JP4947195B2 - Heat engine - Google Patents

Description

  The present invention relates to a heat engine that heats and evaporates a working fluid, extracts the evaporated steam energy as mechanical energy, and then condenses and returns the steam, and is suitable for use in an exhaust heat recovery apparatus.

  Conventionally, this type of heat engine has a high pressure in the evaporation section (evaporation chamber) that evaporates the working fluid, whereas the condensing section that condenses (condensates) the steam has a low pressure. In general, a device such as a pump is used to return the liquid to the evaporation section (for example, Patent Document 1). That is, by driving a device such as a pump using external energy, the working fluid in the condensing unit is pumped and returned to the evaporating unit.

JP-A-8-338207

  In the heat engine that returns the working fluid condensed in the condensing unit to the evaporation chamber by a mechanism such as a pump as in the above prior art, a device such as a pump in addition to external energy (heat energy) that heats and evaporates the working fluid Since external energy for driving the power source is also required, there is a limit to improving the output efficiency.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a heat engine capable of returning hydraulic fluid condensed in a condensing unit to a high-pressure evaporation chamber without using external energy as much as possible. And

In order to achieve the above object, according to the first aspect of the present invention, in the evaporation chamber (156), the working fluid (14) is heated by the heat supplied from the external heat source (3) to generate the vapor of the working fluid (14). 308), and a boiler section (11) in which liquid reservoir chambers (157a, 309a) for storing hydraulic fluid (14) supplied to the evaporation chambers (156, 308) are formed;
An output section (12) through which steam generated in the evaporation chamber (156, 308) flows, converts the steam energy into mechanical energy, and takes it out;
A condensing unit (13) for condensing the vapor that has passed through the output unit (12) and returning the condensed working fluid (14) to the liquid storage chambers (157a, 309a);
A hydraulic fluid introduction member (17) disposed in the boiler section (11), which sucks the hydraulic fluid (14) in the liquid reservoir chambers (157a, 309a) by capillary force and supplies it to the evaporation chamber (156, 308); With
The evaporation chambers (156, 308) are separated from the liquid storage chambers (157a, 309a) and have a higher pressure than the liquid storage chambers (157a, 309a).
The hydraulic fluid introduction member (17)
(2σ / r) · cos θ> PH-PL
Configured to satisfy the relationship
The hydraulic fluid introduction member (17) includes a suction portion (175) that sucks the hydraulic fluid (14) in the liquid reservoir chambers (157a, 309a), and a heat receiving portion (176) that receives heat from the external heat source (3). And
Further, the hydraulic fluid introduction member (17) has different continuity of the gap depending on the part, and the continuity of the gap and the part having high continuity of the gap from the suction part (175) side toward the heat receiving part (176) side. It has a structure in which low parts appear alternately,
The hydraulic fluid introduction member (17) is interposed in the heat transfer path from the external heat source (3) to the liquid reservoir chambers (157a, 309a), and the liquid reservoir chambers (157a, 309a) are disposed in the heat transfer path. It is characterized by suppressing heat transfer to the hydraulic fluid (14) .

  Where σ is the surface tension of the hydraulic fluid (14), r is the equivalent circle radius of the void in the hydraulic fluid introduction member (17), and θ is the wetting angle of the hydraulic fluid (14) with respect to the hydraulic fluid introduction member (17). , PH is the pressure in the evaporation chambers (156, 308), and PL is the pressure in the liquid reservoir chambers (157a, 309a).

  According to this, by configuring the hydraulic fluid introduction member (17) so as to satisfy the relationship of the above mathematical formula, the pressure due to the capillary force of the hydraulic fluid introduction member (17) is reduced to the high-pressure evaporation chamber (156, 308). And the pressure difference between the low pressure reservoir chambers (157a, 309a) and supply of the working fluid (14) from the low pressure reservoir chambers (157a, 309a) to the high pressure evaporation chambers (156, 308). Can be performed by utilizing the capillary force of the hydraulic fluid introduction member (17). Therefore, the working fluid (14) condensed in the condensing unit (13) can be returned to the high-pressure evaporation chamber (156, 308) without using external energy as much as possible.

Further, the hydraulic fluid introduction member (17) has a structure in which a portion having a high continuity of the gap and a portion having a low continuity of the gap appear alternately from the suction portion (175) side to the heat receiving portion (176) side. Since it has, it can suppress that a vapor | steam flows backward through a space | gap from the heat receiving part (176) side to the attraction | suction part (175) side. For this reason, the sealing property of vapor | steam can be improved and the supply property of the working fluid (14) from the reservoir chamber (157a, 309a) to the evaporation chamber (156, 308) can be improved.
Moreover, since the heat insulation of a liquid reservoir chamber (157a, 309a) can be improved, it can suppress that the hydraulic fluid (14) of a liquid reservoir chamber (157a, 309a) evaporates and a fall of output efficiency is caused.

Specifically, as in the invention according to claim 2, in the heat engine according to claim 1, the hydraulic fluid introduction member (17) has a plurality of fiber layers laminated to each other,
The plurality of fiber layers of the hydraulic fluid introduction member (17) are laminated from the suction part (175) side toward the heat receiving part (176) side,
Of the hydraulic fluid introduction member (17), the portion where the continuity of the voids is high is the interface between the fiber layers,
The site | part with low continuity of a space | gap among the hydraulic fluid introduction members (17) should just be a site | part which comprises a fiber layer.

  More specifically, a thermoplastic resin fiber (more specifically, an aramid fiber) is preferable as the fiber constituting the fiber layer of the hydraulic fluid introduction member (17).

According to a third aspect of the present invention, in the heat engine according to the second aspect, the hydraulic fluid introduction member (17) is formed in a flat plate shape whose plate surface extends in parallel with the direction in which the fiber layer extends,
The suction part (175) is composed of one plate surface of the hydraulic fluid introduction member (17),
The heat receiving portion (176) is configured by the other plate surface of the hydraulic fluid introduction member (17).

  As a result, the shape stability and strength of the hydraulic fluid introduction member (17) can be increased. In addition, the hydraulic fluid introduction member (17) can be easily manufactured.

According to a fourth aspect of the present invention, in the heat engine according to any one of the first to third aspects, the boiler section (11) contacts the heat receiving section (176) of the hydraulic fluid introduction member (17). And a heat transfer member (152, 23, 302) for transferring heat from the external heat source (3) to the working fluid introduction member (17),
The steam generated from the hydraulic fluid introduction member (17) is exhausted to the outside of the hydraulic fluid introduction member (17) at a portion of the heat transfer member (152, 23, 302) that contacts the heat receiving portion (176). For this purpose, an exhaust passage (21) is formed.

  According to this, the steam generated from the hydraulic fluid introduction member (17) is transferred to the outside of the hydraulic fluid introduction member (17) at the portion of the heat transfer member (152, 23, 302) that contacts the heat receiving portion (176). Since the exhaust passage (21) for exhausting is formed, it is possible to avoid the vapor from staying inside the working fluid introduction member (17) and hindering the suction of the working fluid (14).

Specifically, as in the invention according to claim 5 , in the heat engine according to claim 4 , the exhaust passage (21) is configured by a groove (22) formed in the heat transfer member (152). It only has to be.

Further, as in the invention described in claim 6 , in the heat engine according to claim 4 , the heat transfer member (152, 23) includes an exhaust passage forming member (23) that forms the exhaust passage (21), and It is divided into a member (152) constituting the remaining part and molded,
The exhaust passage forming member (23) is a net-like member or a plurality of ball-like members sandwiched between the member (152) constituting the remaining portion and the hydraulic fluid introduction member (17),
The exhaust passage (21) may be constituted by a gap formed by a mesh member or a plurality of ball members.

According to a seventh aspect of the present invention, in the heat engine according to any one of the fourth to sixth aspects, the heat transfer member (152, 23, 302) has a top surface portion extending in the horizontal direction,
The hydraulic fluid introduction member (17) is formed in a flat plate shape and is superimposed on the upper surface portion of the heat transfer member (152, 23, 302).
The hydraulic fluid introduction member (17) receives heat from the external heat source (3) via the heat transfer member (152, 23, 302).

  Thereby, since the heat receiving area of the hydraulic fluid introducing member (17) can be secured large, the hydraulic fluid (14) sucked by the hydraulic fluid introducing member (17) can be effectively heated.

According to an eighth aspect of the present invention, in the heat engine according to the seventh aspect , the boiler part (11) is located on the side opposite to the heat transfer member (152, 23, 302) of the hydraulic fluid introduction member (17). It has a heat transfer plate (19) which is superposed on the surface and transmits heat from the external heat source (3) to the hydraulic fluid introduction member (17).

  Thereby, the hydraulic fluid introduction member (17) is heated from the upper surface side. For this reason, since the hydraulic fluid (14) evaporates from the upper surface of the hydraulic fluid introduction member (17), the release of the vapor of the hydraulic fluid (14) is improved, and the output can be improved.

In invention of Claim 9 , in the heat engine as described in any one of Claim 1 thru | or 8 , the boiler part case (30) which accommodates a boiler part (11),
A reflux part case (31) for accommodating the output part (12) and the condenser part (13);
A steam passage forming portion (32) that forms a steam passage (32a) that connects the evaporation chamber (308) of the boiler portion (11) and the output portion (12);
A circulation passage forming portion (33) that forms a circulation passage (33a) that communicates between the condensation portion (13) and the liquid storage chamber (309a) of the boiler portion (11);
The boiler part case (30) and the reflux part case (31) are arranged so as to be spaced apart from each other and connected via a steam passage forming part (32) and a circulation passage forming part (33).

  According to this, since the output unit (12) and the condensing unit (13) are spaced apart from the boiler unit (11), the boiler unit (11) is connected to the output unit (12) and the condensing unit (13). It is difficult for the heat to be transmitted, and the temperature rise of the output part (12) and the condensing part (13) is suppressed. For this reason, the aggregation / refluxing performance of the steam discharged from the output section (12) is improved.

According to a tenth aspect of the present invention, in the heat engine according to the seventh or eighth aspect , a portion of the working fluid introduction member (17) located inside the evaporation chamber (156) penetrates the front and back. A through hole (172) is formed.

  According to this, since the vapor heated and evaporated by the heat transfer member (152, 23, 302) can be quickly released from the through hole (172) to the upper side of the hydraulic fluid introduction member (17), It can be suppressed that the hydraulic fluid stays in the hydraulic fluid introduction member (17) and prevents the hydraulic fluid (14) from being sucked.

According to an eleventh aspect of the present invention, in the heat engine according to the tenth aspect , the through hole (172) communicates with the exhaust passage (21).

  Thus, the vapor heated and evaporated by the heat transfer member (152, 23, 302) can be quickly released from the exhaust passage (21) and the through hole (172) to the upper side of the hydraulic fluid introduction member (17). Therefore, it is possible to further suppress the vapor from staying in the hydraulic fluid introduction member (17) and hindering the suction of the hydraulic fluid (14).

Specifically, as in the invention according to claim 12 , in the heat engine according to claim 10 or 11 , the through hole (172) is a groove extending in the plate surface direction of the working fluid introduction member (17). What is necessary is just to be formed in the shape.

As in the invention described in claim 13 , in the heat engine described in claim 10 or 11 , a large number of through holes (172) may be dispersed.

In a fourteenth aspect of the present invention, in the heat engine according to any one of the first to thirteenth aspects, the boiler section (11) operates so that the gap in the hydraulic fluid introduction member (17) is reduced. A load applying means (161) for applying a load to the liquid introduction member (17);
The hydraulic fluid introduction member (17) is characterized in that it is held in the boiler section (11) in a state where a load is applied from the load application means (161).

  According to this, since the load applying means (161) reduces the gap in the hydraulic fluid introduction member (17), the circle equivalent radius r of the gap in the hydraulic fluid introduction member (17) can be reduced. The hydraulic fluid introduction member (17) that satisfies the above mathematical relationship can be easily configured.

In the invention according to claim 15 , in the heat engine according to claim 14 , the boiler part (11) has a partition wall (16) separating the evaporation chamber (156) and the liquid reservoir chamber (157a),
The partition wall (16) is disposed in the boiler section (11) so as to apply a load to the hydraulic fluid introduction member (17),
The load applying means (161) is constituted by a partition wall (16).

  According to this, since the partition wall (16) separating the evaporation chamber (156) and the liquid storage chamber (157a) also serves as a load applying means, it is compared with the case where the load applying means is provided separately from the partition wall (16). Thus, the configuration can be simplified.

In the invention according to claim 16 , in the heat engine according to any one of claims 1 to 15 , the hydraulic fluid introduction member (17) is made of a material woven with at least resin fibers. Features.

In the invention according to claim 17 , in the heat engine according to any one of claims 1 to 16, the evaporation chamber (411b) heats the working fluid (44) with heat obtained from sunlight, and Generating a vapor of the hydraulic fluid (44) ;
The boiler part (41) has a sunlight intake part (411c) for taking sunlight into the evaporation chamber (411b),
The hydraulic fluid introduction member (412) has a heat receiving portion (412b) that receives and heats sunlight received from the sunlight intake portion (411c).

  According to this, in the heat engine that extracts mechanical energy from sunlight, the working fluid (44) condensed in the condensing unit (43) can be returned to the high-pressure evaporation chamber (411b) without using external energy as much as possible. it can. For this reason, energy saving and clean energy can be realized.

  Further, the hydraulic fluid introduction member (44) has a structure in which a portion having high continuity of the gap and a portion having low continuity of the gap appear alternately from the suction portion (412a) side to the heat receiving portion (412b) side. Since it has, it can suppress that a vapor | steam flows backward from a heat receiving part (412b) to a suction part (412a). For this reason, the sealing property of vapor | steam can be improved and the supply property of the working fluid (44) from a liquid reservoir chamber (411a) to an evaporation chamber (411b) can be improved by extension.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

It is sectional drawing of the waste heat recovery apparatus in the form used as the premise of this invention. It is a perspective view which shows the external appearance of the waste heat recovery apparatus in the form used as the premise of this invention. It is a perspective view which shows the internal structure of the waste heat recovery apparatus in the form used as the premise of this invention. It is sectional drawing which shows the engine of the waste heat recovery apparatus in the form used as the premise of this invention. It is sectional drawing of the waste heat recovery apparatus in 1st Embodiment of this invention. It is sectional drawing and the top view which show the principal part of the boiler part in 1st Embodiment of this invention. It is explanatory drawing explaining the manufacturing method of the wick in 1st Embodiment of this invention. It is a top view which shows the example of a pattern of the groove | channel in 1st Embodiment of this invention. It is sectional drawing which shows the principal part of the boiler part in 2nd Embodiment of this invention. It is the top view and sectional view which show the principal part of the boiler part in 3rd Embodiment of this invention. It is sectional drawing of the waste heat recovery apparatus in 4th Embodiment of this invention. It is the top view and sectional drawing which show the principal part of the boiler part in 5th Embodiment of this invention. It is the top view and sectional drawing which show the principal part of the boiler part in the modification of 5th Embodiment of this invention. It is the perspective view and sectional drawing which show the solar power generator in 6th Embodiment of this invention.

(Form which is the premise of the present invention)
The form which becomes the premise of this invention is demonstrated based on FIGS. In this embodiment, the heat engine is applied to the exhaust heat recovery device. FIG. 1 is a cross-sectional view showing the overall configuration of the exhaust heat recovery apparatus. FIG. 2 is a perspective view showing an external appearance of the exhaust heat recovery apparatus. FIG. 3 is a perspective view showing the internal structure of the exhaust heat recovery apparatus. 1 to 4, the up and down arrows indicate the up and down direction (vertical direction) in the installed state of the exhaust heat recovery device.

  The exhaust heat recovery apparatus 10 according to the present embodiment is roughly divided into a boiler unit 11, an output unit 12, and a condensing unit 13. In the example of FIG. 1, the generator 1 is attached to the exhaust heat recovery device 10 in order to use mechanical energy extracted by the exhaust heat recovery device 10 for power generation. In the example of FIG. 2, the fan 2 is rotationally driven by the mechanical energy extracted by the exhaust heat recovery apparatus 10.

  The boiler unit 11 heats and evaporates the hydraulic fluid 14 (water in this example) with heat (exhaust heat) supplied from an external heat source, and supplies the vapor of the hydraulic fluid 14 to the output unit 12. The output unit 12 converts the energy of the steam supplied from the boiler unit 11 into mechanical energy and outputs the mechanical energy.

  The condensing unit 13 condenses the vapor that has passed through the output unit 12 to condense it into the working fluid 14, and returns the condensed working fluid 14 to the boiler unit 11. Therefore, the condensing part 13 can also be expressed as a reflux part.

  The boiler unit 11 and the output unit 12 are accommodated in the case 15. In this example, the case 15 is composed of a single container. The case 15 is placed on the heating element 3 that forms an external heat source. In this example, the heating element 3 generates heat due to exhaust heat from the factory.

  The case 15 includes two flat plates 151 and 152 that extend in the horizontal direction, and a cylinder 153 that extends in the vertical direction between the two flat plates 151 and 152. That is, the upper and lower walls of the case 15 are configured by the flat plates 151 and 152, and the side wall of the case 15 is configured by the cylinder 153.

  In this example, since water is used as the working fluid 14, the flat plates 151 and 152 and the cylinder 153 are preferably formed of stainless steel having excellent water resistance. In this example, the flat plates 151 and 152 are formed in a rectangular flat plate shape, and the tube 153 is formed in a cylindrical shape.

  The flat plates 151 and 152 and the tube 153 are fixed so as to ensure liquid tightness and air tightness. In the example of FIG. 1, a seal member 154 is interposed between the flat plates 151 and 152 and the cylinder 153. In the example of FIGS. 2 and 3, a support column 155 that connects the flat plates 151 and 152 is disposed on the outer peripheral side of the tube 153.

  The internal space of the case 15 is separated by a partition wall 16 into a high pressure chamber 156 and a low pressure chamber 157. The partition wall 16 is divided into a cylindrical wall portion 161 disposed on the lower wall portion 152 of the case 15 and a plate-like wall portion 162 covering the cylindrical wall portion 161. In this example, the cylindrical wall part 161 is formed in a cylindrical shape, and the plate-like wall part 162 is formed in a disk shape.

  The high-pressure chamber 156 is a space formed inside the cylindrical wall portion 161 and below the plate-like wall portion 162, and constitutes an evaporation chamber in which the working fluid 14 is heated by the heat of the heating element 3 to evaporate. Therefore, the high pressure chamber 156 becomes high pressure by the vapor of the working fluid 14.

  The low pressure chamber 157 is a space formed on the outer side of the cylindrical wall portion 161 and on the upper side of the plate-like wall portion 162. The steam that has flowed through the output unit 12 and the working fluid 14 that has been condensed in the condensing unit 13 flow into the low-pressure chamber 157. Therefore, the low pressure chamber 157 has a lower pressure than the high pressure chamber 156.

  The partition wall 16 is formed of a heat-insulating material having heat resistance such as a heat-resistant resin so that the vapor in the evaporation chamber (high pressure chamber) 156 is not cooled and condensed.

  An engine 121 that constitutes the output unit 12 is disposed in the low pressure chamber 157. In this example, the engine 121 is fixed to the upper side of the plate-like wall portion 162 of the partition wall 16, and a steam passage 162 a for supplying the vapor of the evaporation chamber 156 to the engine 121 is formed in the plate-like wall portion 162. Yes.

  A space located between the cylinder 153 of the case 15 and the cylindrical wall portion 161 of the partition wall 16 in the low-pressure chamber 157 constitutes a liquid reservoir chamber 157 a that stores the working fluid 14 supplied to the evaporation chamber 156. That is, the liquid reservoir chamber 157 a is disposed on the horizontal direction side of the evaporation chamber 156.

  A wick 17 corresponding to a hydraulic fluid introduction member is sandwiched between the bottom wall portion (lower wall portion) 152 of the case 15 and the cylindrical wall portion 161 of the partition wall 16.

  Here, the hydraulic fluid introduction member is defined as a member that generates a capillary force (capillary force generation member) that sucks the hydraulic fluid 14 in the liquid reservoir chamber 157, for example, porous ceramic or metal sintered material. It is a structure in which a porous body such as a body or a fiber is knitted.

  In this example, the wick 17 is formed of a heat-resistant sheet material. Specifically, the wick 17 is formed of a braided material of a stainless wire and an aramid fiber (thermoplastic resin fiber). In this example, the wick 17 is formed in a flat plate shape, more specifically in a disk shape.

  The wick 17 is overlaid on an upper surface portion extending in the horizontal direction in the planar bottom wall portion 152. The bottom wall portion 152 is in contact with the heating element 3 and serves as a heat transfer member that transfers heat from the heating element 3 to the wick 17. As a result, the lower surface portion (planar portion on the bottom wall portion 152 side) 173 of the wick 17 receives heat from the heating element 3 via the bottom wall portion 152.

  The outer peripheral edge portion of the wick 17 is sandwiched between the bottom wall portion 152 of the case 15 and the cylindrical wall portion 161 of the partition wall 16. Thereby, the end surface 171 in the horizontal direction of the wick 17 constitutes an inflow port through which the working fluid 14 in the liquid reservoir chamber 157 flows.

  A central portion of the wick 17 (a portion closer to the center than the cylindrical wall portion 161) is located in the evaporation chamber 156. In other words, the wick 17 extends from the cylindrical wall portion 161 to the evaporation chamber 156 side.

  In this example, the cylindrical wall portion 161 and the wick 17 are fastened together with the bottom wall portion 152 of the case 15 by bolts 18 and fixed. By tightening the bolt 18, the wick 17 is held in the case 15 in a state of being compressed by receiving a load from the cylindrical wall portion 161.

  When the wick 17 is compressed by receiving a load from the cylindrical wall portion 161, the air gap in the wick 17 is reduced as compared with a state where the load is not received (a single state of the wick 17). In other words, the cylindrical wall portion 161 constitutes a load applying means for applying a load to the wick 17 so that the gap in the wick 17 is reduced.

  Here, a pressure difference is generated inside the wick 17 by capillary action. Hereinafter, the pressure difference due to the capillary phenomenon is referred to as a pressure ΔP due to the capillary force of the wick 17. The pressure ΔP due to the capillary force of the wick 17 is expressed by the following formula 1.

(Equation 1)
ΔP = (2σ / r) · cos θ
However, r is the equivalent circle radius (capillary radius) of the void in the wick 17, σ is the surface tension, and θ is the wetting angle. The circle equivalent radius is a radius of a circle having the same area as the target cross section.

  As described above, the wick 17 receives the load from the cylindrical wall portion 161 and is compressed to reduce the gap in the wick 17. As a result, the equivalent circle radius r of the gap in the wick 17 in Equation 1 is reduced, and the pressure ΔP due to the capillary force of the wick 17 is the pressure difference between the pressure PH of the high pressure chamber 156 and the pressure PL of the low pressure chamber 157 ( PH-PL) (ΔP> PH-PL).

  In other words, the wick 17 is configured to satisfy the relationship of the following formula 2.

(Equation 2)
(2σ / r) · cos θ> PH-PL
A disc-shaped plate 19 is placed at the center of the wick 17. The plate 19 and the wick 17 are fastened to the bottom wall portion 152 of the case 15 by bolts 20 and fixed. This prevents the central portion of the wick 17 from being lifted.

  A predetermined number of through-holes 172 and 191 extending in the vertical direction and penetrating the front and back are formed in portions of the wick 17 and the plate 19 located in the evaporation chamber 156. The through holes 172 and 191 serve as a steam vent for allowing steam generated in the evaporation chamber 156 to escape upward of the wick 17 and the plate 19.

  In other words, when the hydraulic fluid 14 in the evaporation chamber 156 evaporates due to heat transfer from the bottom wall portion 152 of the case 15, the hydraulic fluid 14 escapes to the upper side of the wick 17 and the plate 19 through the through holes 172 and 191.

  A heat insulating groove 152a that suppresses heat conduction in the bottom wall 152 is circumferential, more specifically circumferential, at a portion of the bottom wall 152 that is located closer to the liquid reservoir chamber 157a than the through holes 172 and 191. It is formed in a shape.

  Of the bottom wall portion 152, the inner portion 152 b of the heat insulating groove 152 a, that is, the portion located closer to the through holes 172 and 191 than the heat insulating groove 152 a is placed on the heat generating body 3 and is in contact with the heat generating body 3. On the other hand, the outer portion 152 c of the heat insulating groove 152 a in the bottom wall portion 152 is not placed on the heating element 3 and is not in contact with the heating element 3.

  The cylindrical wall portion 161 of the partition wall 16 is disposed on the outer portion 152 c of the heat insulating groove 152 a in the bottom wall portion 152.

  In this example, the engine 121 of the output unit 12 is a pendulum engine in which the piston 122 and the cylinder 123 swing like a pendulum. A steam turbine or the like may be used instead of the engine 121.

  FIG. 4 is a cross-sectional view showing the engine 121. The cylinder 123 is supported so as to be swingable about a swing shaft 125 with respect to a base 124 fixed to the plate-like wall portion 162 of the partition wall 16.

  The base 124 is formed with an intake passage 124a that communicates with the steam passage 162a. The intake path 124 a is a flow path through which the steam sucked into the cylinder 123 flows. The base 124 is formed with an exhaust passage 124 b communicating with the low pressure chamber 157. The exhaust passage 124b is a passage through which steam exhausted from the cylinder 123 flows. An outlet portion of the intake passage 124 a and an inlet portion of the exhaust passage 124 b are open on the upper surface of the base 124.

  In this example, the piston 122 and the cylinder 123 are disposed in the horizontal direction, and the swing shaft 125 is disposed in the vertical direction. Therefore, the piston 122 and the cylinder 123 swing within the horizontal plane.

  On the lower surface of the cylinder 123, a port 123a for sucking and exhausting steam is opened. In a state where the cylinder 123 is located on one end side in the swinging direction, the port 123a communicates with the intake passage 124a. In a state where the cylinder 123 is located on the other end side in the swinging direction, the port 123a communicates with the exhaust passage 124b.

  When the cylinder 123 is positioned on one end side in the swinging direction and the port 123a communicates with the intake passage 124a, the steam in the evaporation chamber 156 flows into the cylinder 123 and the piston 122 is pushed out to move forward.

  The tip of the piston 122 is connected to the wheel gear 127 via the rod 126. As shown in FIG. 1, the wheel gear 127 is connected to the center gear 128. An output shaft 129 is fixed at the center of the center gear 128. Thereby, when the piston 122 is pushed out, the output shaft 129 rotates through the wheel gear 127 and the center gear 128.

  Further, when the piston 122 is pushed out and the wheel gear 127 rotates, the cylinder 123 swings toward the other end side in the swinging direction, and the port 123 a is closed by the upper surface of the base 124.

  When the port 123a is closed, the wheel gear 127 continues to rotate due to the inertial force, and the piston 122 is pushed back by the inertial force of the wheel gear 127 to return. At this time, the swing of the cylinder 123 is continued. When the cylinder 123 is positioned on the other end side in the swing direction and the port 123a communicates with the exhaust passage 124b, the steam in the cylinder 123 is discharged to the low pressure chamber 157.

  In the example of FIGS. 1 and 3, the engine 121 constitutes a multi-cylinder engine provided with a plurality of cylinders 123, but may constitute a single-cylinder engine provided with only one cylinder 123. .

  The output shaft 129 of the output unit 12 and the rotating shaft 1a of the generator 1 are connected by a magnet coupling via the upper wall portion 151 of the case 15. The rotor 1b is rotated by the rotation of the rotating shaft 1a, and power is generated by the coil 1c by the rotation of the rotor 1b. The electric power generated by the coil 1 c is supplied to an arbitrary electric device 4 connected to the generator 1.

  In the example of FIG. 1, the condensing unit 13 is disposed on the upper side of the case 15. On the upper wall portion 151 of the case 15, an outflow path 151 a for allowing the vapor of the low pressure chamber 157 discharged from the output portion 12 to flow out to the condensing portion 13, and the working fluid 14 condensed in the condensing portion 13 to the low pressure chamber 157. A reflux path 151b for refluxing is formed.

  The condensing part 13 is formed of a container having a predetermined shape, and the internal space of the condensing part 13 communicates with the outflow path 151a and the reflux path 151b. The steam that has flowed into the condensing unit 13 through the outflow passage 151 a dissipates heat into the atmosphere and condenses in the condensing unit 13. That is, in the condensing unit 13, the steam is returned to the working fluid 14. The working fluid 14 recovered by the condensing unit 13 is returned to the low pressure chamber 157 through the reflux path 151b and is stored in the liquid storage chamber 157a.

  In the example of FIG. 1, the fan 1d is connected to the rotating shaft 1a of the generator 1 to increase the heat radiation amount of the steam in the condensing unit 13, and the fan 1d is rotated by the rotating shaft 1a. The condensing unit 13 is cooled by the blown air.

  Next, the operation in the above configuration will be described. The heat of the heating element 3 is transmitted to the working fluid 14 in the evaporation chamber 156 via the bottom wall portion 152 of the case 15, and the working fluid 14 evaporates. The steam generated in the evaporation chamber 156 is supplied to the engine 121 through the steam passage 162a.

  The steam supplied to the engine 121 drives the piston 122. Thereby, the energy of the steam is converted into mechanical energy. The output shaft 129 is rotated by driving the piston 122, and the generator 1 generates power. In this way, the exhaust heat energy of the heating element 3 is recovered as electric energy.

  The steam in the engine 121 is discharged to the low pressure chamber 157 through the exhaust passage 124b after driving the piston 122. The steam discharged from the engine 121 to the low pressure chamber 157 flows into the condensing unit 13 through the outflow passage 151 a, is condensed in the condensing unit 13, and is returned to the working fluid 14. The working fluid 14 recovered by the condensing unit 13 returns to the low-pressure chamber 157 through the reflux path 151b and accumulates in the liquid reservoir chamber 157a.

  The working fluid 14 accumulated in the liquid reservoir chamber 157a is sucked into the wick 17 and supplied to the evaporation chamber 156 to evaporate. That is, the wick 17 generates a capillary force that sucks the hydraulic fluid 14 in the liquid reservoir chamber 157a, so that the hydraulic fluid 14 is transferred from the low-pressure reservoir chamber 157a to the high-pressure evaporation chamber 156 by using this capillary force. Supply.

  More specifically, in the boiler section 11 having the pressure partition wall 16, the reflux working fluid 14 in the low-temperature and low-pressure reservoir chamber 157 a is pulled into the high-pressure evaporation chamber 156 by the capillary force of the wick 17 and reaches the end of the wick 17. Drops of the working fluid 14 are continuously evaporated.

  Here, the air gap in the wick 17 is made small so that the circle-equivalent radius r of the air gap in the wick 17 is sufficiently small so as to satisfy the above formula 2, so the pressure ΔP due to the capillary force of the wick 17 is It becomes larger than the pressure difference (PH-PL) between the pressure PH of the high pressure chamber 156 and the pressure PL of the low pressure chamber 157 (ΔP> PH-PL).

  For this reason, the capillary force of the wick 17 overcomes the pressure difference (PH-PL) between the pressure PH of the high-pressure chamber 156 and the pressure PL of the low-pressure chamber 157, and the hydraulic fluid 14 accumulated in the low-pressure reservoir chamber 157a The evaporation chamber 156 can be sucked well.

  In other words, in the state where a pressure difference is generated between the liquid storage chamber 157a and the evaporation chamber 156 by the pressure partition wall 16, by using the wick 17, a capillary force that does not lose the pressure difference (PH-PL) is given. The working fluid 14 can be pulled from the low-pressure liquid reservoir chamber 157 a to the high-pressure evaporation chamber 156. Therefore, the hydraulic fluid 14 in the liquid reservoir chamber 157a can be returned to the high-pressure evaporation chamber 156 without using external energy.

  Further, since the evaporation amount of the working fluid 14 in the evaporation chamber 156 and the movement amount of the working fluid 14 from the liquid storage chamber 157a are the same, the recirculation amount control of the working fluid 14 becomes autonomous. For this reason, since the control mechanism for controlling the recirculation | reflux amount of the hydraulic fluid 14 is unnecessary, size reduction and cost reduction of an apparatus physique can be achieved.

  Further, since the gap in the wick 17 is made small, it is possible to prevent the steam generated in the evaporation chamber 156 from flowing back to the low pressure chamber 157 through the wick 17.

  As described above, in this embodiment, as an example of the wick 17, a braided material of stainless wire and aramid fiber is used. When the wick 17 is in a single state (uncompressed state) and the internal gap is large, the wick 17 is compressed to make the fibers dense, thereby reducing the gap in the wick 17 and the gap in the wick 17. It is preferable that the equivalent circle radius r is sufficiently small.

  In the present embodiment, the wick 17 is compressed between the cylindrical wall portion 161 and the bottom wall portion 152 by tightening the cylindrical wall portion 161 of the partition wall 16 with the bolt 18 against the bottom wall portion 152 of the case 15. is doing. For this reason, the wick 17 satisfying the relationship of the mathematical formula 2 can be easily configured.

One specific example of such compression of the wick 17 is that the wick 17 having a material thickness of 5 mm, a density of 2.5 m / cm ³ , and a fiber diameter of 8 μm is tightened and compressed to 12%. The equivalent circle radius r can be reduced to 12 μm, and a capillary force that overcomes the pressure of 10 kPa in the evaporation chamber 156 can be generated.

  In the present embodiment, since the wick 17 is compressed by applying a load to the wick 17 by the cylindrical wall portion 161 which is a part of the partition wall 16, the wick 17 is compressed by applying a load to the wick 17. The configuration can be simplified as compared with the case where the load applying means is provided separately from the partition wall 16.

  If the gap in the wick 17 is already sufficiently small even when the wick 17 is in a single state (uncompressed state), a sufficient capillary force can be obtained even if the wick 17 is used without being compressed. An example of such a wick 17 is a porous sintered metal plate.

  In the present embodiment, since the wick 17 extends to the evaporation chamber 156 side from the cylindrical wall portion 161, the wick 17 is disposed only between the cylindrical wall portion 161 and the bottom wall portion 152 of the case 15. Compared with the case where it is, the hydraulic fluid 14 of the liquid storage chamber 157a can be reliably supplied to the evaporation chamber 156.

  In the present embodiment, the end surface 171 in the horizontal direction of the wick 17 constitutes an inflow port into which the hydraulic fluid 14 in the liquid reservoir chamber 157a flows, so that the wick 17 sucks the hydraulic fluid 14 in the horizontal direction. It will be. For this reason, it is possible to suppress the influence of gravity when the wick 17 sucks the working fluid 14. For this reason, the hydraulic fluid 14 in the liquid reservoir chamber 157 a can be reliably supplied to the evaporation chamber 156 by the wick 17.

  In the present embodiment, since the wick 17 is formed in a flat plate shape extending in the horizontal direction and disposed on the bottom wall portion 152, the flat portion 173 on the bottom wall portion 152 side of the wick 17 is the bottom wall. Heat can be received from the heating element 3 via the part 152. For this reason, since the heat receiving area of the wick 17 can be ensured large, the working fluid 14 sucked by the wick 17 can be effectively heated.

  Further, in the present embodiment, since a through hole 172 extending in the vertical direction is formed in a portion of the wick 17 located in the evaporation chamber 156, the vapor heated and evaporated by the bottom wall portion 152 is passed through the through hole 172. Can be quickly released to the upper side of the wick 17. For this reason, it can suppress that vapor | steam retains in the wick 17, and the inside of the wick 17 is heated and dried and the suction | inhalation of the working fluid 14 is prevented.

  In the present embodiment, a circumferential heat insulating groove 152a that suppresses heat conduction in the bottom wall portion 152 is formed in a portion of the bottom wall portion 152 that is located closer to the liquid reservoir chamber 157a than the through hole 172, An inner portion 152b of the circumferential heat insulating groove 152a in the bottom wall portion 152 is in contact with the heating element 3.

  For this reason, heat reception is performed satisfactorily in the vicinity of the through-hole 172 in the wick 17, whereas heat reception is suppressed in a portion of the wick 17 away from the through-hole 172 (portion on the liquid reservoir chamber 157a side).

  As a result, the vapor that is heated and evaporated by the bottom wall portion 152 can be more quickly released from the through hole 172 to the upper side of the wick 17, so that the steam stays in the wick 17 and heats the inside of the wick 17. It can be avoided more that the suction of the hydraulic fluid 14 is prevented by drying.

  Therefore, the flow of the hydraulic fluid 14 in the wick 17 can be prevented from being interrupted, and loss (heat loss) in which the heat of the heating element 3 escapes to the case 15 can be suppressed.

  Incidentally, in this example, the inside of the case 15 is set to atmospheric pressure without reducing pressure, the temperature of the external heat source is set to 230 ° C., and the temperature of the high pressure chamber 156 is set to 102 ° C. and the temperature of the low pressure chamber 157 is set to 97 ° C. during operation. It is trying to become.

  Here, since the boiling point of the hydraulic fluid 14 is determined by the material of the hydraulic fluid 14 and the pressure in the case 15, for example, if alcohol is used for the hydraulic fluid 14 and the inside of the case 15 is evacuated, the temperature of the external heat source can be applied below zero degree Is possible. When the temperature of the external heat source is low, it is not necessary to impart heat resistance to the structure of the wick 17 and the boiler part 11 (case 15 and the like). Therefore, a material having low heat resistance as the material of the wick 17 and the boiler part 11 ( Resin or the like).

(First embodiment)
In the first embodiment, as shown in FIG. 5, the configuration of the boiler unit 11 is changed with respect to the above embodiment. Hereinafter, changes to the above embodiment will be described.

  The liquid storage chamber 157 a is disposed on the upper side of the wick 17. In other words, the wick 17 is interposed between the bottom wall portion 152 of the case 15 and the liquid reservoir chamber 157a. Therefore, the wick 17 is interposed in the heat transfer path from the heating element 3 to the liquid storage chamber 157a.

  In the example of FIG. 5, the lower part of the cylindrical case 15 has a larger diameter than the remaining part, the wick 17 is arranged in the lower part of the enlarged diameter, and the part (expanded) located above the wick 17. A liquid reservoir chamber 157a is formed in a portion not having a diameter.

  The wick 17 is a fiber assembly (fiber layer laminate) having a plurality of fiber layers laminated to each other. In this example, the wick 17 is a mixture of aramid fibers, which are thermoplastic resin fibers, and rock wool particles.

  FIG. 6 is a cross-sectional view showing the vicinity of the wick 17 of FIG. The wick 17 is formed by integrally joining a plurality of stacked disc-shaped materials. In FIG. 6, for convenience of illustration, the interface between the disk-shaped materials is indicated by a thin solid line. A plurality of disk-shaped materials constituting the wick 17 are laminated from the suction portion 175 side of the wick 17 toward the heat receiving portion 176 side of the wick 17.

  The suction part 175 of the wick 17 is a part that sucks the hydraulic fluid 14 in the liquid storage chamber 157a. The heat receiving portion 176 of the wick 17 is a portion that receives heat from the heating element 3.

  In the example of FIG. 5, since the liquid reservoir chamber 157 a is disposed on the upper surface side of the evaporation chamber 156, the suction portion 175 of the wick 17 is configured by the upper surface portion of the wick 17, and the heat receiving portion 176 of the wick 17 It consists of a bottom surface. Therefore, the plurality of disk-shaped materials constituting the wick 17 are stacked in the thickness direction of the wick 17.

  Although not shown, each fiber layer of the wick 17 extends in a direction (horizontal direction) orthogonal to the thickness direction of the wick 17. In other words, each fiber layer of the wick 17 extends in parallel with the plate surface of the wick 17.

  An outline of a method for manufacturing such a wick 17 will be described with reference to FIG. First, as shown in FIG. 7A, a plate material W1 is prepared.

  The plate-like material W1 is a fiber assembly (fiber layer laminate) having a plurality of fiber layers laminated to each other, and is formed to a predetermined thickness by repeating the paper-making method. In this example, the plate-like material W1 is a mixture of aramid fibers, which are thermoplastic resin fibers, and rock wool particles. In this example, a thin material having a thickness of about 4 mm is used as the plate-like material W1.

  FIG.7 (b) is the A section enlarged view of Fig.7 (a). In FIG.7 (b), the interface between fiber layers is shown with the thin continuous line for convenience of illustration. As shown in FIG.7 (b), the some fiber layer which comprises the plate-shaped raw material W1 is laminated | stacked on the thickness direction of the plate-shaped raw material W1. In other words, the plurality of fiber layers constituting the plate material W1 extend in parallel with the plate surface of the plate material W1.

  Next, as shown in FIG. 7C, the plate-shaped material W1 is cut to obtain a large number of disk-shaped materials W2. At this time, the outer diameters of a large number of disk-shaped materials W2 are made to be the same.

  Next, as shown in FIG. 7D, a large number of disk-shaped materials W2 are stacked without gaps in the thickness direction to obtain a disk-shaped array W3.

  In the disk-shaped array W3 obtained in this way, the fiber layer extends in a direction perpendicular to the thickness direction. In other words, the flat array W3 has a fiber layer extending in a direction parallel to the plate surface.

  Next, as shown in FIG. 7E, the plate-like material W2 of the array W3 is joined to each other by setting the flat array W3 on the jigs J1, J2 and J3 and performing hot pressing. A disk-like wick 17 can be obtained.

  In the wick 17 obtained in this way, the fiber layer extends in a direction orthogonal to the thickness direction. And in the interface part of the fiber layers of the wick 17, the continuity of a space | gap becomes higher than the remaining site | part (site | part which comprises a fiber layer).

  For this reason, the continuity of the gap in the thickness direction of the wick 17 is lower than the continuity of the gap in the direction perpendicular to the thickness direction (the direction parallel to the plate surface). It will have the structure where a high part and a part with low continuity of a space | gap appear alternately in the thickness direction.

  In this example, the jigs J1, J2, and J3 are constituted by a stainless steel ring J1, a stainless steel circular plate J2, and a stainless steel cylinder J3. As processing conditions for the hot press, for example, temperature: 300 ° C., pressure: 50 tons, and press time: 20 minutes are preferable. That is, the strip-shaped materials W2 can be joined to each other by hot pressing at a temperature at which the aramid fibers (thermoplastic resin) of the strip-shaped materials W2 are softened.

  After the pressing time has elapsed, the gap between the fibers can be reduced by cooling while applying pressure and compressing. Moreover, since the contact | adhesion power of fibers can be raised by cooling with applying pressure and compressing, the intensity | strength of the wick 17 can be raised.

  In this example, the outer peripheral portion of the plate 19 constitutes a part of the case 15, and the plate 19 is formed with a flow port 192 through which the working liquid 14 sucked from the liquid reservoir chamber 157 a to the suction portion 175 flows. ing. In other words, the plate 19 also serves as a flow port forming member that forms the flow port 192.

  The circulation port 192 is formed in a groove shape penetrating the front and back of the wick 17. In this example, the circulation port 192 is configured by an annular groove concentric with the wick 17.

  As shown in FIG. 5, the exhaust passage 21 is formed in the bottom wall portion 152 of the case 15. Specifically, the exhaust passage 21 is configured by a groove 22 formed in a contact portion of the bottom wall portion 152 with the wick 17. As a modification, the groove 22 is formed in a plate-like member formed separately from the bottom wall portion 152, and this plate-like member is disposed between the bottom wall portion 152 and the wick 17. It may be like that.

  The groove 22 is formed so as to overlap with the through hole 172 of the wick 17. Therefore, the through hole 172 of the wick 17 communicates with the exhaust passage 21.

  As the pattern of the groove 22, various patterns can be used as shown in FIGS. For example, as in the example of FIG. 8A, the pattern of the groove 22 can be a combination of one circular groove and a plurality of linear grooves of two types of long and short that radially intersect the circular groove.

  For example, as shown in FIG. 8B, the pattern of the grooves 22 may be a combination of a plurality of linear grooves so as to be orthogonal to each other. Further, as shown in FIGS. 8C and 8D, the pitch of the linear grooves can be appropriately modified.

  In the example of FIG. 5, a rubber seal 19 a for preventing steam leakage is disposed between the wick 17 and the plate 19. The rubber seal 19 a is formed with an annular groove that overlaps with the flow port 192 of the plate 19. In the example of FIG. 5, a vapor pressure port 158 to which a vapor pressure measuring sensor is connected is formed in a side portion of the wick 17 in the case 15.

  In the example of FIG. 5, the condensing part 13 is formed in the case 15. That is, the steam discharged from the engine 121 to the low pressure chamber 157 is condensed in the low pressure chamber 157 and returned to the working fluid 14. Of course, the condensation part 13 may be formed with the container different from the case 15 similarly to the form used as the premise of the above-mentioned this invention.

  Also in this embodiment, the gap in the wick 17 is made sufficiently small so that the pressure ΔP due to the capillary force of the wick 17 is the pressure difference (PH−PL) between the pressure PH of the high pressure chamber 156 and the pressure PL of the low pressure chamber 157. (ΔP> PH−PL).

  For this reason, the working fluid 14 accumulated in the low-pressure liquid reservoir chamber 157 a is sucked from the suction portion 175 configured by the upper surface portion of the wick 17, reaches the heat receiving portion 176 configured by the lower surface portion of the wick 17, and receives heat Evaporates in part 176.

  According to this embodiment, since the fiber layer of the wick 17 is laminated from the suction part 175 side toward the heat receiving part 176 side, a continuous gap is formed in the wick 17 from the suction part 175 side toward the heat receiving part 176 side. Highly characteristic parts and low continuity parts of voids appear alternately.

  For this reason, since the connection of the gap from the suction part 175 to the heat receiving part 176 becomes complicated, it is possible to suppress the backflow of steam from the heat receiving part 176 side to the suction part 175 side through the gap, and as a result, the liquid reservoir chamber 157a. Therefore, it is possible to improve the supply of the working fluid 14 to the evaporation chamber 156.

  In particular, in the present embodiment, the wick 17 is formed in a flat plate shape in which the extending direction of the fiber layer and the extending direction of the plate surface are parallel to each other. Therefore, the wick 17 is excellent in shape stability and strength, and the wick 17 is manufactured. Is also easy.

  Further, since the wick 17 is interposed in the heat transfer path from the heating element 3 to the liquid storage chamber 157a, the wick 17 suppresses heat transfer from the heating element 3 to the working fluid 14 in the liquid storage chamber 157a. Can do. For this reason, since the heat insulation of the liquid storage chamber 157a can be improved, it can suppress that the working fluid 14 of the liquid storage chamber 157a evaporates and the output efficiency falls.

  Further, the wick 17 is formed in a flat plate shape, and one plate surface (lower plate surface) constitutes the heat receiving portion 176, so that a large area of the heat receiving portion 176 of the wick 17 can be secured, and as a result, the heat transfer property. Can be improved.

  Further, the wick 17 is compressed (hot press) in the manufacturing process, and is further compressed by receiving a load from the plate 19 in a state where the wick 17 is assembled to the boiler unit 11. As a result, since the gap of the wick 17 is minimized, the pressure ΔP due to the capillary force of the wick 17 can be further increased. As a result, the supply of the working fluid 14 from the liquid reservoir chamber 157a to the evaporation chamber 156 is achieved. Can be further improved.

  In the present embodiment, the exhaust passage 21 is formed in the bottom wall portion 152 of the case 15, so that the vapor of the working fluid 14 evaporated from the lower surface of the wick 17 passes through the exhaust passage 21 and enters the through hole 172 of the wick 17. The vapor that reaches and reaches the through hole 172 of the wick 17 is exhausted to the upper side of the wick 17.

  For this reason, the vapor evaporated from the lower surface of the wick 17 can be easily escaped to the upper side of the wick 17, so that the vapor of the working fluid 14 can be released and the output can be improved.

  Moreover, the steam is further heated while passing through the exhaust passage 21 to become superheated steam, and the steam pressure increases, so the engine thrust increases. In other words, the output energy increases. However, since the heat transfer area decreases as the number of exhaust passages 21 increases, exhaust performance and heat transfer performance are in a trade-off relationship.

(Second Embodiment)
In the first embodiment, the exhaust passage 21 is constituted by the groove 22, but in the second embodiment, as shown in FIG. 9, the exhaust passage 21 is disposed between the bottom wall portion 152 of the case 15 and the wick 17. An exhaust passage 21 is configured by sandwiching an exhaust passage forming member 23 that forms the passage.

  The exhaust passage forming member 23 is formed of a metal or the like having excellent heat conductivity, and is also responsible for heat transfer from the bottom wall portion 152 of the case 15 to the wick 17. In other words, in this embodiment, the heat transfer member responsible for heat transfer from the heating element 3 to the wick 17 is formed by being divided into the member constituting the bottom wall portion 152 and the exhaust passage forming member 23.

FIG. 9 shows an example in which a plurality of ball-shaped members are used as the exhaust passage forming member 23. As the ball-shaped member, for example, a bearing ball having a diameter of φ3 can be used. By using a plurality of ball-shaped members as the exhaust passage forming member 23, a space through which steam can flow is formed between the bottom wall portion 152 of the case 15 and the wick 17, and this space functions as the exhaust passage 21. It will be.

A net-like member may be used as the exhaust passage forming member 23 that forms the exhaust passage . As the mesh member, a woven wire mesh is suitable, and, for example, a linear 0.5 mm stainless mesh can be used.

A woven wire mesh is a wire mesh in which vertical lines and horizontal lines are woven by alternately crossing one by one while maintaining a constant interval. The vertical and horizontal lines of the woven wire mesh are bent in a wave shape. Therefore, by using the woven wire net as the exhaust passage forming member 23, a gap through which steam can flow is formed between the bottom wall portion 152 of the case 15 and the wick 17, and this gap functions as the exhaust passage 21. It becomes.

  Thus, also in this embodiment, the same effect as the second embodiment can be obtained.

(Third embodiment)
In each of the above embodiments, the plate 19 plays the role of preventing the central portion of the wick 17 from being lifted. In the third embodiment, however, the plate 19 is moved from the heating element 3 to the wick 17 as shown in FIG. Also plays a role as a heat transfer plate for heat transfer.

  Therefore, the plate 19 of this embodiment is formed of a material having excellent thermal conductivity. In the example of FIG. 10, the plate 19 is divided into a plurality of sectors, and a gap of a predetermined interval is provided between the sector-shaped divided plates.

  According to this, since the heat conduction path of the heating element 3 → the bottom wall portion 152 of the case 15 → the bolt 20 → the plate 19 → the wick 17 is formed, the wick 17 is heated from the upper surface side. For this reason, since the hydraulic fluid 14 evaporates from the upper surface of the wick 17, the vapor | steam discharge | release of the hydraulic fluid 14 becomes good, and an output can be improved by extension.

(Fourth embodiment)
In each of the above embodiments, the boiler unit 11 and the output unit 12 are accommodated in a common case 15, but in the fourth embodiment, as shown in FIG. 11, the boiler unit 11 is in the boiler unit case 30. The output part 12 and the condensing part 13 are accommodated in the reflux part case 31.

  The boiler part case 30 and the reflux part case 31 are arranged so as to be separated from each other and are connected via a steam passage forming part 32 and a circulation passage forming part 33. The steam passage forming portion 32 forms a steam passage 32 a that connects the boiler portion 11 and the output portion 12. The circulation passage forming unit 33 forms a circulation passage 33 a that allows the condensing unit 13 and the boiler unit 11 to communicate with each other.

  According to this, since the output unit 12 and the condensing unit 13 are arranged separately from the boiler unit 11, the heat of the boiler unit 11 is not easily transmitted to the output unit 12 and the condensing unit 13, and the output unit 12 and the condensing unit 13 Temperature rise is suppressed. For this reason, the aggregation / refluxing performance of the steam discharged from the output unit 12 is improved.

  In addition, in the example of FIG. 11, the boiler part case 30 and the recirculation | reflux part case 31 are comprised as follows.

  The boiler case 30 is placed on the heating element 3 that forms an external heat source. The boiler case 30 is composed of two flat plates 301 and 302 extending in the horizontal direction and cylinders 303 and 304 extending in the vertical direction between the two flat plates 151 and 152. That is, the upper and lower walls of the boiler part case 30 are configured by the flat plates 301 and 302, and the side walls of the boiler part case 30 are configured by the cylinders 303 and 304. The cylinder 303 is disposed above the cylinder 304.

  In this example, since water is used as the working fluid 14, the flat plates 301 and 302 and the tubes 303 and 304 are preferably formed of stainless steel having excellent water resistance. Seal members 305, 306, and 307 are interposed between the flat plates 301 and 302 and the cylinders 303 and 304. The seal member 307 interposed between the flat plate 302 and the cylinder 304 is formed in an annular plate shape, and also serves as a spacer for adjusting the vertical position of the cylinder 304.

  The internal space of the boiler case 30 is separated by a partition wall 34 into a high pressure chamber 308 and a low pressure chamber 309. The partition wall 34 is divided into a cylindrical wall part 341 disposed on the lower wall part 302 of the boiler part case 30 and a plate-like wall part 342 that covers the cylindrical wall part 341. In this example, the cylindrical wall portion 341 is formed in a bottomed cylindrical shape, and the plate-like wall portion 342 is formed in a disc shape. The bottom surface portion of the cylindrical wall portion 341 serves as a plate that prevents the wick 17 from being lifted.

  The partition wall 34 is formed of a heat-resistant heat-insulating material such as a heat-resistant resin so that the vapor in the high-pressure chamber (evaporation chamber) 308 is not cooled and condensed.

  A vapor passage 32 a communicates with the evaporation chamber 308. The steam passage forming portion 32 that forms the steam passage 32 a passes through the upper wall portion 301 of the boiler case 30 and is connected to the plate-like wall portion 342 of the partition wall 34. A sensor 35 for measuring the vapor pressure is arranged in the vapor passage forming part 32.

  A circulation passage 33a communicates with the low pressure chamber 309. The circulation passage forming portion 33 that forms the circulation passage 33 a is connected to the upper wall portion 301 of the boiler portion case 30.

  A space located between the tubes 303 and 304 of the boiler case 30 and the cylindrical wall portion 341 of the partition wall 34 in the low pressure chamber 309 constitutes a liquid reservoir chamber 309 a for storing the working fluid 14 supplied to the evaporation chamber 308. is doing. That is, the liquid reservoir chamber 309 a is disposed on the horizontal direction side of the evaporation chamber 308.

  The wick 17 is sandwiched between the bottom wall portion (lower wall portion) 302 of the boiler case 30 and the cylindrical wall portion 341 of the partition wall 34. The wick 17 is held in the boiler case 30 in a state where the wick 17 is compressed by receiving a load from the cylindrical wall portion 301.

  Since the bottom wall 302 of the boiler case 30 is thermally connected to the heating element 3, the wick 17 receives heat from the heating element 3 through the bottom wall 302 of the boiler case 30. Therefore, the bottom wall 302 of the boiler case 30 serves as a heat transfer member.

  The reflux part case 31 is disposed above the boiler part case 30. The output unit 12 is attached to the center of the lower surface of the reflux unit case 31. A circulation passage forming portion 33 that forms a circulation passage 33 a is connected to the outer peripheral side portion of the lower surface of the reflux portion case 31. The condensing unit 13 is configured by a space around the output unit 12 in the internal space of the boiler unit case 30.

  A sensor 36 for measuring the rotational speed of the fan 1d is fixed to the boiler case 30.

  According to the above configuration, the heat of the heating element 3 is transmitted to the hydraulic fluid 14 in the evaporation chamber 308 via the bottom wall portion 302 of the boiler unit case 30, and the hydraulic fluid 14 evaporates. The steam generated in the evaporation chamber 308 is supplied to the output unit 12 through the steam passage 32a. Thereby, the energy of the steam is converted into mechanical energy.

  Vapor discharged from the output unit 12 dissipates heat into the atmosphere at the condensing unit 13 and condenses, and the working fluid 14 condensed at the condensing unit 13 returns to the low-pressure chamber 309 through the circulation passage 33a and accumulates in the liquid storage chamber 309a. . The working fluid 14 accumulated in the liquid reservoir chamber 309a is sucked into the wick 17 and supplied to the evaporation chamber 308 to evaporate.

  Thus, also in this embodiment, the working fluid 14 in the liquid reservoir chamber 309a can be returned to the high-pressure evaporation chamber 308 without using external energy.

  Although illustration is omitted, also in the present embodiment, the exhaust passage 21 similar to that in the first and second embodiments can be formed in the bottom wall portion 302 of the boiler case 30. As a result, the vapor evaporated from the lower surface of the wick 17 can be easily escaped to the upper side of the wick 17, and the output can be improved.

(Fifth embodiment)
The fifth embodiment shows a specific configuration example of the through hole 172 of the wick 17 in each of the above embodiments.

  In the example of FIG. 12, the through-hole 172 that passes through the front and back of the wick 17 is formed in a groove shape extending in the plate surface direction of the wick 17. More specifically, the through hole 172 is formed in a cross groove shape extending radially from the center of the wick 17 in four directions.

  In the modification of FIG. 13, a large number of through holes 172 are dispersed. More specifically, the through-hole 172 is composed of a large number of circular holes, and the large number of circular holes are distributed on the plate surface of the wick 17.

  According to this, since steam is generated from the edge (interface) of the through-hole 172, the amount of steam can be improved, and the output can be improved. In particular, in the example of FIGS. 12 and 13, the entire length of the edge (interface) of the through hole 172 can be increased. For this reason, the amount of steam can be further improved, and as a result, the output can be further improved.

  In the examples of FIGS. 12 and 13, the plate 19 is a net plate. Thereby, even if the through-hole 172 is formed over a wide range, the wick 17 can be prevented from being lifted without hindering the release of vapor from the edge (interface) of the through-hole 172.

(Sixth embodiment)
In the sixth embodiment, a heat engine is applied to a solar power generator as shown in FIG. The solar power generator 40 is installed in a place where the light SL from the sun S1 is easy to hit, such as the roof of the house H1, and is roughly divided into a boiler unit 41, an output unit 42, and a condensing unit 43.

  In the boiler unit 41, the hydraulic fluid 44 is heated by solar heat and evaporated. The output unit 42 generates power using the steam evaporated in the boiler unit 41. The condensing unit 43 condenses the vapor that has passed through the output unit 42 to condense it. The working fluid 44 recovered by the condensing unit 43 is returned to the boiler unit 41.

  The boiler unit 41 includes a case 411 that forms an outer shell thereof, and a wick 412 that is disposed in a substantially central portion in the vertical direction in the case 411. The wick 412 divides the internal space of the case 411 into two upper and lower spaces 411a and 411b.

  A space 411 a formed on the lower side of the wick 412 in the case 411 constitutes a liquid reservoir chamber in which the working fluid 44 refluxed from the condensing unit 43 is accumulated. The lower surface of the wick 412 constitutes a suction part 412a that sucks the hydraulic fluid 44 in the liquid storage chamber 411a.

  A space 411b formed above the wick 412 in the case 411 constitutes an evaporation chamber in which the working liquid 44 is heated by solar heat and evaporated.

  The upper surface of the case 411 includes a glass window 411c that transmits sunlight SL. The glass window 411c functions as a sunlight intake unit that takes sunlight into the evaporation chamber 411b. The upper surface of the wick 412 constitutes a heat receiving portion 412b that is heated by receiving sunlight taken in from the glass window 411c.

  The wick 412 is configured such that the pressure ΔP due to the capillary force is larger than the pressure difference (PH−PL) between the pressure PH of the high-pressure evaporation chamber 411b and the pressure PL of the low-pressure liquid storage chamber 411a ( ΔP> PH-PL). Accordingly, the wick 412 can suck the hydraulic fluid 14 in the low-pressure reservoir chamber 411a by the capillary force and supply it to the high-pressure evaporation chamber 411b.

  In this example, the wick 44 is a fiber assembly having a plurality of fiber layers stacked on each other, and is composed of a mixture of aramid fibers, which are thermoplastic resin fibers, and rock wool particles. Similar to the second embodiment, the fiber layers of the wick 44 are laminated from the suction part 412a side toward the heat receiving part 412b side. In other words, the wick 44 has a structure in which a portion having high continuity of the gap and a portion having low continuity of the gap appear alternately from the suction portion 412a side to the heat receiving portion 412b side.

  The output unit 42 includes a steam passage 421 that communicates with the evaporation chamber 411b, and a generator 422 that is driven by the steam that flows into the steam passage 421 from the evaporation chamber 411b. The generator 422 includes a mechanism such as a steam turbine or a pendulum engine that converts steam energy into mechanical energy, and generates power using the mechanical energy converted by the mechanism.

  The condensing unit 43 has a cooler 431 that condenses the vapor that has passed through the generator 422 and condenses it into the working fluid 44. The internal space of the cooler 431 communicates with the liquid storage chamber 411a of the boiler unit 41. Thereby, the working fluid 44 recovered by the cooler 431 is returned to the liquid storage chamber 411 a of the boiler unit 41.

  According to the present embodiment, power can be generated by solar energy without using a solar cell that requires advanced technology and production equipment. Therefore, energy saving and clean energy can be easily realized.

(Other embodiments)
In the first to third embodiments, the condensing unit 13 is disposed on the upper side of the case 15. However, the present invention is not limited thereto, and for example, the condensing unit 13 is disposed on the side of the case 15. May be. The specific configuration of the outflow path 151a for allowing the vapor of the low-pressure chamber 157 to flow out to the condensing unit 13 and the recirculation path 151b for returning the working fluid 14 condensed in the condensing unit 13 to the low-pressure chamber 157 is as follows. The number can be changed as appropriate according to the arrangement position of 13.

  Moreover, in each said embodiment, although the boiler part 11 is accommodated in the single case, it divides | segments and accommodates the boiler part 11 in several cases, and connects several cases with piping suitably. It may be. For example, the liquid storage chamber 157a of the boiler unit 11 may be housed in a separate case, and the liquid storage chamber 157a and the evaporation chamber 156 may be connected by piping. In this case, the wick 17 can be disposed in a pipe connecting the liquid reservoir chamber 157a and the evaporation chamber 156.

  Moreover, in the said 1st Embodiment, although the wick 17 is comprised with the mixture of the aramid fiber (resin fiber) and the rock wool particle | grains, as the wick 17, it is a structure containing a fiber, Comprising: A space | gap is enough. Various types that are small and excellent in heat resistance can be used.

  In the first embodiment, since a thin material having a thickness of about 4 mm is used as the plate-like material W1, the plate-like material W1 is cut into a large number of disk-shaped materials W2, and a large number of disk-shaped materials W2 are obtained. The wick 17 having a predetermined thickness is formed by laminating and joining. If the thickness of the plate-like material W1 is sufficient, the wick 17 having the predetermined thickness can be formed by simply cutting the plate-like material W1 into a circular shape. Can be molded.

  Moreover, in the said 1st Embodiment, although the shape of the wick 17 is disk shape, it can change into not only this but a various shape. For example, a plate shape such as a triangle or a square may be used, or a bent column shape may be used.

3 Heating element (external heat source)
DESCRIPTION OF SYMBOLS 11 Boiler part 12 Output part 13 Condensing part 14 Hydraulic fluid 15 Case 16 Partition 17 Wick (member for hydraulic fluid introduction)
19 Plate (heat transfer plate)
21 Exhaust passage 23 Exhaust passage forming member 152 Bottom wall (heat transfer member)
152a Heat insulation groove 156 Evaporation chamber 157a Reservoir chamber 161 Cylindrical wall (load applying means)
172 Through hole

Claims (17)

The working fluid (14) is heated by the heat supplied from the external heat source (3) to generate the vapor of the working fluid (14), and is supplied to the evaporation chamber (156, 308). A boiler section (11) in which a liquid reservoir chamber (157a, 309a) for storing the hydraulic fluid (14) is formed;
An output section (12) through which the steam generated in the evaporation chamber (156, 308) flows and converts the energy of the steam to mechanical energy and takes it out;
A condensing unit (13) for condensing the vapor that has passed through the output unit (12), and refluxing the condensed working fluid (14) to the liquid storage chamber (157a, 309a);
A member for introducing hydraulic fluid that is disposed in the boiler section (11) and sucks the hydraulic fluid (14) in the liquid reservoir chambers (157a, 309a) by capillary force and supplies the hydraulic fluid (14) to the evaporation chamber (156, 308). (17)
The evaporation chambers (156, 308) are separated from the liquid reservoir chambers (157a, 309a) and have a higher pressure than the liquid reservoir chambers (157a, 309a),
The hydraulic fluid introduction member (17)
(2σ / r) · cos θ> PH-PL
Configured to satisfy the relationship
The working fluid introduction member (17) receives heat from the suction portion (175) for sucking the working fluid (14) in the liquid reservoir chamber (157a, 309a) and the heat received from the external heat source (3). Part (176),
Further, the hydraulic fluid introduction member (17) has different continuity of the gap depending on a part, and a part having a high continuity of the gap from the suction part (175) side toward the heat receiving part (176) side. Having a structure in which low-continuity portions of the voids appear alternately,
The hydraulic fluid introduction member (17) is interposed in a heat transfer path from the external heat source (3) to the liquid reservoir chambers (157a, 309a), and from the external heat source (3) to the liquid reservoir chamber (157a). , 309a) to suppress the heat transfer to the hydraulic fluid (14) .
However, (sigma) is the surface tension of the said hydraulic fluid (14), r is the circle | round | yen equivalent radius of the space | gap in the said hydraulic fluid introduction member (17), (theta) is the said hydraulic fluid (14) with respect to the said hydraulic fluid introduction member (17). ), The wetting angle, PH is the pressure in the evaporation chambers (156, 308), and PL is the pressure in the liquid reservoir chambers (157a, 309a). The hydraulic fluid introduction member (17) has a plurality of fiber layers stacked on each other,
The plurality of fiber layers of the hydraulic fluid introduction member (17) are laminated from the suction part (175) side toward the heat receiving part (176) side,
Of the hydraulic fluid introduction member (17), the portion where the continuity of the gap is high is an interface portion between the fiber layers,
2. The heat engine according to claim 1, wherein a portion of the hydraulic fluid introduction member (17) where the continuity of the gap is low is a portion constituting the fiber layer. The hydraulic fluid introduction member (17) is formed in a flat plate shape whose plate surface extends in parallel with the direction in which the fiber layer extends,
The suction part (175) is composed of one plate surface of the hydraulic fluid introduction member (17),
The heat engine according to claim 2, wherein the heat receiving portion (176) is configured by the other plate surface of the hydraulic fluid introduction member (17). The boiler part (11) is in contact with the heat receiving part (176) of the hydraulic fluid introduction member (17), and transfers heat from the external heat source (3) to the hydraulic fluid introduction member (17). A thermal member (152, 23, 302);
Of the heat transfer member (152, 23, 302), the steam generated from the hydraulic fluid introduction member (17) is transferred to the hydraulic fluid introduction member (17) at a portion in contact with the heat receiving portion (176). The heat engine according to any one of claims 1 to 3 , characterized in that an exhaust passage (21) for exhausting air to the outside is formed. The heat engine according to claim 4 , wherein the exhaust passage (21) is constituted by a groove (22) formed in the heat transfer member (152). The heat transfer member (152, 23) is divided and formed into an exhaust passage forming member (23) that forms the exhaust passage (21) and a member (152) that forms the remaining portion,
The exhaust passage forming member (23) is a net member or a plurality of ball members sandwiched between a member (152) constituting the remaining portion and the hydraulic fluid introduction member (17),
The heat engine according to claim 4 , wherein the exhaust passage (21) is configured by a gap formed by the mesh member or the plurality of ball members. The heat transfer member (152, 23, 302) has an upper surface portion extending in the horizontal direction,
The hydraulic fluid introduction member (17) is formed in a flat plate shape and is superimposed on the upper surface of the heat transfer member (152, 23, 302),
Said hydraulic fluid introducing member (17) is any one of claims 4 to 6, characterized in that heat from the external heat source (3) through said heat transfer member (152,23,302) The listed heat engine. The boiler section (11) is superimposed on a surface of the hydraulic fluid introduction member (17) opposite to the heat transfer member (152, 23, 302), and the heat from the external heat source (3) is 8. The heat engine according to claim 7 , further comprising a heat transfer plate (19) for transmitting the working fluid introduction member (17). A boiler case (30) for housing the boiler part (11);
A reflux part case (31) for accommodating the output part (12) and the condensing part (13);
A steam passage forming portion (32) that forms a steam passage (32a) that connects the evaporation chamber (308) of the boiler portion (11) and the output portion (12);
A circulation passage forming portion (33) that forms a circulation passage (33a) communicating the condensing portion (13) and the liquid storage chamber (309a) of the boiler portion (11);
The boiler part case (30) and the reflux part case (31) are arranged so as to be separated from each other and connected via a steam passage forming part (32) and a circulation passage forming part (33). The heat engine according to any one of claims 1 to 8 . Wherein the site located inside the evaporation chamber (156) of the hydraulic fluid introducing member (17), according to claim 7 or, characterized in that the through-hole penetrating the front and back (172) is formed 8. The heat engine according to 8 . The heat engine according to claim 10 , wherein the through hole (172) communicates with the exhaust passage (21). The heat engine according to claim 10 or 11 , wherein the through hole (172) is formed in a groove shape extending in a plate surface direction of the hydraulic fluid introduction member (17). The heat engine according to claim 10 or 11 , wherein a large number of the through holes (172) are dispersed. The boiler section (11) has load applying means (161) for applying a load to the hydraulic fluid introduction member (17) so that a gap in the hydraulic fluid introduction member (17) is reduced.
Said hydraulic fluid introducing member (17), of claim 1 to 13, characterized in that it is held in the said boiler part in a state in which the load is applied from the load-applying means (161) (11) The heat engine as described in any one. The boiler part (11) has a partition wall (16) separating the evaporation chamber (156) and the liquid storage chamber (157a),
The partition wall (16) is disposed in the boiler part (11) so as to apply the load to the hydraulic fluid introduction member (17),
The heat engine according to claim 14 , wherein the load applying means (161) is constituted by the partition wall (16). The heat engine according to any one of claims 1 to 15 , wherein the hydraulic fluid introduction member (17) is made of a material woven with at least resin fibers. The evaporation chamber (411b) heats the hydraulic fluid (44) with heat obtained from sunlight to generate vapor of the hydraulic fluid (44) ,
The boiler part (41) has a sunlight intake part (411c) for taking the sunlight into the evaporation chamber (411b),
It said hydraulic fluid introducing member (412) is claims 1, characterized in that it has the solar light intake portion receiving portion which is heated by the sunlight which is introduced from (411c) (412b) The heat engine according to any one of 16 .

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