DE102011053570A1 - Heat machine for heating hydraulic fluid in waste heat recovery device, has steam generator part that is provided with liquid collection portion and evaporation part - Google Patents

Abstract

The heat machine has a steam generator part (11) that is provided with a liquid collection portion (111) and evaporation part (112). A condensation part is provided to condense the steam, which is passed to output part (12), where condensed hydraulic fluid (14) leads back to the liquid collection portion. The liquid collection portion is formed in an inner side or outer side of components for introducing hydraulic fluid (16).

Description

BACKGROUND OF THE INVENTION

Technical field of the invention

The present invention relates to a heat engine that heats a hydraulic fluid to vaporize it and returns a condensed vapor after extracting energy as mechanical energy from the vaporized vapor, and which is suitable for use in a waste heat recovery device.

DESCRIPTION OF THE RELATED TECHNIQUE

In a conventional heat engine, an evaporation part (evaporation chamber) where the hydraulic fluid is evaporated is pressurized while a condensation part condensing the vapor (reliquefaction) is pressurized with low pressure.

Then, generally, an apparatus such as a pump for returning the hydraulic fluid to the evaporation part which is condensed at the condensing part is used (for example, refer to FIGS JP 8-338207 ).

That is, the hydraulic fluid in the condensing part is returned to the evaporating part by pressurized feeding using the pump, etc., which is operated by external power.

In the heat engine, which returns the hydraulic fluid condensed in the condensing part to the evaporating part using the mechanism such as the above-mentioned pump, the external power for driving the device such as the pump also becomes external energy (Thermal energy) is needed, which heats the hydraulic fluid for evaporation, whereby an improvement of the output efficiency is limited.

SUMMARY OF THE INVENTION

The present invention has been made in light of the above-mentioned problems and has an object to provide a heat engine having an excellent output efficiency.

In a heat engine according to a first aspect, the heat engine has a boiler part which includes a liquid collecting part where a hydraulic fluid is collected, an evaporation part where the hydraulic fluid supplied from the fluid collecting part is heat-exchanged by a hydraulic fluid external heat source is provided, is evaporated, an output part, where the steam which is generated in the evaporation part, circulates and converts the thermal energy of the steam into mechanical energy and removes, and has a condensation part, which the steam, the The discharge part passes, condenses, and returns the condensed hydraulic fluid to the liquid collecting part.

The steam generator part has a component for introducing a hydraulic fluid, which supplies the hydraulic fluid, which is absorbed by capillary force in the fluid-collecting part, to the evaporating part.

The hydraulic fluid introducing member is formed cylindrically to have an inner circumferential surface and a circumferential surface, wherein the liquid collecting member is formed in any one of inside and outside of the hydraulic fluid introducing member, the evaporating member being in the vicinity of the inner circumferential surface of the component for introducing the hydraulic fluid is formed when the liquid collecting part is formed outside the component for introducing the hydraulic fluid, and wherein the evaporation part is formed in the vicinity of the peripheral surface of the component for introducing the hydraulic fluid when the fluid collecting part is formed within the member for introducing the hydraulic fluid ,

Accordingly, since the components for introducing the hydraulic fluid absorb the hydraulic fluid in the fluid collecting part by the capillary force to the vaporization part, the hydraulic fluid condensed on the condensation part can be returned to the high pressure vaporization part using as little external energy as possible.

In addition, since the components for introducing the hydraulic fluid are formed cylindrically, and the evaporation part in the vicinity of a surface opposite to the liquid collecting part of the inner peripheral surface and the peripheral surface of the hydraulic fluid introducing members, the evaporation part can be far secured and the thermal Conductivity can be improved and, as a result, this speeds up the evaporation of the hydraulic fluid.

From the above, the heat engine can be achieved with excellent output efficiency.

In the heat engine according to a second aspect, the hydraulic fluid reaches the inner circumferential surface of the hydraulic fluid introducing member when the liquid collecting member is formed outside the hydraulic fluid introducing member, and the hydraulic fluid reaches the peripheral surface of the hydraulic fluid introducing member when the fluid collecting member is inside of the hydraulic fluid injecting member, and the steam generator part has a hydraulic fluid evaporation part which absorbs the hydraulic fluid absorbed by a capillary force weaker than a capillary force of the hydraulic fluid introducing parts by the heat is provided by the external heat source, evaporates.

In the heat engine according to a third aspect, the porosity within the material for the evaporation of the hydraulic fluid is higher than the porosity within the component for introducing the hydraulic fluid.

In the heat engine according to a fourth aspect, the thermal conductivity of the material for the evaporation of the hydraulic fluid is set higher than the thermal conductivity of the components for introducing the hydraulic fluid.

In the heat engine according to a fifth aspect, the steam generator part has a heat transfer material which transfers the heat of the external heat source to the material for the evaporation of the hydraulic fluid, and the material for the evaporation of the hydraulic fluid is connected to both the components for introducing the hydraulic fluid and the heat transfer material in contact.

In the heat engine according to a sixth aspect, the components for introducing the hydraulic fluid are formed with an insulating material which suppresses the heat transfer from the external heat source to the hydraulic fluid in the fluid collecting part.

In the heat engine according to a seventh aspect, a heat insulator which suppresses the heat transfer from the external heat source to the hydraulic fluid in the fluid-collecting part is disposed at both ends in an axial direction of the hydraulic fluid introducing members.

In the heat engine according to an eighth aspect, the hydraulic fluid injecting member is a cylindrical member that extends horizontally, the fluid collecting member is positioned inside the hydraulic fluid introducing members, and the evaporating member is formed near the circumferential surface of the hydraulic fluid introducing members.

In the heat engine according to a ninth aspect, the hydraulic fluid injecting member is a cylindrical member which is vertically extended, the fluid collecting member is positioned outside the hydraulic fluid introducing member, and the evaporating member is located near the inner peripheral surface of the hydraulic fluid introducing member educated.

KUZRZE DESCRIPTION OF THE DRAWINGS

1 Fig. 10 is a cross-sectional view of a waste heat recovering apparatus in a first embodiment of the present invention;

2 Fig. 10 is a cross-sectional view of a waste heat recovering apparatus in a first embodiment of the present invention;

3A - 3C FIG. 12 is a cross-sectional view of an engine of the exhaust heat recovery apparatus in the first embodiment of the present invention; FIG.

4A - 4E explain a manufacturing process of a wick in the first embodiment of the present invention; and

5 FIG. 10 is a cross-sectional view of the waste heat recovering apparatus in the second embodiment of the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

First Embodiment

With reference to the 1 to 4 Hereinafter, the first embodiment of the present invention will be described.

In the present embodiment, a heat engine of the present invention is applied to a waste heat recovery device.

1 and 2 FIG. 15 are cross-sectional views of a construction of the exhaust heat recovery apparatus and arrows in FIG 1 and 2 show a top-bottom (vertical direction) direction of the waste heat recovery device when installed.

The cutting planes differ by 90 ° in 1 and 2 ,

The waste heat recovery device 10 in the present embodiment is coarse from a steam generator part 11 , an output part 12 and a condensation part 13 built up.

To a mechanical energy, which from the waste heat recovery device 10 is used to generate electricity is a generator 1 in the waste heat recovery device 10 arranged in the present embodiment. The generator 1 is in 2 Not shown.

The steam generator part 11 vaporizes a hydraulic fluid 14 (Water in the present embodiment) by heat (waste heat), which is provided by an external heat source, and provides the vapor of the hydraulic fluid 14 passing through the steam generator part 11 is generated, the output part 12 to disposal.

The energy of the steam, which through the steam generator part 11 is made available, is converted into mechanical energy and to the output part 12 output.

A condensation part 13 condenses the steam after passing through the output part 12 passes, which then into the hydraulic fluid 14 is reliquefied.

Then the liquefied hydraulic fluid 14 back to the steam generator part 11 recycled.

As a result, the condensation part 13 be expressed as a return flow part.

The steam generator part 11 has a housing 110 which is formed as in block.

As water as the hydraulic fluid 14 is used in the present embodiment, it is desirable to the housing 110 with stainless steel or stainless steel, which is excellent in corrosion resistance.

The housing 110 is on or on a heat source 3 brought, which is the external heat source.

In the present embodiment, the heat source generates 3 the heat from the waste heat that comes from factories.

Side walls of the housing 110 are with a heat indicator 15 covered.

The housing 110 is constructed by fixing a plurality of components by fastening and wicks 16 , which correspond to components for introducing the hydraulic fluid, are included therein.

Specifically, three wick receiving holes are formed in a columnar shape, which are horizontal in the housing 110 extend, and every cylindrical wick 16 is included in each of the three wick receiving holes.

Here, the component for introducing the hydraulic fluid is defined as a component which has capillary force, which is the hydraulic fluid 14 absorbed, generated (capillary force generating member), which is, for example, a porous medium such as a porous ceramic and sintered material.

In the present embodiment, the wick receiving hole is columnar, and the wick 16 is cylindrical.

The wick 16 may be constructed of a cylindrical member or may be constructed of a plurality of cylindrical components.

In other words, the wick can 16 be formed unitary and the wick 16 can be formed separated or divided in an axial direction.

The wick 16 is a mixture of a fiber assembly (laminated fiber layer) having a plurality of fiber layers which are mutually laminated, and is a mixture of aramid fibers and rock wool particles which are a thermoplastic resin fiber in the present embodiment.

In addition, the wick can 16 a mixture of aramid fibers and glass wool particles.

Here, the mixture of the aramid fibers of the rock wool particles and the mixture of the aramid fibers and the glass wool particles can be used as the heat insulating material.

The wick 16 is uniformly formed by joining a plurality of laminated ring plate-like materials.

In 2 For example, interface parts of the ring plate-like materials are shown by a solid line for the purpose of showing.

In addition, the interface parts of the ring plate-like materials of the wick 16 in a radial direction of the wick 16 (a direction crossing the axial direction at right angles).

Although not shown, each fibrous layer of the wick extends 16 parallel to the interface part of the ring plate-like material.

Accordingly, each fiber layer of the wick extends 16 in the radial direction of the wick 16 (The direction crosses the axial direction at right angles).

An interior of the wick 16 builds a fluid collection part 111 on where the hydraulic fluid 14 is collected.

The hydraulic fluid 14 in the liquid collecting part 111 is from an inner circumferential surface of the wick 16 by capillary force of the wick 16 absorbed.

Both heat insulators 17 are at both ends in an axial direction of the wick 16 arranged as in 2 is shown.

In the present embodiment, the heat insulators 17 on the housing 110 fixed by fixing, and has a structure that the wick receiving holes of the housing 110 with the heat insulators 17 are closed.

That is, a receiving member, which the wicks 16 is from the housing 110 and the heat insulators 17 built up.

The heat insulators 17 and the wicks 16 play the role of interrupting the heat transfer from the heat source 3 to the hydraulic fluid 14 in the liquid collecting part 111 ,

That is, the wicks 16 act as a heat insulator because the wicks 16 of the present embodiment are formed of an insulating material having excellent thermal insulation.

An exhaust gas passage forming material 18 is between a peripheral surface of the wick 16 and an inner wall surface of the wick receiving hole of the housing 110 arranged.

The components forming the exhaust gas passage 18 form exhaust gas passages 18a , which is the vapor of the hydraulic fluid 14 suck off or dissipate.

The components forming the exhaust gas passage 18 are formed of a metal excellent thermal conductivity, etc., and practice the heat transfer or the heat transfer on the peripheral surface of the wick 16 from the case 110 out.

That is, heat from the heat source 3 through the housing 110 and the exhaust passage forming components 18 on the peripheral surface (side opposite to the liquid collecting part 111 ) of the wick 16 Will be received.

Then that's in the wick 16 absorbed hydraulic fluid 14 heats and vaporizes near the peripheral surface of the wick 16 ,

As a result, near the peripheral surface of the wick 16 an evaporation part 112 built up where the hydraulic fluid 14 is evaporated.

In the embodiment of the 1 and the 2 becomes a plurality of bead-shaped or spherical materials as the exhaust passage forming components 18 used.

For example, a bearing ball with a diameter of ∅3 may be used as the spherical material.

A gap through which the vapor can circulate is between the peripheral surface of the wick 16 and the inner wall of the wick receiving hole of the housing 110 using a plurality of spherical materials as the exhaust passage forming members 18 formed, and the gap acts as the exhaust passage 18a ,

In addition, a net-like material may be used as the components forming the exhaust gas passage 18 be used.

For the net-like material, a woven wire mesh is appropriate and, for example, a stainless mesh made of a wire having a diameter of 0.5 millimeter can be used.

The woven wire mesh is a wire mesh having vertical joints and horizontal joints with a uniform gap, and the wires are interwoven alternately one after the other woven.

The vertical connections and the horizontal connections of the woven wire mesh are formed in a wave-like shape.

As a result, rolling the woven wire mesh on the peripheral surface of the wick 16 a gap through which the vapor can circulate between the peripheral surface of the wick 16 and the inner wall of the wick receiving hole of the housing 110 formed and the gap acts as the exhaust passage.

The wick 16 is obtained by receiving the load in the axial direction from the heat insulators 17 when connected to the steam generator section 11 be attached, compressed or compressed.

In addition, the wick swells 16 through the hydraulic fluid 14 at. As a result, the gap of the wick 16 further compressed.

A pressure difference occurs through a capillary phenomenon in the wick 16 on.

The pressure difference caused by the capillary phenomenon will hereafter be a pressure ΔP by the capillary force of the wick 16 called.

The pressure ΔP due to the capillary force of the wick 16 is shown by the following expression (1). ΔP = (2σ / r) · cosθ (1)

Here, r is an equivalent circle radius (narrow tube radius) of the gap in the wick 16 , σ is a surface tension and θ is a wetting angle.

The equivalent circle radius is a radius of a circle having the same area as a target section.

The equivalent circle radius r of the gap in the wick 16 in the above-mentioned expression (1) is achieved by compressing the gap of the wick 16 as mentioned above, so that the pressure ΔP is due to the capillary force of the wick 16 becomes larger (ΔP> PH - PL) than a pressure difference (PH - PL) of a pressure PH in the evaporation part 112 (near the peripheral surface of the wick 16 ) and a pressure PL of the liquid collecting part 111 ,

In other words, the wick is 16 constructed to satisfy the relationship of the following expression (2). (2σ / r) <* cosθ> PH - PL (2)

steam passages 110a and 110b are in the case 110 of the steam generator part as in 1 shown is formed.

The steam passages 110a and 110b are for guiding the steam from the exhaust gas passage 18a to the output part 12 ,

The steam passage 110a is horizontally extended to mutually connect the upper part of the three wick receiving holes.

An end to the steam passage 110b stands with the steam passage 110a in communication and another end is upwards in a vertical direction, extending to an upper surface of the housing 110 to open.

A housing 120 of the output part 12 is on the steam generator part 110 set.

This will heat from the heat source 3 through the steam generator part 11 to the output part 12 transfer.

As in the present embodiment, water as the hydraulic fluid 14 is used, it is desirable, the output part housing 120 made of stainless steel or stainless steel, which is outstanding in its corrosion resistance.

The present embodiment has a structure that a bottom surface of the dispensing part housing 120 through an upper wall of the steam generator housing 110 is closed.

Sealing members, etc. (not shown) are used for securing the dispensing part housing 120 and the steam generator housing 110 ,

As a result, airtightness of an inner space of the dispensing part housing becomes 120 secured or secured.

Side walls and an upper wall of the dispenser housing 120 are with the heat insulator 15 covered.

A machine 121 is in the inner space of the dispenser housing 120 arranged.

The machine 121 is in the present embodiment on an upper wall of the steam generator sub-housing 110 by a plate-like base component 19 attached.

In the machine 121 of the output part 12 For example, in the present embodiment, a pendulum type machine swinging a piston and a cylinder like a pendulum is used. A steam turbine etc. can be used instead of the machine 121 be used.

The 3A to 3C show cross-sectional views of the machine 121 ,

The machine 121 has a piston 122 and a cylinder 123 ,

The cylinder 123 is about a swing axis or axis of rotation 125 on a cylinder base 124 , which on the base component 19 is fixed, swinging supported.

supply passages 19a and 124a , which with the steam passages 110a and 110b the steam generator part 11 are in the base member 19 and the cylinder base 124 educated.

The feed passages 19a and 24a are passages where the in the cylinder 123 absorbed steam flows.

In addition, there is an exhaust passage 124b in the cylinder base 124 educated.

The exhaust passage 124b is a passage where the steam coming out of the cylinder 123 flows or is ejected, flows.

Output parts of the feed passages 19a and 124a and an inlet portion of the exhaust passage 124b are on an upper surface of the cylinder base 124 open. The exit part of the exit passage 24b is to the inner space of the dispensing part housing 120 open.

The piston 122 and the cylinder 123 are arranged horizontally in the present embodiment and the pivot axis 125 is arranged vertically.

As a result, the piston swing 122 and the cylinder 123 in a horizontal plane.

A connection 123a where the steam is absorbed and expelled is at a bottom of the cylinder 123 open.

In the state in which the cylinder 123 is positioned at one end side of the swinging direction, the terminal is 123a with the feed passages 19a and 124a connected.

In the state in which the cylinder 123 positioned at another end side of the swing direction is the port 123a with the exhaust passage 124b connected.

If the cylinder 123 is positioned at the one end side of the swing direction and the connection 123a with the feed passages 19a and 124a communicates, flows the steam of the steam passages 110a and 110b the steam generator part 11 in the cylinder 123 and pushes the cylinder 122 out to move back and forth.

A tip portion and a front end portion of the piston, respectively 122 is about a staff 126 with a gear 127 connected.

As in 1 and in 2 shown is the gear 127 with a central gear or center gear 128 engaged.

An output wave 129 is at a middle of the center gear 128 attached.

This will rotate the output shaft 129 through the gear 127 and the center gear 128 when the piston 122 is pushed out.

In addition, it vibrates by the fact that the gear 127 by pushing the piston out 122 is turned, the cylinder 123 toward the other end side of the swing direction and the port 123a is through the top surface of the cylinder base 124 locked.

If the connection 123a is locked, drives the gear 127 by inertial forces continue to turn, and the piston 122 is due to the inertial forces of the gear 127 pushed back and moved back and forth. In this case, the swinging of the cylinder 123 continued.

Then, if the cylinder 123 positioned at the other end side of the swinging direction and the connection 123a with the exhaust passage 124b communicates, the steam in the cylinder 123 in the interior of the dispensing part housing 120 pushed out.

Although the machine 121 in the embodiment of 1 and 2 is a multi-cylinder engine, which consists of a plurality of cylinders 123 is built, the machine can 121 from a cylinder 123 be constructed.

The output wave 129 of the output part 12 and a rotary shaft 1a of the generator 1 are by a magnetic coupling through the top wall of the housing 120 connected.

Electricity is generated by the generator 1 by a rotation of the rotary shaft 1a generated.

The electrical power generated is any electrical equipment (not shown) connected to the generator 1 connected, provided.

The condensation part 13 has a condensation tank 130 , which outside of the steam generator sub-housing 110 and the dispensing part housing 120 as in 2 is shown is arranged.

The condensation tank 130 is constructed of a longitudinal container and on the side of the steam generator sub-housing 110 and the dispensing part housing 120 arranged.

As water as the hydraulic fluid 14 is used in the present embodiment, it is desirable to use the condensation tank 130 made of stainless steel or stainless steel, which is outstanding in its corrosion resistance.

An entry section 130a of the vapor, which is the output part 12 has happened is in the upper part of the condensation tank 130 educated.

The entrance part 130a is with a steam outlet 120a connected in the upper part of the dispensing part housing 120 is formed, through an inlet-side pipe 131 ,

As a result, the steam coming from the machine 121 to the interior of the dispensing part housing 120 is discharged into the condensation tank 130 stream.

In the condensation tank 130 The incoming steam radiates heat into the atmosphere and is condensed (re-liquefaction).

An exit part 130b the condensed hydraulic fluid 14 is in the bottom of the condensation tank 130 educated.

The starting part 130b is with a feed passage 113 , which on the heat insulator 17 the steam generator part 11 through an outlet-side pipe 132 is formed, connected.

Because the Zuführpassage 113 with the liquid collecting part 111 can communicate, the Zuführpassage 113 the hydraulic fluid 14 which are in the condensation tank 130 is condensed into the liquid collecting part 111 through the outlet side pipe 132 and feed the insertion passage.

In the present embodiment, the insertion passage is 113 from the liquid collecting part 111 which extends in a horizontal direction on a part where the liquid collecting part 111 of the heat insulator 17 is horizontally formed, formed.

The starting part 130b of the condensation tank 130 is on the extension or extension of the Einführpassage 113 arranged and the output side pipe 132 is horizontal between the output part 130b and the feed passage 113 extends.

As a result, the output part communicate 130b of the liquid collecting part 111 and the condensation tank 130 linear or linearly connected to each other.

A steam delivery pipeline 133 is with the input side pipe 131 and the output side piping 132 connected.

The steam delivery pipeline 133 is arranged for discharging the vapor, which in the liquid collecting part 111 is generated, to the output side pipe 132 ,

A vacuum pipeline 134 is with an upper end portion of the condensation tank 130 connected.

An internal pressure of the waste heat recovery device can be reduced by a vacuum passing through the vacuum pipeline 134 is pulled before the waste heat recovery device is started.

The vacuum pipeline 134 is closed when the waste heat recovery device is operated and a hypobarfc condition is maintained.

Next is an outline of the manufacturing process of the wick 16 based on 4A to 4E explained.

First, plate-like materials W1, as in 4A shown, prepared.

The plate-like materials W1 are a fiber assembly (laminated fiber layer) having a plurality of fiber layers which are mutually laminated and formed into a predetermined thickness with a repetition of a process similar to papermaking.

In the present embodiment, the plate-like materials W1 are a mixture of aramid fibers and rock wool particles which are a thermoplastic synthetic resin fiber.

In addition, a thin material of about 4 millimeters in thickness is used as plate-like materials W1 in the present embodiment.

4B is an enlarged part of the A 4A ,

In 4B For clarity of illustration, interface parts between the fiber layers are shown by thin solid lines.

As in 4B is shown, a plurality of fiber layers constituting the plate-like materials W1 are laminated in a thickness direction of the plate-like materials W1.

In other words, the plurality of fiber layers composing the plate-like material W1 extend in parallel with a surface of the plate-like materials W1.

Next, annular plate materials W2 are obtained by cutting the plate-like material W1 as shown in FIG 4C is shown.

At this time, a dimension of an inner diameter and a dimension of an outer diameter of the annular plate materials W2 are aligned in the same dimensions.

Next, the annular plate materials W2 are laminated in the direction of thickness, as in FIG 4D is shown, and a cylindrically arranged body W3 is obtained.

In the cylindrical body W3 as obtained in this way, the fiber layer is extended in a radial direction (a direction crossing at right angles the axial direction).

Next, the cylindrical wick 16 can be obtained by bonding the annular plate materials W2 of the disposed body W3 by setting a cylindrical body W3 in jigs J1, J2 and J3 and by heat-pressing the same, as in FIG 4E is shown.

In the wick 16 obtained in this way, the fiber layer is extended in a radial direction (one direction crosses the axial direction at right angles).

Furthermore, a continuity of the gap increases more than a remaining part (part which builds up the fiber layer) in the interface part in the fibrous layer of the wick 16 ,

Accordingly, the wick receives 16 the structure that the part having a high continuity of the gap is extended in a radial direction (a direction crossing at right angles the axial direction).

In the present embodiment, the jigs J1, J2 and J3 are made of a ring J1 made of stainless steel, a circular plate J2 made of a stainless steel, and a column J3 made of a stainless steel built up.

Processing temperatures for the heat compression are, for example, temperature: 300 ° C, pressing force: 50 tons and time of pressing: 20 minutes are desirable.

That is, the annular plate materials W2 can be mutually connected by heat-pressing at the temperature at which the aramid fiber of the annular plate materials W2 (thermoplastic resin) becomes soft.

The gap between fibers can be compressed by cooling while being compressed by adding the pressing force after the pressing time has elapsed.

In addition, adhesion of the fiber by cooling can be improved while being compressed with the addition of the pressing force, thereby improving the strength of the wick 16 can be improved.

In the steam generator part 11 becomes the heat of the heat source 3 on the peripheral surface of the wick 16 through the steam generator sub-housing 110 and the exhaust passage forming components 18 transferred, and the hydraulic fluid 14 in the liquid collecting part 111 is from the inner circumferential surface of the wick 16 absorbs and enters towards the peripheral surface of the wick 16 one.

As a result, the hydraulic fluid becomes 14 near the peripheral surface of the wick 16 heated and evaporated. The vapor, which is near the peripheral surface of the wick 16 is generated, the machine 121 of the output part 12 through the exhaust passage 18a and the steam passages 110a and 110b made available.

The machine 121 steam provided drives the piston 122 at.

As a result, the energy of the steam is converted into mechanical energy.

The output wave 129 turns by driving the piston 122 and the electricity gets through the generator 1 generated.

As a result, waste heat energy of the heat source 3 collected as electrical energy.

The steam in the machine 121 is through the exhaust passage 124b in the interior of the dispensing part housing 120 ejected after the piston 122 is driven.

The in the interior of the output part housing 120 from the machine 121 discharged steam flows into the condensation tank 130 of the condensation part 13 through the input-side pipeline 131 and is in the condensation tank 130 condensed and then into the hydraulic fluid 14 liquefied again.

The hydraulic fluid 14 which are in the condensation tank 130 is re-liquefied, returns to the liquid collecting part 111 the steam generator part 11 through the outlet side pipe 132 back.

As mentioned above, the hydraulic fluid becomes 14 , which in the liquid collecting part 111 is collected from the inner peripheral surface of the wick 16 absorbed and a vicinity of the peripheral surface (evaporation part 112 ) of the wick 16 provided and evaporated.

That is, because the capillary force, which is the hydraulic fluid 14 in the liquid collecting part 111 absorbed in the wick 16 is generated, the hydraulic fluid 14 the high-pressure evaporation part 112 from the low-pressure liquid collecting part 111 provided by the use of capillary force.

More specifically, in the steam generator section 11 the recirculated hydraulic fluid 14 in the low-temperature and low-pressure liquid collecting parts 111 in the high pressure evaporation section 112 through the capillary force of the wick 16 brought and drops of hydraulic fluid, which the evaporation part 112 have been achieved, are evaporated continuously.

Here, since the equivalent circle radius r of the gap in the wick 16 by decreasing the gap of the wick 16 is decreased to satisfy the above-mentioned expression (2), the pressure ΔP by the capillary force of the wick 16 greater (ΔP> PH - PL) than the pressure difference (PH - PL) of the pressure PH in the evaporation section 112 and the pressure PL of the liquid collecting part 111 ,

Thus, the capillary force of the wick overcomes 16 the pressure difference (PH - PL) of the pressure PH in the evaporation part 112 and the pressure PL of the liquid collecting part 111 , causing the hydraulic fluid 14 , which in the low pressure liquid collecting part 111 is collected, outstanding to the high pressure evaporation section 112 can be absorbed.

In other words, the hydraulic fluid 14 by adding the capillary force, which is not constrained by the pressure difference (PH - PL), using the wick 16 in the state in which the pressure difference between the liquid collecting part 111 and the evaporation part 112 occurs from the low pressure liquid collecting part 111 to the high pressure evaporation part 112 to be brought.

As a result, the hydraulic fluid 14 in the liquid collecting part 111 to the high pressure evaporation part 112 be returned without any use of external energy.

In addition, since the amount of evaporation of the hydraulic fluid 14 in the evaporation part 112 and the movement distance of the hydraulic fluid 14 from the liquid collecting part 111 the same is the Rückflußstrommengensteuerung or control of the hydraulic fluid 14 autonomous.

Accordingly, since the control mechanism for controlling the backflow amount of the hydraulic fluid 14 is unnecessary, the miniaturization of the device body and a cost reduction can be obtained.

Furthermore, since the gap of the wick 16 is reduced, prevents the steam, which in the evaporation part 112 is generated by the wick 16 backwards into the liquid collecting part 111 flows.

Here it is, since an evaporation point or boiling point of the hydraulic fluid 14 by a material of the hydraulic fluid 14 and the pressure within the dispenser housing 120 is determined, applicable, even if the temperature of the external heat source is below zero (freezing point) by using an alcohol for the hydraulic fluid 14 and around the interior of the dispenser housing 120 to shape as a vacuum.

As a heat resistance to the structures or structures such as the wick 16 and the evaporator part 11 (the output part housing 120 etc.) need not be given, when the temperature of the external heat source is low, a material which a has low heat resistance (resin or Kunsthatz etc.), as a material for the wick 16 and the evaporator part 11 be used.

According to the present embodiment, since the fibrous layer of the wick 16 in the radial direction from the inner peripheral surface side toward the circumferential surface side, the gap continuously extending from the inner peripheral surface side toward the circumferential surface side is formed between the fiber layers.

Consequently, since the circulation of the hydraulic fluid 14 to the peripheral surface of the inner peripheral surface can be improved, the supply of hydraulic fluid 14 from the liquid collecting part 111 to the evaporation part 112 be improved.

Especially since the wick 16 is cylindrical, assuming that the direction of extension of the fibrous layer is to be the radial direction in the present embodiment, the length of the passage of the hydraulic fluid 14 of the wick 16 be shortened or shortened as much as possible.

Consequently, since the circulation of the hydraulic fluid 14 to the peripheral surface of the inner circumferential surface can be further improved, the supply of hydraulic fluid 14 from the liquid collecting part 111 to the evaporation part 112 continue to be improved.

In addition, since the wick 16 is formed cylindrically, the hydraulic fluid 14 evenly each part of the evaporation part 112 from the liquid collecting part 111 to provide.

Furthermore, since the wick 16 is formed of the heat-insulating material and in a heat conversion route from the heat source 3 to the liquid collecting part 111 lies and there the heat insulator 17 at both ends in the axial direction of the wick 16 is arranged, the wick 16 the heat transfer from the heat source 3 to the hydraulic fluid 14 in the liquid collecting part 111 suppress.

Consequently, since the thermal insulation of the liquid collecting part 111 can be improved, the decrease in the output efficiency due to the evaporation of the hydraulic fluid 14 in the liquid collecting part 111 be suppressed.

In addition, since the wick 16 and the heat insulators 17 in the heat conversion route from the liquid collecting part 111 to the machine 121 a reduction in the temperature of the machine 121 due to the hydraulic fluid 14 in the liquid collecting part 111 be suppressed.

As a result, the decrease in the output efficiency can be due to the decrease of the vapor pressure in the engine 121 be suppressed.

In addition, since the wick 16 is cylindrical and receives the heat at the peripheral surface, a heat-receiving area of the wick 16 be secured to a high degree.

In other words, the evaporation part 112 be largely secured.

As a result, since the thermal conductivity can be improved, the output can be improved.

Moreover, lowering of the heating temperature by the thermal conductivity which is improved becomes possible.

A thermal change of the wick 16 can be suppressed by trying to lower the heating temperature.

Furthermore, the wick 16 in the manufacturing process (heat pressing) compresses and receives the load from the steam generator sub-housing 110 and is further compressed in the state in which the wick 16 on the steam generator part 11 is arranged.

In addition, the wick swells 16 through the hydraulic fluid 14 ,

As a result, since the gap of the wick 16 is minimized, prevents the steamer, which in the evaporator section 112 is generated, backward to the liquid collecting part 111 through the gap of the wick 16 flows.

That is, a seal of the steam can be secured.

Moreover, in the present embodiment, since the exhaust passage 18a on the peripheral surface of the wick 16 is formed, the vapor of the hydraulic fluid 14 , which in the peripheral surface of the wick 16 has evaporated through the exhaust passage 18a to the steam passages 110a and 110b pushed out.

As a result, since in the peripheral surface of the wick improves 16 vaporized steam can easily be induced from the steam passages 110a and 110b to escape, a release of the vapor of the hydraulic fluid 14 and consequently, the output can be improved.

Further, since the steam is further heated while passing through the exhaust passages 18a a superheated steam is increased and the steam pressure is increased, a thrust of the machine increases.

In other words, the output energy increases.

However, since the heat transfer area decreases when the exhaust gas passage 18a increases, the relationship between an exhaust gas property and the thermal conductivity is a balance.

In addition, since the condensation tank 130 of the condensation part 13 outside the steam generator sub-housing 110 and the dispensing part housing 120 is arranged in the present embodiment, the steam generator sub-housing 110 and the dispenser housing 120 with the heat insulators 15 be covered.

That is, the hydraulic fluid 14 can be condensed prominently by securing the heat radiation to the atmosphere without covering the condensation tank 130 with the heat insulator and the heat radiation to the atmosphere can be suppressed by covering the steam generator part 11 and the output part 12 with the heat insulators 15 ,

Accordingly, since the hydraulic fluid 14 efficient in the steam generator section 11 by the heat transfer from the heat source 3 to the steam generator part 11 and the output part 12 can be evaporated and the temperature of the steam (vapor pressure) in the machine 121 can be increased, the improvement of the output is tried or achieved.

Second Embodiment

It should be appreciated that in the second embodiment, the components which are identical to or similar to those in the first embodiment are given the same reference numerals for the purpose of omitting explanations.

In the first embodiment mentioned above, the cylindrical wick is 16 arranged horizontally extending, the liquid collecting part 111 is inside the wick 16 formed and the evaporation part 112 is near the inner circumferential surface of the wick 16 educated.

The cylindrical wick 16 however, it is arranged vertically extending (in a rectangular direction), the liquid collecting part 111 is outside the wick 16 formed and the evaporation part 112 is near the inner peripheral surface of the wick 16 in the second embodiment, which in 5 shown is formed.

Especially is the steam generator sub-housing 110 like a hollow cylindrical shape formed by fixing a plurality of components by tightening, and is arranged such that its axial direction becomes vertical.

The cylindrical wick 16 is in the interior of the steam generator sub-housing 110 recorded coaxially.

An inner diameter of the steam generator sub-housing 110 is made larger than an outer diameter of the wick 16 ,

As a result, an annular space serving as the liquid collecting part 111 acts between the inner peripheral surface of the steam generator sub-housing 110 and the peripheral surface of the wick 16 educated.

In the present embodiment, the introduction passage is 113 that the hydraulic fluid 14 , which in the condensation part 13 is condensed into the liquid collecting part 111 introduces, in a bottom wall of the steam generator sub-housing 110 educated.

A wicker stalk 115 as a heat transfer material is in a center hole of the wick 16 introduced.

The wicker stalk 115 is a columnar member extending in a vertical direction, and is formed with a material having a superior thermal conductivity (metallic material, etc.).

A bottom end part of the wick stalk 115 is through the bottom wall of the steam generator housing 110 performed and the heat is from the heat source 3 to the wicker stalk 115 transferred.

An upper end part of the wick stalk 115 Penetrates the upper wall of the steam generator sub-housing 110 and is arranged to the base member 19 of the output part 12 to contact.

An evaporation dream 20 , which is a material for the evaporation of the hydraulic fluid is between a peripheral surface of the wick stem 115 and the inner peripheral surface of the wick 16 sandwiched.

Here, the material for the hydraulic fluid evaporation is defined as a material which generates a capillary force weaker than that of the wick 16 and has excellent thermal conductivity, such as a structure with knitted metallic fibers or a porous material such as a sintered material, for example.

In the present embodiment, a straight stitched metal wire is used as the evaporation wire 20 used.

In other words, in the present embodiment, a double-structured wick is constructed by the insertion wick 16 for introducing the hydraulic fluid 14 and through the evaporation wick 20 for vaporizing the hydraulic fluid 14 ,

In the present embodiment, the capillary force of the evaporation wick becomes 20 more weakened than that of the wick 16 and the inner surface area of the evaporation dross 20 is achieved by increasing the porosity within the evaporation hole 20 more than the porosity within the wick 16 extended.

In addition, the thermal conductivity of the Verdampfungsdochtes 20 chosen higher than that of the wick 16 ,

As the evaporation wick 20 the inner circumferential surface of the wick 16 contacted or touched, the hydraulic fluid 14 that the inner circumferential surface of the wick 16 reached, through the evaporation wick 20 absorbs and spreads out and enters the gap in the evaporation wick 20 ,

In addition, as the evaporation wick 20 the peripheral surface of the wick stalk 115 touches the heat of the heat source 3 through the wicker stalk 115 on the evaporation wick 20 transfer.

The room where the evaporation wick 20 sandwiched (annular space) communicates with the inlet passages 19a and 124a of the output part 12 (it is related to 3 taken) through the steam passage 110b , which in the upper wall of the steam generator housing 110 is formed.

The heat of the heat source 3 is in the steam generator part according to the present embodiment 11 through the wicker stalk 115 on the evaporation wick 20 transfer.

The hydraulic fluid 14 in the liquid collecting part 111 becomes from the peripheral surface of the insertion hole 16 absorbs and reaches the inner peripheral surface of the insertion hole 16 ,

The hydraulic fluid 14 is then wicked through the evaporation 20 absorbs and vaporizes.

The one in the evaporation wick 20 generated steam becomes the machine 121 through the steam passage 110b in the steam generator sub-housing 110 and the introductory passages 19a and 124a in the output part 12 made available.

The machine 120 steam provided drives the piston 122 at. As a result, the energy of the steam is converted into mechanical energy.

The output wave 129 turns by driving the piston 122 and the electricity gets through the generator 1 generated.

As a result, waste heat energy of the heat source 3 as an electric energy in the present embodiment as well as in the first embodiment mentioned above.

Here is the operation and the function of the evaporation thief 20 explained.

The hydraulic fluid 14 , which from the peripheral surface of the Einführdochtes 16 is absorbed, and the inner peripheral surface of the Einführdochtes 16 is achieved, through the evaporation wick 20 absorbs and disperses and penetrates into the gap in the evaporation wick 20 one.

Because the heat of the heat source 3 through the wicker stalk 115 on the evaporation wick 20 is transferred, the hydraulic fluid 14 , which is distributed to the gap and penetrated into the gap, in the evaporation wick 20 heated and evaporated.

That is, the evaporation wick 20 the role is played to increase the heat transfer surface area, and it accelerates the evaporation of the hydraulic fluid 14 , As a result, the improvement of the output can be achieved.

In addition, since the evaporation wick 20 the peripheral surface of the introduction wick 16 contacted evenly, a localized squeezing or crushing, which on the peripheral surface of the Einführungsdochtes 16 is formed when the introduction wick 16 swells, be prevented.

Because the upper end part of the wick stalk 115 the basic component 19 of the output part 12 contacted in the present embodiment, the temperature of the steam (vapor pressure) in the machine 121 through the thermal conduction from the heat source 3 of the output part 12 can be increased, and accordingly, the improvement of the output can be obtained.

In the present embodiment, it can be suppressed that the hydraulic fluid 14 in the liquid collecting part 111 through the heat source 3 is heated and evaporated, by placing the heat insulator, which the heat transfer of the heat source 3 to the liquid collecting part 111 at both ends (the upper side and the lower side) in the axial direction of the insertion hole 16 as well as in the first embodiment mentioned above.

[Modifications]

In the first embodiment mentioned above, the plurality of spherical materials is 18 (the exhaust passage forming member) between the peripheral surface of the wick 16 and the inner wall of the wick receiving hole of the steam generator sub-housing 110 arranged.

The evaporation wick 20 however, (material for the evaporation of the hydraulic fluid) used for the evaporation in the second embodiment mentioned above may be used in place of the spherical material 18 (the exhaust passage forming member) are used.

In addition, although the condensation part can 13 (Condensation vessel 130 ) outside the dispenser housing 120 is arranged in each of the above-mentioned embodiments, the condensation part 13 within the dispenser housing 120 be arranged.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 8-338207 [0003]

Claims (9)

Heat engine comprising: a steam generator section ( 11 ), which a liquid collecting part ( 111 ), in which a hydraulic fluid ( 14 ) and an evaporation part ( 112 ), where the hydraulic fluid ( 14 ), which of the liquid collecting part ( 111 ) is provided by heat generated by an external heat source ( 3 ) is evaporated; an output part ( 12 ), where the vapor, which in the evaporation part ( 112 ) is generated, circulated, and energy of the steam is converted into mechanical energy and the mechanical energy is removed; and a condensation part ( 13 ), which the steam, which the output part ( 12 ), condenses, and the condensed hydraulic fluid ( 14 ) to the liquid collecting part ( 111 ); the steam generator part ( 11 ) a component for introducing a hydraulic fluid ( 16 ), which has the hydraulic fluid ( 14 ), which by a capillary force in the liquid collecting part ( 111 ) is absorbed to the evaporation part ( 112 ); the component for introducing the hydraulic fluid ( 16 ) is formed cylindrically to have an inner peripheral surface and a peripheral surface; wherein the liquid collecting part ( 111 ) in one of an inside or outside of the component for introducing the hydraulic fluid ( 16 ) is formed; wherein the evaporation part ( 112 ) in the vicinity of the inner circumferential surface of the hydraulic fluid introducing member ( 16 ) is formed when the liquid collecting part ( 111 ) outside the component for retracting the hydraulic fluid ( 16 ) is formed; and wherein the evaporation part ( 112 ) in the vicinity of the peripheral surface of the hydraulic fluid introducing member ( 16 ) is formed when the liquid collecting part ( 111 ) within the component for introducing the hydraulic fluid ( 16 ) is formed. Heat engine according to claim 1, wherein the hydraulic fluid ( 14 ) the inner circumferential surface of the component for introducing the hydraulic fluid ( 16 ) is reached when the liquid collecting part ( 111 ) outside of the component for introducing the hydraulic fluid ( 16 ) is formed; the hydraulic fluid ( 14 ) the circumferential surface of the component for introducing the hydraulic fluid ( 16 ) is reached when the liquid collecting part ( 111 ) within the component for introducing the hydraulic fluid ( 16 ) is formed; and the steam generator part ( 11 ) a component for a hydraulic fluid evaporation ( 20 ) due to the heat generated by the external heat source ( 3 ), the hydraulic fluid ( 14 ), which is absorbed by a capillary force which is weaker than a capillary force of the component for introducing the hydraulic fluid (FIG. 16 ). Heat engine according to claim 2, wherein a porosity within the material for the hydraulic fluid evaporation ( 20 ) is higher than a porosity within the component for introducing the hydraulic fluid ( 16 ). Heat engine according to claim 2 or 3, wherein the thermal conductivity of the material for the hydraulic fluid evaporation ( 20 ) is higher than the thermal conductivity of the component for introducing the hydraulic fluid ( 16 ). Heat engine according to one of claims 2-4, wherein the steam generator part ( 11 ) a heat transfer material ( 115 ) which has the heat of the external heat source ( 3 ) on the material for the hydraulic fluid evaporation ( 20 ) transmits; and the material for the hydraulic fluid evaporation ( 20 ) with both the component for introducing the hydraulic fluid ( 16 ) as well as the heat transfer material ( 115 ) is in contact. Heat engine according to one of claims 1-5, wherein the component for introducing the hydraulic fluid ( 16 ) is formed with an insulating material, which is a heat transfer from the external heat source ( 3 ) to the hydraulic fluid ( 14 ) in the liquid collecting part ( 111 ) is suppressed. Heat engine according to one of claims 1-6, wherein a heat insulator ( 17 ), which the heat transfer from the external heat source ( 3 ) to the hydraulic fluid ( 14 ) in the liquid collecting part ( 111 ) is suppressed at both ends in an axial direction of the hydraulic fluid introducing member (FIG. 16 ) is arranged. Heat engine according to one of claims 1-7, wherein the component for introducing the hydraulic fluid ( 16 ) is a cylindrical member which extends horizontally, the liquid collecting part ( 111 ) within the component for introducing the hydraulic fluid ( 16 ), and the evaporation part ( 112 ) in the vicinity of the peripheral surface of the hydraulic fluid introducing member ( 16 ) is formed. Heat engine according to one of claims 1-7, wherein the component for introducing the hydraulic fluid ( 16 ) is a cylindrical member which extends vertically, the liquid collecting part ( 111 ) outside of the component for introducing the hydraulic fluid ( 16 ), and the evaporation part ( 112 ) in the vicinity of the inner circumferential surface of the hydraulic fluid introducing member ( 16 ) is formed.

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