The present invention relates to a scroll expander in which power is recovered by expanding a refrigerant and is used in compression.
In conventional scroll expanders, a compression chamber of a compressing means is formed by a first fixed scroll and an orbiting scroll, and at the same time, an expansion chamber of an expanding means is formed by a second fixed scroll and the orbiting scroll. The orbiting scroll is linked to a crankshaft, and is configured so as to be driven to revolve by a motor mounted to the crankshaft (see Patent Literature 1, for example).
Patent Literature 1: Japanese Patent Publication No. HEI 07-037857 (Gazette: pp 3-4; FIG. 1)
However, scroll expanders such as that described above have had to be configured integrally with driving sources such as the motor, etc., making construction complicated. Another problem has been that recovered power is reduced in off-design point operating conditions since quantity of flow or differential pressure of the expansion mechanism must be reduced in order to synchronize the rotational frequencies of the expansion mechanism and the compression mechanism. An additional problem has been that leakage at tip of spiral teeth cannot be suppressed because the expansion chamber and the compression chamber are disposed on two surfaces of the orbiting scroll (pivoting scroll).
The present invention aims to solve the above problems and an object of the present invention is to provide a scroll expander that is efficient in a wide range of operating conditions by suppressing leakage loss and decreases in recovered power using a simple construction.
According to one aspect of the present invention, there is provided a scroll expander including: an expansion mechanism that is constituted by an orbiting scroll and a first fixed scroll, and that recovers power by expanding a refrigerant; and an auxiliary compression mechanism that is constituted by an orbiting scroll and a second fixed scroll, and that compresses refrigerant using power recovered by the expansion mechanism, characterized in that a tip seal is mounted only to a spiral tooth of an orbiting scroll and a fixed scroll of one of either the expansion mechanism or the auxiliary compression mechanism.
According to another aspect of the present invention, there is provided a scroll expander including: an expansion mechanism that is constituted by an orbiting scroll and a first fixed scroll, and that recovers power by expanding a refrigerant; and an auxiliary compression mechanism that is constituted by an orbiting scroll and a second fixed scroll, and that undertakes a portion of a compression process of a refrigerating cycle by compressing refrigerant using power recovered by the expansion mechanism, characterized in that a tip seal is mounted only to a spiral tooth of an orbiting scroll and a fixed scroll of one of either the expansion mechanism or the auxiliary compression mechanism.
The present invention can provide a scroll expander that is efficient in a wide range of operating conditions by suppressing leakage loss and decreases in recovered power using a simple construction.
In
A shaft 8 is held rotatably at two ends by shaft bearing portions 51b and 61b that are formed centrally on the fixed scroll 51 of the expansion mechanism 5 and the fixed scroll 61 of the auxiliary compression mechanism 6, respectively. Eccentric shaft bearing portions 52b and 62b that are formed centrally on the orbiting scroll 52 of the expansion mechanism 5 and the orbiting scroll 62 of the auxiliary compression mechanism 6, respectively, are penetrated and supported by a crank portion 8b fitted onto the shaft 8 so as to enable pivoting motion.
An expansion suction pipe 13 that sucks in refrigerant and an expansion discharge pipe 15 that discharges expanded refrigerant are installed on side surfaces of the sealed vessel 10 outside the expansion mechanism 5. Similarly, an auxiliary compression suction pipe 12 that sucks in refrigerant is installed on an upper surface of the sealed vessel 10 above the auxiliary compression mechanism 6, and an auxiliary compression discharge pipe 14 that discharges compressed refrigerant is installed on a side surface of the sealed vessel 10 outside the auxiliary compression mechanism 6.
In the auxiliary compression mechanism 6, tip seals 21 that partition off an auxiliary compression chamber 6a that is formed by the spiral tooth 61c of the fixed scroll 61 and the spiral tooth 62c of the orbiting scroll 62 are mounted onto tips of the spiral teeth 61e and 62c of the fixed scroll 61 and the orbiting scroll 62, respectively. An inner seal 22a that forms a seal between the orbiting scroll 62 and the fixed scroll 61 is disposed outside the eccentric shaft bearing portion 62b of the orbiting scroll 62 on a surface that faces the fixed scroll 61. In addition, an outer seal 23 that forms a seal between the orbiting scroll 62 and the fixed scroll 61 is disposed outside the spiral tooth 61c of the fixed scroll 61 on a surface that faces the orbiting scroll 52.
Similarly, in the expansion mechanism 5, an inner seal 22b that forms a seal between the orbiting scroll 52 and the fixed scroll 51 in a similar manner to the auxiliary compression mechanism 6 is disposed outside the eccentric shaft bearing portion 52b of the orbiting scroll 52 on a surface that faces the fixed scroll 51. However, tip seals 21 are not mounted to tips of the spiral teeth 51c and 52c of the fixed scroll 51 and the orbiting scroll 52. Nor is an outer seal 23 disposed outside the spiral tooth 51c in the fixed scroll 51 on a surface that faces the orbiting scroll 52.
The orbiting scroll 52 of the expansion mechanism 5 and the orbiting scroll 62 of the auxiliary compression mechanism 6 are integrated by bonding elements such as pins, etc., and autorotation is corrected by an Oldham ring 7 that is disposed on the auxiliary compression mechanism 6. Counterweights 9a and 9b are mounted to two ends of the shaft 8 in order to cancel out centrifugal force that is generated by the pivoting motion of the orbiting scrolls 52 and 62. Moreover, the orbiting scroll 52 of the expansion mechanism 5 and the orbiting scroll 62 of the auxiliary compression mechanism 6 may also be formed integrally in a shape in which the base plates 52a and 62a are shared.
In the expansion mechanism 5, power is generated inside the expansion chamber 5a that is formed by the spiral tooth 51c of the fixed scroll 51 and the spiral tooth 52c of the orbiting scroll 52 by expansion of high-pressure refrigerant that has been sucked in through the expansion suction pipe 13. Refrigerant that has expanded inside the expansion chamber 5a and decompressed is discharged outside the sealed vessel 10 through the expansion discharge pipe 15. Refrigerant sucked in through the auxiliary compression suction pipe 12 is compressed and pressurized inside the auxiliary compression chamber 6a that is formed by the spiral tooth 61c of the fixed scroll 61 and the spiral tooth 62c of the orbiting scroll 62 of the auxiliary compression mechanism 6 by the power generated in the expansion mechanism 5. Refrigerant that has been compressed and pressurized inside the auxiliary compression chamber 6a is discharged outside the sealed vessel 10 through the auxiliary compression discharge pipe 14.
A thick portion 52d is disposed on an inner end portion of the spiral tooth 52c of the orbiting scroll 52, and the eccentric shaft bearing portion 52b into which the crank portion 8b is inserted is formed so as to pass through the thick portion 52d. An inner seal groove 52g is formed on the base plate 52a of the orbiting scroll 52 outside the eccentric shaft bearing portion 52b, and the inner seal 22b is mounted into the inner seal groove 52g.
A suction port 51d for sucking in refrigerant and a discharge port 51e for discharging refrigerant are opened through the base plate 51c of the fixed scroll 51. The suction port 51d has a generally elongated slot shape in order to ensure aperture area, and is connected to the expansion suction pipe 13. A notched portion 52e is also disposed on the thick portion 52d in order to reduce blocked area of the suction port 51d during the pivoting motion. The discharge port 51e is opened at a position that does not interfere with the outer end portion of the spiral tooth 52c of the orbiting scroll 52, and is connected to the expansion discharge pipe 15.
In a similar manner to the orbiting scroll 52 of the expansion mechanism 5, the eccentric shaft bearing portion 62b into which the crank portion 8b is inserted is formed so as to pass through a thick portion 62d of the orbiting scroll 62, and a suction port 61d for sucking in refrigerant and a discharge port 61e for discharging refrigerant are opened through the base plate 61a of the fixed scroll 61. The discharge port 61e has a generally elongated slot shape in order to ensure aperture area, and is connected to the auxiliary compression discharge pipe 14. A notched portion 62e is also disposed on the thick portion 62d in order to reduce blocked area of the discharge port 61e during the pivoting motion. The suction port 61d is opened at a position that does not interfere with the outer end portion of the spiral tooth 62c of the orbiting scroll 62, and is connected to the auxiliary compression suction pipe 12.
Tip seal grooves 61f and 62f for mounting the tip seals are formed on tip surfaces of the spiral teeth 61c and 62c. An inner seal groove 62g for mounting the inner seal 22a is formed on the base plate 62a of the orbiting scroll 62 outside the eccentric shaft bearing portion 62b. An outer seal groove 61g for mounting the outer seal 23 is formed on the base plate 61a of the fixed scroll 61 outside the spiral tooth 61c.
In
Refrigerant that has been pressurized in the main compression mechanism 11a of the main compressor 11 is pressurized further by the auxiliary compression mechanism 6 of the scroll expander 1. Refrigerant that has been pressurized in the auxiliary compression mechanism 6 is cooled by the gas cooler 2, then a portion is sent to the expansion mechanism 5 of the scroll expander 1 to be expanded and decompressed. The expansion valve 3 is disposed in parallel with the expansion mechanism 5 of the scroll expander 1 in order to adjust quantities of flow passing through the expansion mechanism 5 and to ensure differential pressure at startup, and the remaining refrigerant is sent to the expansion valve 3 to be expanded and decompressed. In the expansion mechanism 5, the refrigerant expands isentropically, and expansion power is transmitted from the expansion mechanism 5 through the main shaft 8 to the auxiliary compression mechanism 6 and is used for auxiliary compression work. Refrigerant that has been expanded in the expansion mechanism 5 is heated by the evaporator 4, then returns to the main compression mechanism 11a of the main compressor 11.
As shown in
As shown in
Rotational frequency NC at the auxiliary compression mechanism 6 can be expressed as in Mathematical Formula 2.
Consequently, since NE=NC is a condition for matching the rotational frequencies of the expansion mechanism 5 and the auxiliary compression mechanism 6, Mathematical Formula 3 must be satisfied.
A ratio of stroke volumes σvec of the expansion mechanism 5 and the auxiliary compression mechanism 6 shown in Mathematical Formula 3 is constant if equipment dimensions are fixed relative to certain design conditions. If operating outside the design conditions, it becomes necessary to adjust a ratio between quantities of volume flow (Gevei/Gcvcs) so as to satisfy Mathematical Formula 3. If all of the compression process of the refrigerating cycle is undertaken by the auxiliary compression mechanism 6 (in that case, it is necessary to use a separate driving source for the auxiliary compression mechanism 6 in addition to the recovered power from the expansion mechanism 5), because specific volumes vei and vcs at the entrances of the expansion mechanism 5 and the auxiliary compression mechanism 6, respectively, are determined by the operating conditions, the quantity of mass flow Ge is normally adjusted by a means such as a bypass like the expansion valve 3, etc. Here, because the quantity of flow that is made to bypass is a quantity of non-recoverable flow from which expansion power cannot be recovered and effective power recovery decreases, it is necessary to suppress the quantity of bypass flow as much as possible.
As shown in
As explained above, because adjustment of rotational frequency using specific volume vcs at the entrance of the auxiliary compression mechanism 6 and adjustment of compression power by increasing pressure in the auxiliary compression mechanism 6 can be used in combination if a portion of the compression process of the refrigerating cycle is undertaken by the main compression mechanism 11a that is driven by the electrically powered mechanism 11b and the remainder of the compression process is undertaken by the auxiliary compression mechanism 6 of the scroll expander 1 that is driven by recovered power, decreases in recovery effects due to bypassing can be suppressed more than if all of the compression process of the refrigerating cycle is undertaken by the auxiliary compression mechanism 6 of the scroll expander 1.
Tip seals 21 that partition off the auxiliary compression chamber 6a are mounted to the spiral teeth 61c and 62c of the auxiliary compression mechanism 6. An outer seal 23 is also disposed on the base plate 61a of the fixed scroll 61 of the auxiliary compression mechanism 6 outside the spiral tooth 61c. In addition, inner seals 22a and 22b are disposed outside the eccentric shaft bearing portions 52b and 62b of the orbiting scrolls 52 and 62. In the expansion mechanism 5, an outer portion of the base plate 51a of the fixed scroll 51 and an outer portion of the base plate 52a of the orbiting scroll 52 are configured so as to come into contact.
In
In Embodiment 1 of the present invention, the expansion mechanism 5 undertakes an expansion process from a high pressure Ph (pressure at point c) to a low pressure Pl (pressure at point b), and the auxiliary compression mechanism 6 undertakes a compression process from an intermediate pressure Pm (pressure at point d′) to the high pressure Ph (pressure at point d≈pressure at point c). For this reason, in the orbiting scrolls 52 and 62, the high pressure Ph acts on both a central portion of the expansion chamber 5a and a central portion of the auxiliary compression chamber 6a, and the low pressure Pl acts on an outer portion of the expansion chamber 5a and the intermediate pressure Pm on an outer portion of the auxiliary compression chamber 6a. Because the inside of the sealed vessel 10 is set to the low pressure Pl, the outer seal 23 is disposed on the base plate 61a of the fixed scroll 61 of the auxiliary compression mechanism 6 outside the spiral tooth 61c in order to seal off differential pressure between the outer portion of the auxiliary compression chamber 6a (Pm) and the inside of the sealed vessel 10 (Pl). The inner seals 22a and 22b are disposed outside the eccentric shaft bearing portions 52b and 62b of the orbiting scrolls 52 and 62 in order to seal off differential pressure between the central portion of the expansion chamber 5a (Ph) and the inside of the sealed vessel 10 (Pl) and between the central portion of the auxiliary compression chamber 6a (Ph) and the inside of the sealed vessel 10 (Pl).
If the inside of the sealed vessel 10 is set to the high pressure Ph, outer seals 23 must be disposed on an outer portion of the expansion mechanism 5, which is at the low pressure Pl, and an outer portion of the auxiliary compression mechanism 6, which is at the intermediate pressure Pm. If the inside of the sealed vessel 10 is set to the intermediate pressure Pm, an outer seal 23 must be disposed on an outer portion of the expansion mechanism 5, which is at the low pressure Pl, and inner seals 22a and 22b disposed on a central portion of the expansion mechanism 5 and a central portion of the auxiliary compression mechanism 6, which are at the high pressure Ph. Even if the inside of the sealed vessel 10 is set to the high pressure Ph or set to the intermediate pressure Pm, the number of seals is equal to or less than when the inside of the sealed vessel 10 is set to the low pressure Pl. However, if the inside of the sealed vessel 10 is set to the high pressure Ph or set to the intermediate pressure Pm, it is necessary to increase the thickness of the walls of the sealed vessel 10 more than if the inside of the sealed vessel 10 is set to the low pressure Pl in order to ensure pressure tolerance of the sealed vessel 10 relative to the high pressure Ph or to the intermediate pressure Pm, which is close to the high pressure Ph. Consequently, because the inner seals 22a and 22b are disposed at a central portion of the expansion mechanism 5 and a central portion of the auxiliary compression mechanism 6, and the outer seal 23 is disposed on the outer portion of auxiliary compression mechanism 6, the inside of the sealed vessel 10 can be set to the low pressure Pl, enabling manufacturing costs for the scroll expander 1 to be reduced.
As shown in
In
In scroll-type fluid machinery, in the case of both compressors and expanders, and in the case of both single-side spiral constructions that include a spiral tooth on only one surface of an orbiting scroll and double-sided spiral constructions that include spiral teeth on two surfaces of the orbiting scrolls, axial positions of the orbiting scrolls are determined by points that support axial force due to the pressure of the refrigerant, and gaps that correspond to assembly clearance arise on surfaces on opposite sides of the orbiting scrolls from the direction of pressure. For this reason, leakage may arise with the expansion chamber 5a or within the auxiliary compression chamber 6a where pressure differs.
In a scroll expander according to Embodiment 1, because the orbiting scrolls 52 and 62 are pressed together against the fixed scroll 51 of the expansion mechanism 5 by the pressing force F, gaps at the tips of the spiral teeth 51c and 52c of the expansion mechanism 5 are generally eliminated. Because of this, leakage from the tips of the spiral teeth 51c and 52c can be reduced in the expansion mechanism 5. In particular, because the differential pressure between the intermediate pressure Pm and the low pressure Pl is also increased if the high pressure Ph is an extremely high pressure, as in the case of carbon dioxide, adjustment of the diameter of the outer seal 23 in order to obtain the required pressing force F need only be small and can be achieved without enlarging outside diameter dimensions. On the other hand, gaps arise in the auxiliary compression mechanism 6 between the tip surface of the spiral tooth 62c of the orbiting scroll 62 and the base plate 61a of the fixed scroll 61 and between the base plate 62a of the orbiting scroll 62 and the tip surface of the spiral tooth 61c of the fixed scroll 61 of the auxiliary compression mechanism 6. However, because the tip seals 21 are mounted to the tips of the spiral teeth 61c and 62c, radial leakage outward from inside the spiral at the tips of the spiral teeth 61c and 62c is almost eliminated, enabling leakage to be limited to only circumferential leakage parallel to the spiral teeth 61c and 62c at sides of the tip seals 21.
In the expansion mechanism 5, because the outer portion of the base plate 51a of the fixed scroll 51 and the outer portion of the base plate 52a of the orbiting scroll 52 are configured so as to come into contact, the pressing force F can be supported over a wider area, suppressing absolute values of the surface pressure acting on the tooth ends of the spiral teeth 51c and 52c and amplitude of fluctuations during working pressure changes.
Now, if p is a spiral tooth pitch, and t is a spiral tooth thickness, then pivoting radii r of the expansion mechanism 5 and the auxiliary compression mechanism 6 have a relationship such as that shown in Mathematical Formula 4.
In Embodiment 1 of the present invention, the pivoting radii r are equal in the expansion mechanism 5 and the auxiliary compression mechanism 6. However, the spiral tooth thickness t is greater in the spiral teeth 51c and 52c of the expansion mechanism 5 than in the spiral teeth 61c and 62c of the auxiliary compression mechanism 6. The spiral tooth pitch p is also correspondingly greater in the spiral teeth 51c and 52c of the expansion mechanism 5 than in the spiral teeth 61c and 62c of the auxiliary compression mechanism 6. Because the spiral tooth thickness t is greater in the spiral teeth 51c and 52c of the expansion mechanism 5 than in the spiral teeth 61c and 62c of the auxiliary compression mechanism 6, strength can be ensured in the spiral teeth 51c and 52c of the expansion mechanism 5 where differential pressure before and after expansion is greater than differential pressure before and after compression in the auxiliary compression mechanism 6.
In a configuration such as that above, because a portion of the compression process of the refrigerating cycle is undertaken by the auxiliary compression mechanism 6 of the scroll expander 1, decreases in recovery effects due to bypassing can be suppressed, enabling a scroll expander that is efficient in a wide range of operating conditions to be achieved. Because the orbiting scrolls 52 and 62 are configured so as to be pressed against the fixed scroll 51 of the expansion mechanism 5 and the tip seals 21 are mounted to the spiral teeth 51c and 62c of the fixed scroll 61 and the orbiting scroll 62 of the auxiliary compression mechanism 6, leakage loss can be reduced.
Because the tip surfaces of the spiral teeth 51c and 52c and the outer portions of the base plates 51a and 52a of the expansion mechanism 5 are pressed together by performing compression from the intermediate pressure Pm to the high pressure Ph in the auxiliary compression mechanism 6, pressurization in the auxiliary compression mechanism 6 arises after activation, and an entire region of the auxiliary compression mechanism 6 from the outer portion to the central portion is at high pressure Ph before activation, making it possible to achieve a scroll expander 1 having superior activation since tooth end pushing in the expansion mechanism 5 becomes more reliable.
In Embodiment 1, tip seals 21 were mounted to tips of spiral teeth 61c and 62c of an auxiliary compression mechanism 6, and orbiting scrolls 52 and 62 were configured so as to be pressed against a fixed scroll 51 of an expansion mechanism 5. In a scroll expander 1A according to Embodiment 2 of the present invention, as shown in
In
Refrigerant that has been pressurized in the auxiliary compression mechanism 6 that is driven by the expansion mechanism 5 of the scroll expander 1A is pressurized further by the main compression mechanism 11a that is driven by the electrically powered mechanism 11b of the main compressor 11. Refrigerant that has been pressurized in the main compression mechanism 11a is cooled by the gas cooler 2, then a portion is sent to the expansion mechanism 5 of the scroll expander 1A to be expanded and decompressed. The expansion valve 3 is disposed in parallel with the expansion mechanism 5 of the scroll expander 1A in order to adjust quantities of flow passing through the expansion mechanism 5 and to ensure differential pressure at startup, and the remaining refrigerant is sent to the expansion valve 3 to be expanded and decompressed. In the expansion mechanism 5, the refrigerant expands isentropically, and expansion power is transmitted from the expansion mechanism 5 through the main shaft 8 to the auxiliary compression mechanism 6 and is used for auxiliary compression work. Refrigerant that has been expanded in the expansion mechanism 5 is heated by the evaporator 4, then returns to the auxiliary compression mechanism 6 of the scroll expander 1A.
As shown in
In Embodiment 2 of the present invention, a portion of the compression process of the refrigerating cycle is also undertaken by the main compression mechanism 11a driven by the electrically powered mechanism 11b and the remainder is undertaken by the auxiliary compression mechanism 6 of the scroll expander 1A driven by recovered power. Because of this, decreases in recovery effects due to bypassing can be suppressed proportionately more than if all of the compression process of the refrigerating cycle is undertaken by the auxiliary compression mechanism 6 of the scroll expander 1A since adjustment of compression power by increasing pressure in the auxiliary compression mechanism 6 is possible.
Tip seals 21 that partition off the expansion chamber 5a are mounted to the spiral teeth 51c and 52c of the expansion mechanism 5. Inner seals 22a and 22b are installed outside the eccentric shaft bearing portions 52b and 62b of the orbiting scrolls 52 and 62. In the auxiliary compression mechanism 6, an outer portion of the base plate 61a of the fixed scroll 61 and an outer portion of the base plate 62a of the orbiting scroll 62 are configured to come into contact.
In Embodiment 2 of the present invention, the expansion mechanism 5 undertakes an expansion process from a high pressure Ph (pressure at point c) to a low pressure Pl (pressure at point b), and the auxiliary compression mechanism 6 undertakes a compression process from the low pressure Pl (pressure at point a≈pressure at point b) to an intermediate pressure Pm (pressure at point a′). For this reason, the high pressure Ph acts on the central portion of the expansion chamber 5a, and the intermediate pressure Pm on a central portion of the auxiliary compression chamber 6a, and the low pressure Pl acts on both the outer portion of the expansion chamber 5a and the outer portion of the auxiliary compression chamber 6a. Because the inner seals 22a and 22b are installed outside the eccentric shaft bearing portions 52b and 62b of the orbiting scrolls 52 and 62, differing pressures can be separated at the central portion of the expansion chamber 5a and the central portion of the auxiliary compression chamber 6a. Because the pressures that act on the outer portion of the expansion chamber 5a and the outer portion of the auxiliary compression chamber 6a are both equal to the low pressure Pl, it is not necessary to separate the pressures, and outer seals 23 are not disposed on an expansion mechanism 5 side or on an auxiliary compression mechanism 6 side. In addition, because the inner seals 22a and 22b are disposed outside the eccentric shaft bearing portions 52b and 62b of the orbiting scrolls 52 and 62, the inside of the sealed vessel 10 can be set to the low pressure Pl, and it is no longer necessary to increase the thickness of the walls of the sealed vessel 10 as much as if the inside of the sealed vessel 10 is at the high pressure Ph or the intermediate pressure Pm, enabling manufacturing costs for the scroll expander 1A to be reduced.
In
In a scroll expander according to Embodiment 2, because the orbiting scrolls 52 and 62 are pressed together against the fixed scroll 61 of the auxiliary compression mechanism 6, gaps at the tips of the spiral teeth 61c and 62c of the auxiliary compression mechanism 6 are generally eliminated. Because of this, leakage from the tips of the spiral teeth 61c and 62c can be reduced in the auxiliary compression mechanism 6. In particular, because the differential pressure between the expansion mechanism 5 side and the auxiliary compression mechanism 6 side is increased at the central portion if the high pressure Ph is an extremely high pressure, as in the case of carbon dioxide, the tooth ends of the spiral teeth 61c and 62c can be reliably pressed down even if there is no differential pressure at the outer portions where the pressure receiving area is great and both are at the low pressure Pl. On the other hand, gaps arise in the expansion mechanism 5 between the tip surfaces of the spiral tooth 52c of the orbiting scroll 52 and the base plate 51a of the fixed scroll 51 and between the base plate 52a of the orbiting scroll 52 and the tip surfaces of the spiral tooth 51c of the fixed scroll 51 of the expansion mechanism 5. However, because the tip seals 21 are mounted to the tips of the spiral teeth 51c and 52c, radial leakage at the tips of the spiral teeth 51c and 52c is generally eliminated, enabling leakage to be limited to only circumferential leakage parallel to the spiral teeth 51c and 52c at sides of the tip seals 21, and also ensuring activation.
In a configuration such as that above, because a portion of the compression process of the refrigerating cycle is undertaken by the auxiliary compression mechanism 6 of the scroll expander 1A, decreases in recovery effects due to bypassing can be suppressed, enabling a scroll expander that is efficient in a wide range of operating conditions to be achieved. Because the orbiting scrolls 52 and 62 are configured so as to be pressed against the fixed scroll 61 of the auxiliary compression mechanism 6 and the tip seals 21 are mounted to the spiral teeth 51c and 52c of the fixed scroll 51 and the orbiting scroll 52 of the expansion mechanism 5, leakage loss can be reduced.
Because outer portions of the spiral teeth 51c, 52c, 61c, and 62c of both the expansion mechanism 5 and the auxiliary compression mechanism 6 are all at the low pressure Pl, large-diameter outer seals 23 are not required, enabling manufacturing costs for the scroll expander 1A to be reduced.
Number | Date | Country | Kind |
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2005-094705 | Mar 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2006/301204 | 1/26/2006 | WO | 00 | 8/23/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/103821 | 10/5/2006 | WO | A |
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