• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    It should be a free-piston Stirling cycle machine, comprising a hermetically sealed pressure housing (3) with a working section (I) and at least one of the working section (I) adjacent displacement (II) are provided, wherein in the interior of the working section (I) at least one Working piston (11 ') movable, forming part of a linear generator (1) is arranged and in at least one displacement section (II) as a regenerator (2) acting displacement piston is arranged so that when filling the pressure housing (3) with a working gas (11 ) and at the effect of a temperature difference between the displacer section (II) at elevated temperature (T2) and the rest of the pressure housing (3) at low temperature (T1, T1 <T2) mechanical work by the working piston (11 ') can be made and by the linear generator ( 1) is convertible into electrical energy. Further, a second displacement section (II ') with effective as a regenerator (2) displacer on the other side of the work section available. The regenerators (2) are permanently magnetic and can be moved by means of induction coils (5) in their position, whereby the regenerators (2) can move as a displacer in the power stroke.
    公开号:CH712956A2
    申请号:CH01262/16
    申请日:2016-09-27
    公开日:2018-03-29
    发明作者:Bertschi Daniel;Mafli Jörg
    申请人:Bertschi Daniel;Joerg Mafli;
    IPC主号:
    专利说明:

    description
    TECHNICAL FIELD The invention relates to a Stirling engine according to the preamble of claim 1.
    The Stirling machine or free-piston Stirling cycle machine, comprising a housing with a linear generator which separates the two with working gas-filled chambers in the middle. The invention converts thermal energy into electrical energy. In the text, for the sake of simplicity, the term Stirling machine is used instead of the free-piston cycle machine.
    PRIOR ART Stirling engines have been used as efficient thermomechanical devices for converting thermal energy into mechanical energy for around 200 years.
    Likewise, Stirling cycle cooling machines are used for converting mechanical energy into the pumping of thermal energy from a cooler temperature to a warmer temperature. These chillers are often connected to a linear motor or an alternator. A Stirling engine can drive a linear alternator for generating electrical energy. Conversely, a linear alternator can also drive a Stirling engine to generate cold.
    [0005] As described in DE 10 2008 041 076, a hermetically sealed housing is very important for the operation of a Stirling engine. The efficiency of the Stirling engine depends on the highest possible outlet pressure of the working gas. The Stirling engine described in the above patent is considered to be the closest prior art. Due to the complex internal structure of the Stirling engine described in document DE 10 2008 041 076, the technology must be enclosed in a pressure-resistant, higher-level housing. This pressure-resistant housing, which was specifically developed for this Stirling engine, represents a high cost factor because it is exposed to a double load of approx. 500 ° C due to the internal gas pressure and the heat energy supplied from outside. Therefore, the use of high-quality and therefore expensive materials is mandatory, which additionally complicate the weight of the Stirling engine. The aim of the Stirling engine according to the invention was therefore to introduce the construction into a simple geometric shape which withstands the pressures which occur and is available in commercially available dimensions and shapes.
    [0006] The Stirling engine described in DE 10 2008 041 076 works like all other known Stirling engines of this type against the resistance of a mechanical spring, a membrane or the like. The task of this spring is to bring the working piston back into the starting position after the working gas has been expanded so that the cycle can start again. Since energy is extracted from the working piston by compressing the spring, this affects the efficiency negatively.
    The Stirling engine according to the invention can dispense with a spring or the like, since pressure forces are alternately generated on both sides of the working piston or linear generator by heating the working gas. The Stirling engine according to the invention is therefore also referred to as double-acting. The double action of the Stirling engine results in a much more harmonious run, since the movement of the working piston from one side to the other takes place in the same way and there are no differences in acceleration and deceleration. Vibration compensation as described in document DE 10 2008 041 076 can therefore be dispensed with.
    Another disadvantage of existing Stirling engines is the lack of efficient performance control. By regulating the heat input, a minimal and sluggish power regulation can be achieved. The Stirling engine reacts to the changes in energy with great delay. The displacement piston in particular has a major influence on the speed of the work cycle. In conventional Stirling engines, this is mechanically connected to the working piston. This connection is mostly achieved via a flywheel.
    The connection of the working piston with the displacer by means of degree of swing has the disadvantage that the displacer is braked significantly when changing direction, after which it slowly accelerates again. This slowdown reduces the efficiency of the Stirling engine. This connection means that the displacement piston cannot be used for power control independently of the working piston.
    The connection of the displacement piston and the working piston by means of the degree of swing requires movable mechanical components in the form of e.g. Ball bearings that are exposed to mechanical and thermal loads and make production more expensive. These components are also maintenance-intensive and therefore have a negative impact on maintenance costs.
    These mechanical connections described further have the disadvantage that the housing in which the space of the working gas with the displacement piston is located must be penetrated. This penetration cannot be sealed permanently and leads to a reduction in efficiency.
    CH 712 956 A2
    DISCLOSURE OF THE INVENTION The object of the present invention is to eliminate the disadvantages mentioned above and to develop a Stirling engine which has increased efficiency and achieves increased efficiency with already small temperature differences, so that high temperatures can be dispensed with.
    The aim of the Stirling engine according to the invention is not to achieve a very high output power, but rather to be able to use low temperature differences below 100 ° C. As a result, the building materials used are not exposed to high temperatures, which leads to lower manufacturing costs and an extension of the service life.
    In the Stirling engine according to the invention, the displacement piston can be moved independently of the working piston. This movement takes place by means of an electromagnetic field which is generated by a coil outside the housing and which, by changing the polarities, forces the displacement piston to move linearly in the desired cycle.
    Due to the low temperature difference, it is possible to use temperature differences occurring in nature and convert their heat into electrical energy. The Stirling engine according to the invention thus opens up completely new areas of application and can finally emancipate itself from fuels such as wood, oil or gas. Existing Stirling engines are currently still heated using conventional fuels to achieve the required temperature difference. This worsens the CO2 balance and leads to further fine dust pollution from the combustion.
    The Stirling engine according to the invention is also suitable for the use of waste heat from existing machines, since part of the waste heat energy can be converted into electricity.
    The invention is described below using exemplary embodiments.
    BRIEF DESCRIPTION OF THE DRAWINGS The drawings used to explain the exemplary embodiments show:
    1a shows a longitudinal section of the Stirling engine according to the invention in the direction of the R axis with a possible position of the regenerators shown in sections II and II '
    Fig. 1b shows a longitudinal section of the Stirling engine according to the invention in the direction R with the opposite position of the regenerators compared to Fig. 1a.
    1c shows an enlarged longitudinal section, in the area of the linear generator, of the Stirling engine according to the invention in the direction of the R.
    Fig. 2 shows a cross section at the level of the regenerator of the Stirling engine according to the invention, transverse to the axis R, while
    3 shows a cross section at the level of the linear generator of the Stirling engine according to the invention, transverse to the R axis.
    Description One embodiment of a free-piston Stirling cycle machine 0 or a Stirling engine 0 is shown in FIGS. 1 to 3.
    Figure 1a As shown in Fig. 1a, the Stirling engine 0 has three sections which are divided into section I, section II and section II ', all three sections penetrate a hollow cylindrical pressure housing 3 which is hermetically sealed and has closed end surfaces. The pressure housing 3 holds in the interior of section I, a linear generator 1, which consists of a working piston 11 'with several integrated permanent magnets and is sealed with piston sealing rings 13', and a stator with windings 12 '. The working piston 11 'is the rotor of the linear generator 1. The stator or the windings 12' surround the working piston 11 ', spaced from it in section I of the linear generator 1.
    In sections II and II ', left and right of section I, 3 regenerators 2 or displacers 2 are arranged within the pressure housing 3 and the interior of the pressure housing 3 is filled with a working gas 11. The regenerators 2 also consist of a permanent magnet 21 'and slide rings 22' made of abrasion-resistant plastic. The pressure housing 3 has a filling opening 16 for the working gas 11 on each of the two end faces. The working gas 11 is distributed in the interior of the sections II, II ', of the pressure housing 3 and is filled once during manufacture before thermal insulation is arranged on the pressure housing 3. The Stirling engine 0 presented here can be defined as a gamma type, since the working pistons 11 'and both regenerators 2 are accommodated in the same cylindrical interior of the pressure housing 3. The working piston 11 'and the regenerators 2 are linearly movable in the R axis
    CH 712 956 A2
    Pressure housing interior stored, with no mechanical connection between the working piston 11 'and regenerators. Both regenerators 2 and the working piston 11 'are maximally deflected to the left in the position according to FIG. 1a.
    As shown in Fig. 1a, are located outside the pressure housing 3 in the middle of the sections II and II ', each an induction coil 5, which is wound around the pressure housing 3. The induction coil 5 is operated as an electromagnet, a current being applied to a magnetic field which is used to move the regenerators 2. The induction coil 5 divides a heat transfer medium 14, here in the form of foamed metal 14, into two parts. Since heat energy is to be transferred as efficiently as possible to the working gas 11 in the pressure housing in the second sections II, II ', the heat transfer means 14 are important.
    A sheath 22 surrounds the foamed metal 14 and the induction coils 5 along the second sections II and II '. In the second sections II, II ', the casing 22 is surrounded by a surrounding thermal insulation 13, the heat supply areas 9 and heat removal areas 10. A control module 6 with integrated interfaces such as WLAN and Bluetooth, a rechargeable battery 7 and a frequency converter 8 are positioned within this thermal insulation 13, advantageously in the front edge area. An electric line 21 leads the current of the frequency converter 8 to the outside. Lines 19 for a heat transfer fluid, preferably water, are arranged in the thermal insulation 13. These lines 19 include solenoid valves 18 and sensors 17, the lines 19 running essentially parallel to the axis R.
    A closed casing 12 encased the Stirling engine 0 in the second sections II and II ', the thermal insulation 13 surrounding. The lines 19 for the fluid are mounted continuously within the lining 12 in the second sections II, II '.
    The first section I, in which the linear generator 1 is arranged, encloses a perforated cladding 20, which allows cooling of the first section I. Between the perforated casing 20 and the pressure housing 3, cooling fins 4 are arranged at right angles to the axis R, which improve the heat emission of the linear generator 1 to the room air. As shown in FIG. 1a, in sections II and II ', in the heat supply areas 9, on the outer two sides of the Stirling engine 0, heat applied T2. In the heat dissipation areas 10, left and right of the first section I or of the linear generator 1 with working piston 11 ', heat is dissipated T1. For this purpose, the lines 19 are provided, through which hot and cold water is conducted into the heat supply areas 9 and heat removal areas.
    1b shows the Stirling engine 0 compared to FIG. 1a with different positions of the regenerators 2 and the working piston 11 '. The regenerator 2 of the second section II is maximally deflected in the direction of the working piston', while the regenerator 2 of the second section II 'is maximally deflected away from the working piston 11' in the direction of the outer edge of the pressure housing 3.
    FIG. 1c FIG. 1c shows section I with the linear generator 1, enlarged compared to FIG. 1a, with a working piston 11 'consisting of permanent magnets which can also be moved with the working piston 11'. Piston rings 13 'are arranged on the left and right at the outer end of the working piston 11', which simplifies the linear movement of the working piston 11 '.
    The linear generator 1 also has a stator with a plurality of windings 12 '. The linear generator 1 is completely enclosed in the pressure housing 3. The pressure housing 3 has cooling fins 4 on the outside wall in the area of the linear generator 1. The lines 19 are arranged through the area of the cooling fins 4.
    Figure 2 shows a cross section 90 ° to the axis R of the Stirling engine 0 shown in Fig. 1a, in section II, at the level of a regenerator 2 in the heat supply area 9, with the permanent magnet 21 '. The regenerator 2 is located within the pressure housing 3, which in turn is surrounded by the foamed metal 14 as a heat transfer medium 14. The casing 22 seals the foamed metal 14 from the thermal insulation 13. The lines 19 and the electrical line 21 are guided within the thermal insulation 13. All components are in turn enclosed within the panel 12. The lines 19 and the electrical lines 21, embedded in the thermal insulation 13, come into contact only with ambient air and not with the heat transfer fluid which flows through the lines 19 and is let into the heat transfer means 14 through the casing 22.
    Figure 3 shows the section 2, in section I, transverse to the linear generator 1. In the center of Fig. 3, the working piston 1V comprises permanent magnets, which is surrounded by a gap spaced from the stator with windings 12 '.
    CH 712 956 A2
    The pressure housing 3 is in turn surrounded by the cooling fins 4. The lines 19 for the heat transfer fluid are passed through the cooling fins 4. All of the components described are in turn enclosed in the perforated covering 20.
    WAYS OF IMPLEMENTING THE INVENTION The Stirling engine 0 presented here, as shown in the figures, converts thermal energy into electrical energy. To operate the Stirling engine 0, a heat source is necessary which introduces thermal energy within the sections II and II 'into the heat supply areas 9 by means of increased temperature T2. In the illustrated embodiment, warm liquid is used as the heat transfer fluid e.g. Water supplied via lines 19. The flow rate is measured by means of sensors 17. These data go to the control module 6, which in turn can regulate the flow rate by means of solenoid valves 18. The heat supplied reaches the area of the heat transfer means 14 in the form of the metal foams 14 via the lines 19, the metal foams 14 transfer the heat energy from the heat transfer fluid via the pressure housing 3 to the working gas 11. As an alternative to the metal foams 14, normal metal fins can also be used as heat transfer means 14 can be used.
    The pressure housing 3 is usually created in three individual parts, which are then connected to one another. This ensures that the linear generator 1 can be installed or replaced.
    Helium is advantageously used as the working gas 11. In the heat dissipation area 10 with low temperature T1, thermal energy is in turn conducted away via the lines 19. Between the heat dissipation areas 10 with low temperature T1 and heat supply areas 9 with elevated temperature 12, a temperature difference now arises outside and inside the pressure housing 3.
    As shown in Figure 1a, the regenerator 2 displaces the working gas 11 in section II from the heat supply areas 9 with elevated temperature T2 in the heat dissipation area 10 with low temperature T1. In this heat dissipation area 10, the working gas 11 releases the thermal energy via the pressure housing 3 to the metal foam 14 again. Since the metal foam 14 is flushed by the heat transfer fluid, e.g. Water, the heat energy is dissipated. The working gas 11 thereby cools down and the internal pressure on the side of section II of the linear generator 1 drops. The opposite happens simultaneously on the opposite side of the linear generator 1 in section II '. The regenerator 2 displaces the working gas 11 from the cold area 10 with T1 to the warm area 912 of the pressure housing
    3. In the positions of the regenerators 2 described in FIG. 1a, a pressure reduction occurs in section II because heat is carried away and a pressure increase in section II 'because heat is supplied. This pressure drop forces the working piston 11 'to move along the axis R in the direction of section II.
    After this work cycle, the regenerators 2 are moved as shown in Fig. 1 b to the opposite side, within the sections II and IT, along the axis R by means of a reversal of the polarity of the magnetic field of the induction coil 5. As a result of this movement, the working gas 11 is displaced into the region 9 with an increased temperature T2, as shown in section II of FIG. 1b. As a result, it is heated and presses the working piston 11 'along the axis R in the direction of the section II', while in the section II 'the regenerator 2 is in the region with elevated temperature 9 T2 and the working gas 11 in the region with low temperature 10 T1 is ousted. This causes the pressure of the working gas in section II 'to collapse and reduces the resistance of the working piston 11' to enter this section.
    The regenerators 2 are short-term heat stores and absorb thermal energy on one side via the working gas 11 in order to release them again to the working gas 11 on the opposite side. The regenerators 2 are advantageously made of material with a high heat capacity. Since the regenerators 2 delay this heat flow somewhat in time, there is a higher temperature gradient between the working gas volumes 11 on the left and right of the regenerators 2. As a result, the working gas 11 expands and acts along the axis R on the end face of the working piston 11 'of the linear generator 1. The piston ring 13 ′ ensures that the working gas 11 does not penetrate the linear generator 1. A pressure gradient of the working gas 11 now arises between the cavity of the pressure housing 3 divided by the linear generator 1. The forces acting on the working piston 11 'thereby set it in motion parallel to the axis R. The working piston 11 'provided with permanent magnets induces an electrical voltage by means of its magnetic field via the stator with windings 12'. This voltage is fed to the frequency converter 8 by means of the electric lines 21, which increases the frequency to the usual 50 Hz so that the current generated can be fed to an external consumer.
    The double action of the Stirling engine 0 is achieved in that the working gas 11 can act alternately on both sides of the linear generator 1 on the working piston 11 'by being exposed to different temperatures and the pressure on both sides of the linear generator 1 at the same time as described above increases on one side and decreases on the opposite side at the same time.
    The induction coil 5 generates a directional, magnetic field for moving the regenerators 2, it consists of a copper wire winding and is supplied with power via the control module 6. The induction coils 5 thus form an electromagnet with which a controlled positioning of the regenerators 2 is possible. The regenerators 2 must therefore be permanently magnetic or, as shown, be provided with a permanent magnet 21 '.
    CH 712 956 A2
    In order to keep the frictional resistance as low as possible and to avoid wear of the regenerator, slide rings 22 'made of metal or plastic are used.
    In order to start the Stirling engine 0, this requires additional energy. This is provided by the battery 7. The battery 7 is charged during the operation of the Stirling engine 0 by means of specially generated electrical energy in order to provide the necessary starting energy after a standstill for the movement of the regenerators 2 by means of the induction coil 5.
    The control module 6 monitors by means of the sensors 17 the heat flow which is supplied from the outside through the line 19 for the fluid into the Stirling engine. The control module 6 consists of a processor for processing incoming data such as temperature, flow rate, voltage and current. Based on this data, the control module 6 regulates the operating cycle of the regenerators 2 via the induction coil 5. The control module 6 further regulates the flow of the fluid with the aid of the solenoid valves 18. In a first embodiment, the control module 6 provides an interface, optionally via Bluetooth, WLAN , or USB interface. This interface is used to control, monitor and set the Stirling engine 0 for the user.
    The Stirling engine 0 is completed in section I around the linear generator 1 with a perforated cladding 20 in order to ensure that the waste heat from the linear generator 1 can be released to the ambient air via the cooling fins 4 and through the perforated cladding 20.
    A double action of the Stirling engine 0 is achieved here in that the two displacement sections II, II 'are arranged on both sides of the working section I, the pressure housing 3 enclosing an interior in which the working gas 11, the working piston 11' and both Regenerators 2 are arranged to be linearly movable. The regenerators 2 move on both sides of the working section I and thus on both sides of the linear generator 1. For a high efficiency, the working gas 11 should not balance out from the sections II and II 'via the working section I. The piston rings 13 'and slide rings 22' prevent the working gas 11 from leaving sections II and II 'and entering section I. Here, the pressure housing 3 is built around the linear generator 1 in order to keep the working gas 11 flowing past the piston ring 13 'and slide rings 22' in the closed system. When the Stirling engine 0 or working piston 11 ′ and regenerators 2 are at a standstill, the working gas 11 balances out again within the entire pressure housing 3. In practice it will also penetrate into section I since pressures of about 200 bar are present. If the working gas 11 could equalize without resistance between the displacer sections II and II ', there would be no pressure drop between the sections I, II, II' and the working piston 11 'would not be driven.
    So that a return spring can be dispensed with, whereby the working piston is pushed back to the starting position in classic Stirling engines, here two sections II, II 'are arranged laterally on the working section I. The problem with a return spring is that it consumes kinetic energy and the working piston has to press against the spring. Here, positive pressure and negative pressure are alternately generated on both sides of the linear generator 1, so that the working piston 11 can be moved between its deflection positions with less resistance.
    Reference symbol list [0045]
    Free piston Stirling cycle machine / Stirling engine
    Linear generator '' working piston (rotor with permanent magnets)
    12 'stator with windings 13' piston ring
    Regenerators (displacement pistons) 'Permanent magnet
    22 'slip rings
    pressure housing
    cooling fins
    induction coil
    control module
    battery pack
    CH 712 956 A2
    frequency
    Heat supply area / elevated temperature T2
    Heat dissipation area / low temperature T1
    working gas
    paneling
    thermal insulation
    Heat transfer agent / foamed metal
    Thermal separation with seal
    Filling opening for working gas
    sensors
    solenoid valves
    Line for fluid
    Perforated cladding
    electric line
    jacket
    R axis
    I first section
    II, II 'displacer sections / second sections
    权利要求:
    Claims (12)
    [1]
    claims
    1. Stirling engine (0), comprising a hermetically sealed pressure housing (3) with a working section (I) and at least one displacer section (II) adjoining the working section (I), at least in the interior of the pressure housing (3) in the working section (I) a working piston (11 ') is movable, forming part of a linear generator (1), and a regenerator (2) is arranged in at least one displacer section (II), so that when the pressure housing (3) is filled with a working gas (11) and When there is a temperature difference between the displacer section (II) at elevated temperature (T2) and the rest of the pressure housing (3) at low temperature (T1, T1 <T2), mechanical work can be performed by the working piston (11 ') and by the linear generator (1) Can be converted into electrical energy, characterized in that a second displacement section (II ') with a regenerator (2) linear from the working section (I) and the first displacement The section (II) is arranged at a distance in the same pressure housing (3), so that the displacer sections (II, II ') directly surround the working section (I) on both sides along a longitudinal axis (R), the two regenerators (2) being permanently magnetic or a permanent magnet (21 ') and can be operatively connected to induction coils (5) which surround each displacement section (II, II') in such a way that the position of the regenerators (2) can be varied by adjusting the current flow through the induction coils (5).
    [2]
    2. Stirling engine (0) according to claim 1, wherein on the working piston (11 ') piston rings 13' and on the regenerators (2) slide rings (22 ') are arranged, which exchange an operating gas (11) within the pressure housing (3) between the first section (I) and the displacer sections (II, II ') difficult.
    [3]
    3. Stirling machine (0) according to claim 1, wherein a stator (12 ') with windings of the linear generator (1) is arranged completely in the pressure housing (3) and the working piston (11') is the rotor of the linear generator (1).
    [4]
    4. Stirling engine (0) according to one of the preceding claims, characterized in that the Stirling engine (0) has a control module (6) which collects and processes data such as temperature and flow rate of a heat transfer fluid via sensors (17) and the flow rate via solenoid valves (18 ) is adjustable.
    [5]
    5. Stirling engine (0) according to claim 4, wherein the control module (6) regulate the movement cycle of the regenerators (2) by reversing the polarity of the induction coils (5) and thereby can directly influence the cycle of the working piston (11 '), which induced the , determined amount of electrical energy obtained.
    CH 712 956 A2
    [6]
    6. Stirling engine (0) according to one of the preceding claims, characterized in that an internal battery (7) provides the necessary starting energy, which is necessary for starting the Stirling engine (0) to the regenerators (2) via the induction coil (5) move, the battery (7) is rechargeable during operation by converted energy of the linear generator (1).
    [7]
    7. Stirling machine (0) according to one of the preceding claims 2 to 6, wherein the regenerator (2) by means of integrated dry-running sliding rings (22 '), in particular made of wear-resistant plastics, runs maintenance-free.
    [8]
    8. Stirling engine (0) according to any one of the preceding claims, wherein the displacer sections (II, II ') outside the pressure housing (3) are encased with a heat transfer medium (14) which is permeable to a heat transfer fluid.
    [9]
    9. Stirling engine (0) according to claim 8, wherein the heat transfer means (14) is in the form of a foamed metal (14), the porosity of which allows the heat transfer fluid to flow through.
    [10]
    10. Stirling engine (0) according to one of claims 4 to 9, wherein the control module (6) has a wireless interface such as WiFi or Bluetooth and can be monitored and controlled by means of an external PC, tablet or smartphone.
    [11]
    11. Stirling engine (0) according to one of the preceding claims, wherein a frequency converter (8) converts the current induced by the linear generator (1) to an alternating voltage frequency of 50 Hz, so that the electrical energy is either fed directly into the power supply system or supplied to a consumer can.
    [12]
    12. Stirling machine (0) according to one of the preceding claims, wherein each displacer section (II, II ') on its side facing away from the working section (I) has a heat supply area (9) and on its side facing the working section (I) has a heat dissipation area (10) has, in which a heat transfer fluid by means of lines (19) can be supplied and removed.
    CH 712 956 A2
    类似技术:
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    同族专利:
    公开号 | 公开日
    EP3301287A1|2018-04-04|
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    EP2657497B1|2012-04-26|2014-11-26|Thilo Ittner|Thermo-electric converter with improved heat transmitter|US10774783B2|2018-04-20|2020-09-15|Stratum Ventures, Llc|Liquid piston stirling engine with linear generator|
    US11268476B2|2019-05-21|2022-03-08|General Electric Company|Energy conversion apparatus|
    法律状态:
    2018-11-30| PUE| Assignment|Owner name: SMART CONVERSION GMBH, CH Free format text: FORMER OWNER: DANIEL BERTSCHI, CH |
    优先权:
    申请号 | 申请日 | 专利标题
    CH01262/16A|CH712956B1|2016-09-27|2016-09-27|Double-acting free-piston Stirling cycle machine with linear generator.|CH01262/16A| CH712956B1|2016-09-27|2016-09-27|Double-acting free-piston Stirling cycle machine with linear generator.|
    EP17187947.1A| EP3301287A1|2016-09-27|2017-08-25|Double action floating piston-stirling-circulating machine with linear generator|
    US15/715,352| US20180087473A1|2016-09-27|2017-09-26|Double-acting free-piston-stirling cycle machine with linear generator|
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