting links 67 connected to each are rotatably connected. Further, a generator 99 is coaxially connected to the centers of the crank 61 and the flywheel 6 as shown in FIG. 3, and receives the output from the Stirling engine to exert a power generating function. There is. An airtight bellows 31 is provided on the outer side of the power piston 3 so that a space 33 continuous with the low temperature side displacer chamber 22 is formed. By operating the power piston 3 and the airtight bellows 31, the heat medium (helium gas) existing in the low temperature side displacer chamber 22 can be sent to the regenerative heat exchanger 4 side. That is, it functions as a pump.

Next, the heat source device 1 for sending out a high temperature heat medium (helium gas) to the high temperature side displacer chamber 21.
1 is formed by a solar heat collector based on the double type vacuum glass pipe 11, as shown in FIG. In the solar heat collecting apparatus 1, a plurality of the double type vacuum glass pipes 11 are lined up in parallel as shown in FIG. 3, and the surroundings thereof are surrounded by the reflector 91. The one having such a configuration is configured to be installed (set) on the stand 95 so as to face the direction of the sun.

In the solar heat collecting apparatus 1 having such a structure, as shown in FIG. 1, the double vacuum glass pipe 11 and the heat pipe 12 housed in the double vacuum glass pipe 11 are provided. A heat exchange chamber 25, which is located between the high temperature side displacer chamber 21 and the regenerative heat exchanger 4, and in which the heat dissipation portion 121 of the heat pipe 12 is housed;
It is basically composed of The heat pipe 12 has a decompressed interior, and a heat medium such as freon, ammonia, or water, which easily evaporates, is enclosed in the interior of the heat pipe 12. In addition,
A medium having high thermal conductivity such as castor oil is enclosed in the double-type vacuum glass pipe 11 in which the heat pipe 12 is housed, and the double-type vacuum glass pipe is inserted through this medium. The solar heat energy selectively absorbed in 11 is transmitted to the heat medium in the heat pipe 12.

As shown in FIG. 1, the heat pipe 12 having such a structure is a main body part, and the heat receiving portion 122 is housed in the double type vacuum glass pipe 11.
And a heat radiating portion 121 for radiating the solar heat collected by the heat receiving portion 122. Of these, the heat dissipation part 121 forms a heat sink composed of a plurality of fins 123, and the heat sink (heat dissipation part) 121 is disposed between the regenerative heat exchanger 4 and the high temperature side displacer chamber 21. It is configured to be installed in the heat exchange chamber 25 formed so as to be connected to each other.

The heat pipe 12 having the above structure
And an O-ring 15 for enclosing the medium such as the castor oil, between the heat pipe 12 and the double-type vacuum glass pipe 11 housed therein. Where the pipe 11 is connected to the heat exchange chamber 25, a heat insulating material 19 made of silicone rubber or the like is provided.

As the heat source device 1 having these configurations, a flat type device as shown in FIG. 2 is also conceivable. This is configured such that the double-type vacuum glass pipe 11 forming the heat source device 1 is installed in a horizontal state, and the Stirling engine itself can be put together in a flat and compact form. You can do it.

The operation mode and the like of this embodiment having the above-mentioned configuration will be described. First, in FIG. 1, when the flywheel 6 is rotated as shown by the arrow A, the connecting link 67 connected to the flywheel 6 via the crank 61 moves upward, and the connecting link 67 and O _{76 are connected.} The yoke 7 connected at the points
An oscillating motion is performed around the attachment point O ₇ . As a result, the displacer piston 2 starts a downward swinging motion with the attachment point O ₂ as a fulcrum via the pin 29 engaged with the fork portion 71 of the yoke 7. Due to the downward swinging motion of the displacer piston 2, the heat medium such as helium gas stored in the high temperature side displacer chamber 21 is pushed downward, and the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1 is pushed. Sent to. Then, the heat medium (helium gas) introduced into the heat exchange chamber 25 is radiated in the heat exchange chamber 25 by the heat radiating portion (heat sink) 12 of the heat pipe 12 forming the solar heat collecting device.
It is heated (heated) to a high temperature by receiving heat from 1.

On the other hand, along with the above operation, the connecting rod 86 connected to the flywheel 6 via the crank 61 also moves in the left-right direction as shown by the arrow in FIG. The movement of the connecting rod 86 in the left-right direction is transmitted via the bell crank 8 to the power piston 3
And the power piston 3 moves downward.
By the downward movement of the power piston 3, the low temperature heat medium (helium gas) contained in the space 33 between the power piston 3 and the airtight bellows 31 is pushed out into the low temperature side displacer chamber 22.

From the above state, the flywheel 6 further makes a rotary motion, and the displacer piston 2 operates,
When the heat medium in the high temperature side displacer chamber 21 is moved to the position of the bottom dead center, most of the heat medium in the high temperature side displacer chamber 21 is activated by the operation of the displacer piston 2.
1 is discharged into the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1 (discharging process). And here,
The heat medium is warmed by the heat sink (heat radiation part) 121 of the heat pipe 12 which is warmed by receiving the solar heat. At the same time, the heated heat medium is sent to the regenerative heat exchanger 4 via the heat exchange chamber 25,
The regenerative heat exchanger 4 is warmed (heated).

In this way, when the displacer piston 2 reaches the position of the bottom dead center, next, the high temperature side displacer chamber 21 is connected to the heat exchange chamber 25 side of the heat source device (solar heat collecting device) 1. A high temperature heat medium is introduced from the heat medium, and the heat medium expands. As a result, the displacer piston 2 is pushed upward (expansion stroke).

At the same time, the displacer piston 2 is provided with a yoke 7, a connecting link 67,
The power piston 3, which is connected via the connecting rod 86 and the bell crank 8, is also pushed upward.
In the latter half of the upward swinging motion of the displacer piston 2, the power piston 3 moves downward, and the displacer piston 2 and the power piston 3 jointly operate in the low temperature side displacer chamber 22. The low-temperature heat medium stored in is sent to the regenerative heat exchanger 4 side. Here, the heat medium in the low temperature state is warmed (preheated) by the regenerative heat exchanger 4 which has already been heated by the high temperature heat medium from the heat source device (solar heat collecting device) 1 in the previous discharge stroke. , To the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1. The heat medium preheated in the regenerative heat exchanger 4 is heated in the heat exchange chamber 25 of the heat source device (solar heat collecting device) 1 by the heat of the heat pipe 1
The heat is further heated by the heat radiating section (heat sink) 121 of No. 2 and is supplied into the high temperature side displacer chamber 21 to contribute to the expansion stroke.

As described above, the heat medium is reciprocally moved between the high temperature side displacer chamber 21 and the low temperature side displacer chamber 22 by the interaction between the displacer piston 2 and the power piston 3 in the state where the phase difference is 90 °. Moreover, during that time, the heat source device (solar heat collecting device) 1 and the regenerative heat exchanger 4 are used to exert a recuperative action on the heat medium, whereby power is supplied from the power piston 3 and the flywheel 6 side. It is supposed to be taken out (outputted).

In such an operation, the heat source device 1 formed by the solar heat collecting device has an existing double type vacuum glass pipe 11 and the double type vacuum glass, as shown in FIGS. 1 to 3. The heat receiving part 122 is housed in the pipe 11, and the heat dissipation part 121 is composed of the heat pipe 12 housed in the heat exchange chamber 25 connected to the high temperature side displacer chamber 21. The heat medium introduced into the side displacer chamber 21 is
Due to the heat exchange action with the heat sink 121 composed of the plurality of fins 123 installed in the heat exchange chamber 25,
It can be quickly and uniformly warmed to a high temperature. Further, as shown in FIG. 3, a plurality of double-type vacuum glass pipes 11 having such a configuration are lined up in parallel and surrounded by a reflector 91 via a stand 95. Therefore, the heat collection efficiency of the solar heat is greatly enhanced because it is configured to be directed toward the sun. Therefore, the heat medium introduced into the high temperature side displacer chamber 21 is sent at a high temperature (T).

Further, in the present embodiment, the volume of the heat exchange chamber 25, which acts to apply heat energy to the heat medium introduced into the high temperature side displacer chamber 21, is set to the volume of both displacer chambers 21 and 22. In comparison, it is a very small value. Therefore, the heat exchange action with the heat sink 121 performed in the heat exchange chamber 25 is performed quickly. That is, in this embodiment, the heat exchange action is performed in a state where the heat receiving efficiency is very high.

On the other hand, since the water jacket 5 into which the cooling water supplied by the water pump 51 is introduced is provided on the low temperature side displacer chamber 22 side, the heat medium accommodated on the low temperature side displacer chamber 22 side is provided. Is cooled by the cooling water and is kept at a low temperature (T ₀ ). From these facts, in this embodiment, so that the value of the temperature difference of the heat medium (T-T ₀₎ is maintained in a large state. As a result, in the Stirling engine of this embodiment, high output and high efficiency can be obtained.

[0031]

According to the present invention, a Stirling engine having a solar heat collector as a heat source device has a high temperature side displacer chamber and a low temperature side displacer chamber formed by a displacer piston, and reciprocates between these displacer chambers. A water jacket containing cooling water for cooling the flowing heat medium (working gas) is provided on the low temperature side displacer chamber side, and a heat source device is installed in the high temperature side displacer chamber into which the high temperature heat medium (working gas) is introduced. And a regenerative heat exchanger for preheating a low temperature heat medium (working gas) flowing from the low temperature side displacer chamber, between the heat source device and the low temperature side displacer chamber. The above heat source device is received in a plurality of double type vacuum glass pipes and in the double type vacuum glass pipes. Part is housed and the heat dissipation part is formed by a solar heat collecting device consisting of a heat pipe housed in a heat exchange chamber connected to the high temperature side displacer chamber. The (heat medium) is heated (heated) quickly and uniformly by the heat sink housed in the heat exchange chamber. That is, the heat medium introduced into the high temperature side displacer chamber of the present Stirling engine is kept in the high temperature state (T). On the other hand, the heat medium (working gas) in the low temperature side displacer chamber is maintained in a low temperature state (T ₀ ) by the water-cooled water jacket, and the temperature difference (T-T ₀ ) of the heat medium (working gas) is maintained. It is now possible to secure a large value for. As a result, in the Stirling engine of the present invention, higher output and higher efficiency can be achieved. In addition, the solar heat collector (heat source device) is formed by arranging multiple double-type vacuum glass pipes in parallel, so the heat source device is made flat and the Stirling engine itself is small. It has become possible to reduce the size and weight.

[Brief description of drawings]

FIG. 1 is a skeleton structure diagram showing an overall configuration of the present invention.

FIG. 2 is a skeleton structure diagram showing an overall configuration of another embodiment when the heat source device is installed in a horizontal state.

FIG. 3 is a perspective view showing the overall configuration of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Heat source device (solar heat collecting device) 11 Double type vacuum glass pipe 12 Heat pipe 121 Heat dissipation part (heat sink) 122 Heat receiving part 123 Fin 15 O-ring 19 Insulating material 2 Displacer piston 21 High temperature side displacer chamber 22 Low temperature side displacer chamber 25 Heat exchange chamber 29 pin 3 Power piston 31 Airtight bellows 33 Space 4 Regenerative heat exchanger 5 Water jacket 51 Water pump 6 Flywheel 61 Crank 67 Connecting link 7 Yoke 71 Fork part 8 Bell crank 86 Connecting rod 91 Reflector 95 Stand 99 Power generation Machine

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Reference number within the agency FI Technical display area F02G 1/055 G F03G 6/00 521 F24J 2/04 2/32 2/42 Z F28D 15/02 X

Claims (1)

[Claims] 1. A Stirling engine using a solar heat collecting device as a heat source device, which has a high-temperature side displacer chamber and a low-temperature side displacer chamber formed by displacer pistons, and a heat medium (reciprocating flow between these displacer chambers) Has a water jacket containing cooling water for cooling gas) on the low temperature side displacer chamber side, and a heat source device is connected to the high temperature side displacer chamber into which a high temperature heat medium (working gas) is introduced.
Between the heat source device and the low temperature side displacer chamber, there is a regenerative heat exchanger that preheats the low temperature heat medium (working gas) flowing from the low temperature side displacer chamber, and the heat source device is a dual Type vacuum glass pipe and a heat pipe in which a heat receiving part is housed in the double type vacuum glass pipe and a heat radiating part is housed in a heat exchange chamber connected to the high temperature side displacer chamber. A Stirling engine, which is characterized by being configured to be formed as follows.