DE112015003978T5 - Screw fluid machine - Google Patents

Abstract

An object of the present invention is to provide a screw fluid machine (1) in which detachment of a slide bush (56) and a spring (61) provided in an eccentric bushing (36) is prevented by a simple configuration. In the receiving hole (58) of the eccentric bush (36) are provided the slide bush (56) which is movable in the eccentric direction and a spring (61) which biases the slide bush (56) in a moving direction. A spring retaining portion (56b) and engaging projections (56a) are provided on the sliding bush (56). After the slide bush (56) is placed in the receiving hole (58), the engaging projections (56a) come into engagement with the eccentric bush (36) in a state in which the slide bush (56) has been moved by the biasing force of the spring (61) Engage, and thus, the slide bush (56) is prevented from falling out of the receiving hole (58), and the spring-holding portion (56b) prevents the spring (61) from falling out of the receiving hole (58).

Description

TECHNICAL AREA

The present invention relates to a screw fluid machine in which a working chamber of a working fluid is formed between the coils of a fixed screw and a movable screw.

STATE OF THE ART

As this type of screw fluid machine, there has been known a single-plate-type compressor-integrated expander including a screw unit consisting of a movable screw provided with a winding provided on a base surface thereof and a fixed screw connected to a screw the winding of the movable screw engaging coil provided on a base surface thereof is composed, and in which a working chamber of the screw unit is partitioned by a partition wall into a compression chamber and an expansion chamber, thereby forming a compression portion and an expansion portion (for example, with reference to Patent Document 1).

In such a screw fluid machine, it is necessary to maintain an extremely small clearance between the stationary screw and moving screw windings in operation or to bring the windings into mutual contact. Therefore, if the cores of the screws are staggered due to poor component accuracy or mounting accuracy of the screws, a gap between the coils will occur, resulting in a considerably deteriorated performance. In order to avoid the problem, a structure has been developed in which a slide bush is provided in an eccentric bush mounted in a boss of the movable scroll, the slide bush being movable in an eccentric direction and biased by a spring to bias the displacement of the flights prevent (for example, related to Patent Document 2).

CITATION

PATENT DOCUMENTS

• Patent Document 1: Publication of Japanese Patent No. 5209764
• Patent Document 2: Publication of Japanese Patent No. 3687279

SUMMARY OF THE INVENTION

PROBLEMS TO BE SOLVED BY THE INVENTION

However, the eccentric bush is slidable and rotatable with respect to a fixed shaft and the movable scroll, and thus there is a problem that the slide bush or spring provided in the eccentric bush may fall out during operation.

The present invention has been made to solve the technical problem in the above-described prior art, and it is an object of the invention to provide a screw fluid machine in which the detachment of a sliding bushing and a sliding bush biasing spring, which in a Eccentric bushing are provided to correct an offset is prevented by a simple structure.

MEANS TO SOLVE THE PROBLEMS

In order to solve the above-described problem, a screw fluid machine according to the present invention includes: a screw unit composed of a stationary screw and a movable screw, each having screw coils formed on base plates thereof opposed to each other by screw flights, and in FIG a working chamber of a working fluid is formed by a circular motion of the movable scroll about an axis of the fixed scroll between the stationary screw and the movable scroll; a frame having a base which rotatively supports the movable scroll at an outer peripheral portion of a rear surface on the opposite side from the base surface of the movable scroll; and a storage mechanism that rotatively supports the movable scroll in a central portion of the rear surface of the movable scroll, the storage mechanism including: a boss provided on the rear surface of the movable scroll; an eccentric bush slidably and rotatably mounted in the boss; a slide bush placed in a receiving hole formed in the eccentric bushing so that the slide bushing is movable in the eccentric direction of the eccentric bushing; a stationary shaft projecting from a lower surface of the frame and slidably and rotatably inserted in an insertion hole formed in the slide bushing; and a spring interposed between the slide bush in the receiving hole and the eccentric bush and biasing the slide bushing in a direction in which the slide bush moves, a spring holding portion and a The engaging protrusion projecting outward is formed on the sliding bush, and the engaging protrusion is engaged with the eccentric bush in a state where the sliding bush is placed in the receiving hole and then moved by a biasing force of the spring, thereby preventing that the slide bush falls out of the receiving hole, and the spring holding portion prevents the spring from falling out of the receiving hole.

The screw type fluid machine according to the invention of claim 2 is characterized in that, in the foregoing invention, the receiving hole is formed continuously through the eccentric bushing, the engaging protrusions are formed on both end portions of the sliding bush and in a state in which the sliding bush passes through Biasing force of the spring has been moved, the engagement projections with both opening edge portions of the receiving hole of the eccentric bush are engaged.

The screw type fluid machine according to the invention of claim 3 is characterized in that, in the above inventions, the accommodating hole consists of a large-diameter portion continuously formed by the eccentric bush and a small-diameter portion extending from the Continued portion having a large diameter in the direction of eccentricity, wherein the engagement protrusions are formed at both ends of the sliding bush at peripheral edges, and in a state in which the sliding bush was placed in the large-diameter portion of the receiving hole and then the sliding bush through the biasing force of the spring has been moved into the small-diameter portion, the portions of the engaging projections positioned in the direction of movement are engaged with both opening edge portions of the small-diameter portion of the receiving hole, and the portions of the opposite S The engagement protrusions positioned laterally from the direction of movement duplicate as the spring retaining portion.

The screw type fluid machine according to the invention of claim 4 is characterized in that, in the invention of claim 1, the receiving hole is continuously formed by the eccentric bush, the engaging protrusions are formed on the other end portion of the sliding bush and, in a state in which the sliding bush has been moved by the biasing force of the spring, are engaged with an opening edge portion of the receiving hole, and an end portion of the sliding bush is provided with a fixing member for preventing the sliding bush and the spring from falling out, the fixing member being positioned outside the receiving hole ,

The screw type fluid machine according to the invention of claim 5 is characterized in that, in the foregoing inventions, the spring holding portion has an inclined surface inclined downwardly toward an opening direction of the receiving hole.

The scroll type fluid machine according to the invention of claim 6 is characterized in that, in the foregoing inventions, the scroll unit decompresses from an expansion section which decompresses a working fluid in an expansion chamber formed between the stationary screw and movable scroll windings, and the movable scroll and a compression portion that compresses the working fluid by the kinetic energy recovered by the expansion portion in a compression chamber formed between the windings of the two scrolls.

The screw fluid machine according to the invention of claim 7 is characterized in that, in the above inventions, carbon dioxide is used as the working fluid.

ADVANTAGEOUS EFFECT OF THE INVENTION

The screw fluid machine according to the present invention includes: a screw unit composed of a stationary screw and a movable screw, each having on base surfaces of base plates thereof spiral windings formed opposite to each other, and in which by a circular motion of movable screw is formed around an axis of the fixed screw a working chamber of a working fluid between the coils of the fixed screw and the movable screw; a frame having a base which rotatively supports the movable scroll at an outer peripheral portion of a rear surface on the opposite side from the base surface of the movable scroll; and a storage mechanism that rotatively supports the movable scroll at a central portion of the rear surface of the movable scroll, the storage mechanism including: a boss provided on the rear surface of the movable scroll; an eccentric bush slidably and rotatably mounted in the boss; a sliding bush which is placed in a receiving hole formed in the eccentric bush so that the sliding bush is movable in the eccentric direction of the eccentric bush; a fixed shaft projecting from a lower surface of the frame and slidably and rotatably formed in a sliding bush Insertion hole is inserted; and a spring interposed in the receiving hole between the slide bush and the eccentric bush and biasing the slide bushing in a direction in which the slide bush moves, a spring holding portion and an engagement protrusion protruding outward are provided on the Formed in a state in which the sliding bush was placed in the receiving hole and then the slide bush was moved by a biasing force of the spring, in the eccentric bush, and thereby prevents the sliding bush from falling out of the receiving hole, and the spring holding portion prevents the spring from falling out of the receiving hole. This arrangement makes it possible to prevent the displacement of the worms by the sliding in the eccentric sliding bushing by the biasing force of the spring.

At this time, the spring is held by the spring holding portion formed on the sliding bush, and the engagement projections also formed on the sliding bush are engaged with the eccentric bush by the biasing force of the spring, and thus the sliding bush is prevented from falling out. This means that it is possible by simple machining to prevent the slide bushing and the spring from falling out of the eccentric bush, and thus it is possible to reduce the manufacturing cost.

In this case, as in the invention of claim 2, forming the accommodating hole passing through the eccentric bush and forming the engaging protrusions on both end portions of the sliding bush and arranging the engaging protrusions so that the engaging protrusions engage with both opening edge portions of the accommodating hole of the eccentric bush a state in which the slide bush has been moved by the biasing force of the spring are engaged, it is possible to reliably prevent the slide bush from falling out by the engagement of the engaging projections at both ends of the receiving hole of the eccentric bushing.

Further, the configuration according to the invention of claim 3 may also make it possible to stably hold the sliding bush and the spring in the receiving hole of the eccentric bush so as to prevent the sliding bush and the spring from falling out. More specifically, in the configuration, the accommodation hole is composed of a large-diameter portion continuously formed by the eccentric bushing and a small-diameter portion continuing from the large-diameter portion in the eccentric direction, the engagement projections being at both ends the slide bush is formed at the peripheral edges, and in a state in which the slide bush has been placed in the large diameter portion of the receiving hole, and then moved into the small diameter portion by the biasing force of the spring, the portions are in the direction of Motion positioned engagement projections with both opening edge portions of the small diameter portion of the receiving hole in engagement, and the portions of the positioned on the opposite side of the direction of movement engagement projections duplicates as the spring-holding portion.

Further, as in the invention of claim 4, the receiving hole may be formed through the eccentric bushing continuously, the engaging projection may be formed on the other end portion of the sliding bush and with an opening edge portion of the receiving hole in a state in which the sliding bush by the biasing force of the spring has been moved, and an end portion of the slide bushing may be provided with a fixing member positioned outside the receiving hole to prevent the slide bush and the spring from falling out with the fixing member positioned outside of the receiving hole. In this case, it is necessary that the engagement projection is formed only on the other end portion of the slide bush and the fastener is attached to an end portion of the slide bushing after the spring is inserted between the eccentric bushing and the slide bushing in the receiving hole, which advantageously simplifies the assembly work ,

Further, as in the invention of claim 5, provision of the spring holding portion having a sloped surface which inclines downward toward an opening direction of the receiving hole enables the spring to be formed by using the inclined surface between the eccentric bushing and the sliding bushing the receiving hole is to be introduced. This arrangement makes the spring installation work extremely easy.

Further, as in the invention of claim 6, the above inventions in the single-plate type screw fluid machine uniting the expansion section and the compression section are effective especially in the case where carbon dioxide is used as a working fluid as in claim 7 becomes.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Fig. 10 is a longitudinal side view of a screw fluid machine according to an embodiment to which the present invention has been applied;

2 is a plan view from above of a fixed snail in 1 seen from one side of a base surface;

3 is one on a line AA in 2 assumed sectional view;

4 is an enlarged view of an in 1 illustrated storage mechanism ';

5 is a perspective view of an eccentric bush, to which an in 1 shown Gleitbuchse has been attached (a first embodiment);

6 is a top view of the in 5 illustrated eccentric bushing;

7 is one in a line BB in 6 assumed sectional view;

8th is one in a line CC in 7 assumed sectional view;

9 FIG. 12 is a diagram of a refrigerant circuit of a refrigeration cycle of the embodiment which is the same as that in FIG 1 illustrated screw fluid machine used;

10 Fig. 12 is a top view of an eccentric bushing to which a sliding bush has been attached according to another embodiment of the present invention (a second embodiment);

11 is one on a line DD in 10 assumed sectional view;

12 Fig. 12 is a plan view of an eccentric bushing from above to which a sliding bush has been attached according to another embodiment of the present invention (a third embodiment);

13 is one on a line EE in 12 assumed sectional view;

14 Fig. 12 is a perspective view of an eccentric bushing to which a sliding bush has been attached according to still another embodiment of the present invention (a fourth embodiment);

15 is a top view of the in 14 illustrated eccentric bushing;

16 is one on a line FF in 15 assumed sectional view; and

17 is one in a line GG in 16 assumed sectional view.

AT THE WAY FOR CARRYING OUT THE INVENTION

The following will describe the embodiments of the present invention in detail.

FIRST EMBODIMENT

(1) GENERAL CONSTRUCTION OF A SCREW FLUID MACHINE 1

1 is a longitudinal side view of a screw fluid machine 1 according to one embodiment. The screw fluid machine 1 According to the embodiment, for example, a compressor-integrated expander of a vertical single-plate type, and in a refrigerating cycle RC (refer to FIG 9 ) a heat pump or the like which uses carbon dioxide having a supercritical pressure on the high pressure side as a refrigerant (working fluid). The refrigeration cycle RC is installed in an air conditioner or a water heater of a heat pump type (not shown). The configuration of the refrigeration cycle RC will be described in detail below. The screw fluid machine 1 according to the embodiment has an expansion section 2 which performs an expansion operation by the pressure of a refrigerant and which will be described later, and a compression portion 3 (on a low-level side) by the expansion operation of the expansion section 2 ( 2 ) performs a compression operation.

The screw fluid machine 1 contains a housing 4 , In the case 4 are a snail unit 8th consisting mainly of a fixed snail 6 and a movable screw 7 related to the fixed snail 6 is circled, formed, a main frame (frame) 9 who is the mobile snail 7 encircling, and a stationary wave 11 attached to the lower surface of the main frame 9 is attached, and that of the lower surface of the main frame 9 is provided above, is provided.

The housing 4 is from a main shell 12 , which is the main body, a cap-shaped upper shell 13 , which is the top of the main bowl 12 covering, and a cap-shaped lower shell 14 , which is the lower part of the main shell 12 covers, formed. The housing 4 is by attaching the upper shell 13 and the lower shell 14 assembled together by screws, with the main shell 12 by a sealing material, such as an O-ring, and the interior of the housing 4 hermetically sealed against the exterior. Further, the outer peripheral portion of the main frame 9 on the inside of the main shell 12 attached. Inside the hermetically sealed housing 4 acting, a pressure is going through Compressing a refrigerant (carbon dioxide) from the cooling circuit RC as the working fluid of the screw fluid machine 1 was absorbed by the compression section 3 receive.

An expansion-side intake pipe 16 by which the refrigerant taken up from the refrigeration cycle RC to the expansion section 2 is supplied with the upper shell 13 connected. With the main shell 12 are an expansion-side ejection tube 17 through which the through the expansion section 2 decompressed refrigerant is discharged to the cooling circuit RC out, and a compression-side discharge pipe 18 through which the through the compression section 3 compressed refrigerant is discharged to the cooling circuit RC out connected. The ends of the expansion-side intake manifold 16 and the expansion-side ejection pipe 17 are each to an expansion-side suction chamber 19 and an expansion-side ejection chamber 21 in a base plate 6a the fixed snail 6 are formed, opened and communicate with it. The end of the compression side ejection tube 18 is in the main shell 12 opened and communicates through the interior of the main bowl 12 with a compression-side ejection chamber 22 that are inside the upper shell 13 is formed.

Further, a compression-side intake pipe 23 (in 3 represented and in 1 positioned on the front side), through which the refrigerant taken up by the refrigerating cycle RC to the compression section 3 is supplied with the main shell 12 connected. The end of the compression side intake manifold 23 is to one in the base plate 6a the fixed snail 6 formed compression-side suction chamber 24 open and communicate with it.

Meanwhile, there is a lubricant chamber 26 inside the lower shell 14 formed, and a lubricant for lubricating the screw unit 8th is in the lubricant chamber 26 retained. An oil feed hole 27 ( 2 ), through the base plate 6a the fixed snail 6 and the main frame 9 is, is in the above-described compression-side suction chamber 23 open. The lubricant in the lubricant chamber 26 gets through the oil feed hole 27 to the compression side suction chamber 24 fed.

Further, an oil supply passage 28 along the axial direction of the stationary shaft 11 into the stationary wave 11 drilled. The lower end of the oil supply passage 28 is to the lubricant chamber 26 open while the upper end in the room (recess) in a round projection 31 , which will be discussed below, is opened.

The stationary snail 6 is on an upper surface 9a of the main frame 9 attached. A compression-side ejection hole 32 which will be discussed below is in the radial direction of the fixed scroll 6 slightly closer to the center than the previous compression-side suction chamber 24 the base plate 6a the fixed snail 6 formed throughout. An oil separator 33 that deposits the lubricant in the refrigerant is relative to the compression-side discharge chamber 22 at the opening of the compression side ejection hole 32 appropriate.

The mobile snail 7 is through a pedestal 9b of the main frame 9 stored so that it is the moving screw 7 is possible through an anti-rotation mechanism 34 such as an Oldham ring, perform a circular motion without making a rotation. The anti-rotation mechanism 34 is in the pedestal 9b built in and through a rear surface 7c that has an area on the opposite side of a base area 7b a base plate 7a is slidably inserted, because the movable screw 7 executes the circular motion. Furthermore, the previous round lead 31 in which an eccentric bush to be discussed below 36 slidably and rotatably mounted by insertion on a rear surface 7c the mobile screw 7 provided above.

The screw unit 8th According to the embodiment, a so-called screw unit is of a single-plate type in which both the compression section 3 as well as the expansion section 2 as the working chambers of a refrigerant through a pair of the fixed screw 6 and the mobile screw 7 may be formed in the compressor-integrated expander. The stationary wave 11 stores the mobile snail 7 along with the main frame 9 simply circling, and the stationary wave 11 itself is not driven in rotation.

More special, as in 2 shown, an annular intermediate partition (annular wall) 38 and an annular outer partition 39 in a standing manner on a base surface 6b the fixed snail 6 intended. An outer fixed helical worm winding (winding) 40 is in a standing manner between the intermediate partition 38 and the outer partition 39 provided, and a helical inner fixed worm winding (winding) 41 is provided in a standing manner at a position closer to the center than the intermediate partition 38 is. Furthermore, in the base area 6b an annular groove 42 into which a sealing ring (not shown) is mounted by insertion, concave in the edge surface of the intermediate partition 38 intended.

In the base plate 6a the fixed snail 6 is the previous compressor-side suction chamber 24 at the outer circumferential end of the compression portion 3 a little to the inside of the outer bulkhead 39 formed, and the compression-side ejection hole 32 is at the inner peripheral end of the compression portion 3 a little to the outer side of the intermediate partition 38 formed. In addition, the foregoing expansion-side ejection chamber is 21 at the outer circumferential end of the expansion portion 2 a little to the inner side of the intermediate partition 38 out in the base plate 6a formed, and the previous expansion-side suction chamber 19 is in the central portion, which is the inner peripheral end of the expansion portion 2 is formed. Further, an annular oil groove 43 in the base plate 6a a little to the outer side of the outer bulkhead 39 formed, and the above Ölzuführloch 27 is in the lower surface of a depression passing through a point that is of a predetermined depth and a diameter greater than the width of the groove over the oil 43 is formed, edged, formed.

Meanwhile, a spiral outer movable worm winding (winding) 44 connected to the outer fixed worm winding 40 is engaged, and a helical inner movable worm winding (winding) 46 that with the internal stationary worm winding 41 is engaged, on the base surface 7b the mobile screw 7 provided in a standing manner so that the worms thereof are in opposite directions to each other.

According to the screw unit described above 8th is the expansion section 2 concerning the intermediate partition 38 formed on the inner side, and the compression section 3 is between the intermediate partition 38 and the outer partition 39 educated. More specifically, as indicated by the solid arrow in 1 indicated by the expansion-side intake pipe 16 absorbed refrigerant via the expansion-side suction chamber 19 in the expansion section 2 introduced and in the expansion chamber (working chamber), by the interacting snails 6 and 7 between the windings 41 and 46 is formed, decompressed. The volume of the expansion chamber increases as the expansion chamber expands to the outer peripheries of the screws 6 and 7 moved, and thus causes the movable screw 7 , a circular movement about the axis of the stationary snail 6 perform. The orbiting movement of the mobile screw 7 subjected refrigerant passes through the expansion-side discharge chamber 21 and is through the expansion-side ejection tube 17 to the cooling circuit RC outside the housing 4 pushed out.

Meanwhile, this is from the compression side intake manifold 23 introduced refrigerant via the compression-side suction chamber 24 in the compression section 3 added. As the refrigerant in the preceding expansion chamber decompresses, the movable scroll becomes 7 causes a circular movement about the axis of the stationary screw 6 to carry out the refrigerant through the cooperating screws 6 and 7 in between the windings 40 and 44 compressed compression chamber (working chamber) to compress. When the circular motion of the moving screw 7 continues, the volume of the compression chamber decreases, as the compression chamber to the centers of the screw 6 and 7 moved. Then, the refrigerant that has been converted into a high-pressure refrigerant by the compression-side discharge hole goes down as the volume of the compression chamber decreases 32 and the compression-side ejection chamber 22 , and is passed through the compression side ejection tube 18 to the cooling circuit RC outside the housing 4 pushed out.

Further, during the process, the lubricant in the through the compression side ejection hole 32 in the compression-side ejection chamber 22 discharged refrigerant from the refrigerant when the refrigerant, as indicated by the dashed arrow in 1 indicated by the oil separator 33 passes. The lubricant separated from the refrigerant passes through the in the main frame 9 formed oil return passage 47 and gets into the lubricant chamber 26 retained.

That in the lubricant chamber 26 retained lubricant is due to the pressure difference between the lubricant chamber 26 and the compression side suction chamber 24 through the oil supply passage 28 moved upwards and from the upper end of the stationary shaft 11 expelled to such a camp 49 , a warehouse 48 and a warehouse 51 to be lubricated as discussed below. The lubricant then reaches one between the pedestal 9b of the main frame 9 and the back surface 7c the mobile screw 7 formed back pressure chamber 52 and reached through the oil feed hole 27 the compression-side suction chamber 24 ,

(2) COOLING CIRCUIT RC

9 FIG. 12 is a refrigerant cycle diagram of the refrigeration cycle RC (Embodiment) of the screw fluid machine 1 used according to the present invention. In this scheme are the expansion section 2 and the compression section 3 the screw fluid machine 1 The explanation is presented in a separate way. The compression section 3 by the one of the expansion section 2 the screw fluid machine 1 recovered kinetic energy is driven, forms a low-stage-side compressor (a low-stage-side compression section) in the cooling circuit RC. The previous compression-side ejection tube 18 of the compression section 3 is with a high-level-sided compression section 70a that by an electric motor 70b a high-level compressor 70 in a rear stage of the compression section 3 is positioned, connected.

A gas cooler 71 that cools the refrigerant is with the rear stage of the compression section 70a connected. The expansion section 2 and an expansion valve 72 the screw fluid machine 1 are between the outlet of the gas cooler 71 and the inlet of an evaporator 73 connected in parallel. The refrigerant from the gas cooler 71 is through the previous expansion-side intake pipe 16 in the expansion-side suction chamber 19 of the expansion section 2 added. Further, the refrigerant from the expansion section 2 the screw fluid machine 1 through the expansion-side ejection tube 17 to the evaporator 73 cleverly. Then the refrigerant from the evaporator 73 through the compression-side intake pipe 23 in the compression section 3 the screw fluid machine 1 introduced.

The operation of the cooling circuit RC including the screw fluid machine 1 will now be described. An intermediate-pressure refrigerant (the carbon dioxide refrigerant), the pressure of which through the low-stage-side compression section 3 that by the expansion section 2 the screw fluid machine 1 is driven, is increased by the compression-side ejection tube 18 to the high-level-sided compressor 70 sent and the pressure of it is by the electric motor 70b driven compression section 70a further increased to a high pressure (supercritical). The high pressure refrigerant is passed through the gas cooler 71 cooled while remaining in the supercritical state, and then a part thereof through the expansion-side intake pipe 16 in the expansion section 2 the screw fluid machine 1 recorded and decompressed so that the pressure is reduced.

The rest of the refrigerant becomes the expansion valve 72 sent, decompressing it so that the pressure is reduced. The expansion valve 72 is provided to the flow rate through the expansion section 2 the screw fluid machine 1 to adjust the refrigerant.

In the expansion section 2 decompresses the refrigerant isentropically, which is the mobile screw 7 causes the circular motion to be carried out and the kinetic energy is thereby recovered. The compression section 3 is due to the orbiting motion of the moving screw 7 operated as the low-stage-side compressor. That through the expansion section 2 Decompressed refrigerant is passed through the evaporator 73 heated (or an object is thereby cooled) and through the compression-side intake pipe 23 again in the compression section 3 the screw fluid machine 1 moved in.

As described above, the compression section leads 3 the screw fluid machine 1 a part (the low-stage side) of the compression process of the refrigeration cycle RC out, while the compression section 70a of the compressor 70 on the high-level side, perform the rest (the high-level side) of the compression process. The compression energy in the compression section 3 is through the in the expansion section 2 recovered energy provided.

(3) COUNTERPRINT OF THE MOVABLE SNAIL 7

In the back pressure chamber 52 the screw fluid machine 1 are mainly the sliding sections between the anti-rotation mechanism 34 , and the pedestal 9b and the back surface 7c the mobile screw 7 lubricated by the lubricant. Further, the inside of the case 4 at the discharge pressure of the compression section 3 which, as described above, through the compression-side ejection hole 32 in the compression-side ejection chamber 22 is discharged, so that the lubricant is at a pressure close to the discharge pressure of the compression portion 3 is maintained through the oil supply passage 28 to the back pressure chamber 52 is supplied. Therefore, the movable screw 7 below the discharge pressure of the compression section 3 from the back pressure chamber 52 crowded and against the stationary snail 6 pressed. The back pressure of the back pressure chamber 52 allows the smooth circular motion of the moving screw 7 with respect to the fixed snail 6 ,

As described above, the screw unit becomes 8th in the screw fluid machine 1 driven by the expansion energy of the refrigerant, and the driving force of the screw unit 8th generates the compression energy of the refrigerant. In this case, as described above, the stationary shaft forms 11 a storage mechanism 54 that, along with the main frame 9 and the central portion of the rear surface 7c , the mobile snail 7 circling stores.

(4) CONFIGURATION OF THE STORAGE MECHANISM 54

How special in 4 shown, which is an enlarged cross-sectional view of the storage mechanism 54 the mobile screw 7 is, the upper end portion of the stationary shaft 11 in an insertion hole 57 a sliding bush 56 introduced so that the upper end section through the bearing 49 can slide and rotate. The sliding bush 56 is in a reception hole 58 that of a columnar insertion section 36a is formed continuously in the axial direction thereof, wherein the insertion portion 36a in the center of the eccentric bush 36 positioned so that the sliding bush 56 in the eccentric direction of the eccentric bush 36 is mobile. In other words, the upper end portion of the stationary shaft 11 through the sliding bush 56 in the eccentric bush 36 introduced.

Further, the insertion section 36a the eccentric bush 36 in the round projection 31 through the camp 48 slidably and rotatably mounted. The warehouse 48 takes one on the eccentric bush 36 applied radial load when the movable screw 7 executes the circular motion. Further, a flanged portion 36b which has a diameter larger than the diameter of the boss 31 is at the bottom of the introductory section 36a the eccentric bush 36 shaped, and a bearing 51 is between the flanged section 36b and the main frame 9 intended. Furthermore, a balance weight 59 having an L-shaped cross-section integrally on the flanged portion 36b educated. The balance weight 59 is in the space between the moving screw 7 and the main frame 9 rotates when the mobile snail 7 executes the circular motion.

As described above, the stationary shaft supports 11 the mobile snail 7 through the deposit of the warehouse 49 , the sliding bush 56 , the eccentric bushing 36 , the camp 48 and the camp 51 , The storage mechanism 54 includes the round lead 31 , the eccentric bush 36 , the sliding bush 56 , the stationary wave 11 and a spring 61 , which are discussed below.

(5) CONFIGURATIONS OF THE ECCENTRIC BUSH 36 , THE SOCKET 56 AND THE FEATHER 61

Well, with reference to 5 to 8th , the eccentric bush 36 , the sliding bush 56 and an embodiment of the spring 61 that the preceding storage mechanism 54 form, described in detail. The recording hole 58 the eccentric bush 36 is through the introductory section 36a continuous, in the center of the eccentric bushing 36 is formed, formed and has a cross section which, as shown in the drawings, in the eccentric direction of the eccentric bush 36 is longer. In this case, the recording hole 58 a pair of flat surfaces 58a extending in the direction of eccentricity and facing each other. Further, both opening end portions of the receiving hole 58 with engaging recesses 58b provided concave in the direction of eccentricity at one end.

Meanwhile, the sliding bush has 56 a substantially cylindrical shape, wherein the above-described receiving hole 58 through the center of the bush 56 is formed throughout. The warehouse 49 is on the inner wall surface of the receiving hole 58 Installed. Both end portions of the sliding bushing 56 in the axial direction of the receiving hole 58 are with engaging projections 56a projecting outwardly and at one end in the eccentric direction of the eccentric bushing 36 are formed provided. Further, a spring-holding portion 56b which is recessed except for both end portions in the axial direction, formed at the other end. Furthermore, both side walls of the sliding bush 56 in the eccentric direction of the eccentric bushing 36 are positioned as a pair of flat surfaces 56c educated.

Furthermore, the spring 61 formed from a leaf spring, which is an in 8th has shown cross-sectional shape, and in the in the sliding bushing 56 recessed spring-holding section 56b is provided. The sliding bush 56 is with the spring provided as described above 61 in the spring-holding section 56b in the reception hole 58 that through the introduction section 36a the eccentric bush 36 is formed throughout, installed. At this time, the spring 61 First, squeezed to the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 to move to the other end, and then the sliding bush 56 in the reception hole 58 introduced.

At this time, the dimension is from the outer ends of the wall at both ends of the spring holding portion 56b the sliding bush 56 to the outer ends of the engagement projections 56a smaller than the dimension of the receiving hole 58 in this particular direction. Further, the dimension of each of the flat surfaces 56c the sliding bush 56 so chosen that each of the flat surfaces 56c with the inside of each of the flat surfaces 58a of the reception hole 58 comes in a sliding contact. The feather 61 is in the reception hole 58 between the sliding bush 56 and the eccentric bush 36 interposed. With this arrangement, the sliding bush 56 in the reception hole 58 inserted so that the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 is mobile.

After the sliding bush 56 in the reception hole 58 is placed, tense when the spring 61 , which has been compressed, relieved, the restoring force of the spring 61 the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 before, what the sliding bush 56 to move in the direction of eccentricity. This in turn brings both engagement projections 56a at one end in the direction of eccentricity in both engagement wells 58b at the opening edge portions of the receiving hole 58 the eccentric bush 36 to move to engage each other (the in 7 shown state).

In this state is the sliding bushing 56 in the reception hole 58 the eccentric bush 36 placed so that the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 is movable, and the sliding bush 56 is by the spring 61 continuously in the eccentric direction of the eccentric bushing 36 biased. Further, the engagement between both engagement protrusions prevents 56a the sliding bush 56 and the engagement wells 58b of the reception hole 58 that the sliding bush 56 from the eccentric bush 36 fall out. In addition, the spring 61 in the spring-holding section 56b the sliding bush 56 arranged and pressed against the eccentric bushing 36 , and thus also prevents the spring 61 from the eccentric bush 36 fall out.

Further, the upper end of the stationary shaft 11 on the inner side of the insertion hole 57 the sliding bush 56 which, as described above, in the eccentric bushing 36 is installed in the warehouse 49 introduced, and thus becomes the upper end of the stationary shaft 11 with respect to the insertion hole 57 the sliding bush 56 slidably and rotatably generated. Reference numeral X1 denotes in 2 the axial center of the stationary screw 6 and the stationary shaft 11 (the sliding bush 56 ), and L1 denotes in 6 a line passing through the axial center X1. Reference numeral L2 denotes in 6 a line passing through the axial center of the moving screw 7 and the eccentric bush 36 goes. The difference between L1 and L2 indicates the amount of eccentricity of the mobile screw 7 with respect to the fixed snail 6 (the same applies to the following embodiments).

Because the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 moves while passing through the spring 61 is biased, it becomes the Exzentrizitätsausmaß the movable screw 7 with respect to the fixed snail 6 and the stationary shaft 11 adjusted so as to offset the movable screw 7 with respect to the fixed snail 6 to eliminate. The dimensional relationship between the engagement projections 56a and the engagement wells 58b is chosen so that, even if the sliding bush 56 during an operation, the engagement therebetween is not canceled (the same is applied in the following embodiments).

As described above, the storage mechanism includes 54 for circular storage of the movable screw 7 on the rear surface of the mobile screw 7 provided round projection 31 , the eccentric bush 36 that in the round tab 31 slidably and rotatably mounted in the receiving hole 58 placed slide bush 56 in the eccentric bushing 36 is formed so that the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 movable, the stationary shaft 11 extending from the lower surface of the main frame 9 is provided above and slidably and rotatably in the sliding bushing 56 formed insertion hole 57 is introduced, and the spring 61 between the sliding bush 56 in the reception hole 58 and the eccentric bush 36 is inserted and the sliding bush 56 in the direction in which the sliding bush 56 moved, pretensioned. The sliding bush 56 has a spring-holding section 56b and the outwardly projecting engagement projections 56a , In the state in which the sliding bush 56 in the reception hole 58 was placed and then the sliding bush 56 by the biasing force of the spring 61 has been moved, the engaging projections 56a with the engaging recesses 58b of the reception hole 58 the eccentric bush 36 engaged, thus preventing the slide bushing 56 from the recording hole 58 falls, and the spring-holding section 56b prevents the spring 61 from the recording hole 58 falls. Thus, the offset of the screws 6 and 7 by the movement of the sliding bush 56 in the eccentric direction by the biasing force of the spring 61 be eliminated.

At this time, the spring 61 through the on the sliding bush 56 formed spring-holding section 56b held, and also on the sliding bush 56 formed engaging projections 56a are with those in the receiving hole 58 the eccentric bush 36 formed engaging recesses 58b by the biasing force of the spring 61 engaged and thereby prevents the sliding bushing 56 fall out. In other words, it makes a simple processing, namely forming the spring-holding portion 56b in the sliding bush 56 in a recessed shape and projecting engagement protrusions 56a possible to prevent it from sliding bushing 56 and the spring 61 from the eccentric bush 36 fall out, and thus it becomes possible to reduce the manufacturing costs.

In particular, according to the present embodiment, the receiving hole 58 through the introduction section 36a the eccentric bush 36 formed continuously, and the engagement projections 56a are at both end portions of the sliding bushing 56 formed so that the engagement projections 56a in the state in which the sliding bush 56 by the biasing force of the spring 61 has been moved, with the at both opening edge portions of the receiving hole 58 the eccentric bush 36 formed engaging recesses 58b are engaged. The engagement of the engagement projections 56a At both ends, it also makes it possible to reliably prevent the slide bush 56 from the recording hole 58 the eccentric bush 36 falls.

SECOND EMBODIMENT

(6) OTHER EMBODIMENT OF THE SLIDING SOCKET 56

With reference to 10 and 11 Now, another embodiment of the sliding bush 56 described. The forms of an eccentric bush 36 and a spring 61 are the same as those in the first embodiment ( 5 to 8th ). A sliding bush 56 has a sloping surface in this case 62 pointing in the direction of the opening of a receiving hole 58 is inclined downwards, and that on the wall at an end portion in the axial direction (in 10 and 11 with reference number 56d is formed), which has a spring-holding portion 56b forms.

Further, the wall 56d formed so that it has a low height, leaving the wall 56d like an arrowhead pointing in the direction of the opening of the receiving hole 58 shows, is shaped. The rest of the configuration is the same as the configuration of the first embodiment described above. When the spring 61 in the spring-holding section 56b installed, allows the inclined surface as described above 62 that the spring 61 using the sloping surface 62 between the sliding bush 56 and the eccentric bush 36 in the reception hole 58 is pushed.

In other words, according to the present embodiment, after the sliding bush 56 in the reception hole 58 the eccentric bush 36 is placed, the spring 61 using the sloping surface 62 the Wall 56d between the eccentric bush 36 and the sliding bush 56 in the reception hole 58 be introduced. The inserted spring 61 is with the vertical wall surface on the opposite side of the sloping surface 62 the Wall 56d engaged, thus preventing the spring 61 fall out. Therefore, as compared with the case in which, as in the previous embodiment, the sliding bush 56 with the spring 61 in the spring-holding section 56b provided in the receiving hole 58 is placed, the sliding bush 56 and the spring 61 be very easy to assemble.

THIRD EMBODIMENT

(7) FURTHER EMBODIMENTS OF THE ECCENTRIC BUSH 36 , THE SOCKET 56 AND THE FEATHER 61

Now, referring to 12 and 13 further embodiments of the eccentric bushing 36 , the sliding bush 56 and the spring 61 described. In this case is a spring 61 formed as in 12 shown to have a circularly deformed tubular shape. In this case is also a recording hole 58 an eccentric bush 36 in the axial direction of an insertion section 36a formed throughout. According to the present embodiment, the receiving hole comprises 58 however, a large diameter section 63a which is a circular hole having a large inner diameter and a small diameter portion 63b which is a circular hole having an inner diameter smaller than the inner diameter of the large-diameter portion 63a is. The section of small diameter 63b settles in the direction of eccentricity of the eccentric bushing 36 (The direction in which a sliding bush 56 moved) to the large diameter portion 63a continued. Furthermore, engaging recesses 58b in the sections, the two opening edge portions of the small-diameter portion 63b correspond, concave.

Meanwhile, the sliding bush has 56 a cylindrical shape, and engaging projections 56a are in the axial direction of the sliding bush 56 formed at both ends on the peripheral edges, wherein the engagement projections 56a projecting outwards in a flange shape. The outer diameter of the sliding bush 56 is smaller than the inner diameter of the small-diameter portion 63b of the reception hole 58 , The outer diameter of the engagement projections 56a are sufficiently smaller than the inner diameters of the large diameter section 63a of the reception hole 58 and larger than the inner diameter of the small-diameter portion 63b , Further, the inner diameters of the engagement recesses 58b chosen larger than the outer diameter of the engaging projections 56a to be. The rest of the configuration is the same as the configurations of the above-described embodiments.

Further, a spring 61 in a compressed state between the engagement projections 56a at both ends so provided that the spring 61 , as in 13 shown on the opposite side from the small diameter portion 63b (opposite side of the direction of movement) is located. With the between the engagement projections 56a spring compressed at both ends 61 becomes the sliding bush 56 in the section with large diameter 63a of the reception hole 58 inserted.

At this time, the outer diameters of the engagement projections are 56a the sliding bush 56 sufficiently smaller than the inner diameter of the large diameter portion 63a of the reception hole 58 thus enabling the sliding bushing 56 evenly in the large diameter section 63a is introduced.

If, after the sliding bush 56 as described above, in the receiving hole 58 is placed, the spring 61 is inserted, the spring tenses 61 by the restoring force of it the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 before, and thus causes the sliding bushing 56 in the small diameter section 63b emotional. This in turn causes both engagement projections 56a at one end in the direction of eccentricity, in both engagement recesses 58b to the opening edge portion of the small-diameter portion 63b to intervene to engage each other (the in 12 and 13 shown state).

In this state is the sliding bushing 56 in the reception hole 58 the eccentric bush 36 placed so that the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 is movable, and the sliding bush 56 is by the spring 61 in the direction of eccentricity of the eccentric bushing 36 continuously biased. Further, both engagement projections 56a the sliding bush 56 in the engagement wells 58b of the small diameter section 63b engaged, and thus prevents the sliding bushing 56 from the eccentric bush 36 fall out. Further, the spring 61 on the opposite side of the small diameter section 63b the sliding bush 56 between the engagement projections 56a positioned and relative to the eccentric bush 36 pressed, and thus also the spring 61 prevented from the eccentric bushing 36 falling out.

As described above, according to the third embodiment, the receiving hole 58 from the through the eccentric bushing 36 continuous section with large diameter 63a and the small diameter portion 63b extending in the eccentric direction from the large diameter section 63a continues, assembled, and the engaging projections 56a are at both ends of the sliding bush 56 formed at the peripheral edges. After the sliding bush 56 in the large diameter section 63a of the reception hole 58 is placed and the sliding bushing 56 by the biasing force of the spring 61 in the small diameter section 63b is moved, the portions of the engaging projections positioned in the direction of movement are 56a with the in both opening edge portions of the small-diameter portion 63b of the reception hole 58 in engagement, and the portions of the engaging projections positioned on the opposite side from the moving direction 56a duplicate themselves as a spring-holding section that holds the spring 61 holds. This arrangement allows the sliding bushing 56 and the spring 61 stable in the receiving hole 58 the eccentric bush 36 be held, and thus prevents the sliding bushing 56 and the spring 61 fall out. In addition, the sliding bush 56 cylindrical, resulting in a reduction in processing costs.

FOURTH EMBODIMENT

(8) OTHER ADDITIONAL EMBODIMENTS OF THE ECCENTRIC BUSH 36 , THE SOCKET 56 AND THE FEATHER 61

Now, referring to 14 to 17 further additional embodiments of the eccentric bushing 36 , the sliding bush 56 and the spring 61 described. In the present embodiments, an elliptical receiving hole 58 the same diameter as that of the small diameter section 63b the in 12 and 13 illustrated third embodiment, in an insertion section 36a an eccentric bush 36 educated. The elliptical reception hole 58 is in the eccentric direction of the eccentric bush 36 longer. Furthermore, the engagement projection became 56a around an end portion in the axial direction of the slide bush 56 eliminated. Instead stands, as in 16 shown, an end portion of the sliding bush 56 in the axial direction from a receiving hole 58 in front. Further, a groove 64 formed concave around the protruding portion. An in 14 and 15 illustrated C-shaped fastening element (clip) 66 is in the groove 64 attached. Further, an engagement recess 58b at one end in the axial direction of the receiving hole 58 the eccentric bush 36 not provided. The rest of the configuration is the same as the configurations of the above-described embodiments.

Further, in the case of the present embodiment, the sliding bush becomes 56 first from the other end of the pick-up hole 58 in the reception hole 58 introduced without a spring 61 to install. After that, the spring 61 in a compressed state from one end in the axial direction between the engagement projection 56a at the other end and the groove 64 so introduced that the spring 61 , as in 17 shown, located on the opposite side of the direction of movement. After the spring 61 is inserted, tensioning the restoring force of the spring 61 the sliding bush 56 in the direction of eccentricity of the eccentric bushing 36 in front, and the sliding bush 56 is therefore moved, and thus, the engaging projection is caused 56a at one end in the eccentric direction into the engagement recess 58b enters and is engaged with the opening edge portion (which is in 16 shown state).

In the state in which the spring 61 introduced as described above, there is the groove 64 the sliding bush 56 outside the recording hole 58 , In this state, a fastener 66 in the groove 64 assembled. This causes the fastener 66 with the eccentric bush 36 at one end in the axial direction of the sliding bush 56 is engaged, and this engagement is not solved, even if the sliding bushing 56 emotional. As the fastener 66 at one end of the spring 61 is positioned, forms the fastener 66 in conjunction with the engagement projection positioned at the other end 56a Further, a spring-holding portion. This arrangement prevents the sliding bushing 56 and the spring 61 fall out.

As described above, the receiving hole is 58 through the eccentric bush 36 formed continuously, the engagement projection 56a is at the other end portion of the sliding bush 56 formed and arranged so that it is in the state in which the sliding bush 56 by the biasing force of the spring 61 was moved, with the engagement recess 58b at the opening edge portion of the receiving hole 58 is engaged, and the fastener 66 to prevent the sliding bush 56 and the spring 61 fall out, is at an end portion of the sliding bush 56 installed so that the fastener 66 outside the recording hole 58 is positioned. Therefore, it is necessary that the engaging projection 56a is formed only on the other end portion of the sliding bush, and the fastening element 66 can at an end portion of the sliding bush 56 be attached after the spring 61 between the eccentric bush 36 and the sliding bush 56 in the reception hole 58 is introduced. Thus, the assembly work becomes easier.

In the embodiments, the present invention has been applied to the so-called single-plate type compressor-integrated screw expander taken as an example of the screw fluid machine; however, the inventions of claim 1 to claim 5 are not limited thereto. The present invention is also effective for a screw type fluid machine or the like in which an expansion portion and a compression portion are connected by a drive shaft.

LIST OF REFERENCE NUMBERS

1

Screw fluid machine

2

expansion section

3

Compression section (low-level side)

6

stationary snail

7

movable snail

8th

screw unit

9

main frame

11

stationary shaft

31

round projection

36

eccentric

40, 41, 44, 46

winding

49

camp

54

storage mechanism

56

bush

56a

engaging projection

57

insertion

58

receiving hole

58b

engaging recess

61

feather

63a

Large diameter section

63b

Small diameter section

66

fastener

RC

Cooling circuit

Claims (7)

A screw fluid machine, comprising: a screw unit composed of a stationary screw and a movable screw, each of which has helical windings formed on base surfaces of base plates thereof, the spiral windings facing each other, and moving in a circular motion of the movable one A worm about an axis of the stationary worm is formed a working chamber of a working fluid between the windings of the fixed worm and the movable worm; a frame having a base which rotatively supports the movable scroll at an outer peripheral portion of a rear surface on the opposite side from the base surface of the movable scroll; and a storage mechanism that rotatively supports the movable scroll at a central portion of the rear surface of the movable scroll, the storage mechanism including: a boss provided on the rear surface of the movable scroll; an eccentric bush slidably and rotatably mounted in the boss; a slide bush which is placed in a receiving hole formed in the eccentric bush so that the slide bush is movable in an eccentric direction of the eccentric bush; a stationary shaft projecting from a lower surface of the frame and slidably and rotatably inserted into an insertion hole formed in the slide bush; and a spring interposed between the slide bush in the receiving hole and the eccentric bush and biasing the slide bushing in a direction in which the slide bush moves, a spring holding portion and an engaging protrusion projecting outward at the Sliding sleeve are formed, and the engaging projection with the eccentric bush in a state in which the sliding bush has been placed in the receiving hole and then moved by a biasing force of the spring is engaged, whereby the sliding bush is prevented from falling out of the receiving hole, and the spring holding portion prevents the spring from falling out of the receiving hole. A scroll fluid machine according to claim 1, wherein the receiving hole is formed continuously through the eccentric bush, the engagement projections are formed at both end portions of the slide bush, and the engaging projections are engaged with both opening edge portions of the receiving hole of the eccentric bush in a state in which the sliding bush has been moved by the biasing force of the spring. A scroll fluid machine according to claim 1 or 2, wherein the receiving hole is composed of a large-diameter portion continuously formed by the eccentric bush and a small-diameter portion continuing from the large-diameter portion in the eccentric direction; the engagement projections are formed on peripheral edges at both ends of the slide bush, and in a state where the slide bush has been placed in the large diameter portion of the receiving hole and the slide bush has been moved into the small diameter portion by the biasing force of the spring, the portions of the engaging projections positioned in the direction of movement are both opened at the edge portions The small diameter portion of the receiving hole are engaged, and the portions of the engaging projections positioned on the opposite side from the moving direction duplicate as the spring holding portion. A scroll fluid machine according to claim 1, wherein the receiving hole is formed continuously through the eccentric bush, the engagement projection is formed at the other end portion of the slide bush and, in a state in which the slide bush has been moved by the biasing force of the spring is engaged with an opening edge portion of the receiving hole, and an end portion of the sliding bush is provided with a fixing member for preventing the sliding bush and the spring from falling out, the fixing member being positioned outside the receiving hole. The screw type fluid machine according to any one of claims 1 to 4, wherein said spring holding portion has an inclined surface that slopes downward toward an opening direction of said receiving hole. A scroll fluid machine according to any one of claims 1 to 5, wherein the scroll unit includes: an expansion portion that decompresses a working fluid in an expansion chamber formed between the stationary screw and the movable scroll to thereby revolve the movable scroll to recover kinetic energy; and a compression portion that compresses the working fluid by the kinetic energy recovered by the expansion portion in a compression chamber formed between the coils by the two screws. A scroll fluid machine according to any one of claims 1 to 6, wherein carbon dioxide is used as the working fluid.

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