US20050214138A1 - Multistage rotary compressor - Google Patents
Multistage rotary compressor Download PDFInfo
- Publication number
- US20050214138A1 US20050214138A1 US11/082,188 US8218805A US2005214138A1 US 20050214138 A1 US20050214138 A1 US 20050214138A1 US 8218805 A US8218805 A US 8218805A US 2005214138 A1 US2005214138 A1 US 2005214138A1
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- United States
- Prior art keywords
- closed vessel
- refrigerant gas
- rotary compressing
- supporting member
- oil
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C29/00—Component parts, details or accessories of pumps or pumping installations, not provided for in groups F04C18/00 - F04C28/00
- F04C29/06—Silencing
- F04C29/068—Silencing the silencing means being arranged inside the pump housing
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- A—HUMAN NECESSITIES
- A47—FURNITURE; DOMESTIC ARTICLES OR APPLIANCES; COFFEE MILLS; SPICE MILLS; SUCTION CLEANERS IN GENERAL
- A47L—DOMESTIC WASHING OR CLEANING; SUCTION CLEANERS IN GENERAL
- A47L13/00—Implements for cleaning floors, carpets, furniture, walls, or wall coverings
- A47L13/10—Scrubbing; Scouring; Cleaning; Polishing
- A47L13/16—Cloths; Pads; Sponges
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B32—LAYERED PRODUCTS
- B32B—LAYERED PRODUCTS, i.e. PRODUCTS BUILT-UP OF STRATA OF FLAT OR NON-FLAT, e.g. CELLULAR OR HONEYCOMB, FORM
- B32B27/00—Layered products comprising a layer of synthetic resin
- B32B27/36—Layered products comprising a layer of synthetic resin comprising polyesters
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B32—LAYERED PRODUCTS
- B32B—LAYERED PRODUCTS, i.e. PRODUCTS BUILT-UP OF STRATA OF FLAT OR NON-FLAT, e.g. CELLULAR OR HONEYCOMB, FORM
- B32B5/00—Layered products characterised by the non- homogeneity or physical structure, i.e. comprising a fibrous, filamentary, particulate or foam layer; Layered products characterised by having a layer differing constitutionally or physically in different parts
- B32B5/18—Layered products characterised by the non- homogeneity or physical structure, i.e. comprising a fibrous, filamentary, particulate or foam layer; Layered products characterised by having a layer differing constitutionally or physically in different parts characterised by features of a layer of foamed material
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F01—MACHINES OR ENGINES IN GENERAL; ENGINE PLANTS IN GENERAL; STEAM ENGINES
- F01C—ROTARY-PISTON OR OSCILLATING-PISTON MACHINES OR ENGINES
- F01C21/00—Component parts, details or accessories not provided for in groups F01C1/00 - F01C20/00
- F01C21/10—Outer members for co-operation with rotary pistons; Casings
- F01C21/104—Stators; Members defining the outer boundaries of the working chamber
- F01C21/108—Stators; Members defining the outer boundaries of the working chamber with an axial surface, e.g. side plates
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C18/00—Rotary-piston pumps specially adapted for elastic fluids
- F04C18/30—Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members
- F04C18/34—Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F04C18/08 or F04C18/22 and relative reciprocation between the co-operating members
- F04C18/356—Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F04C18/08 or F04C18/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the outer member
- F04C18/3562—Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F04C18/08 or F04C18/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the outer member the inner and outer member being in contact along one line or continuous surfaces substantially parallel to the axis of rotation
- F04C18/3564—Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F04C18/08 or F04C18/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the outer member the inner and outer member being in contact along one line or continuous surfaces substantially parallel to the axis of rotation the surfaces of the inner and outer member, forming the working space, being surfaces of revolution
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C23/00—Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids
- F04C23/001—Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids of similar working principle
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C23/00—Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids
- F04C23/008—Hermetic pumps
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C29/00—Component parts, details or accessories of pumps or pumping installations, not provided for in groups F04C18/00 - F04C28/00
- F04C29/0092—Removing solid or liquid contaminants from the gas under pumping, e.g. by filtering or deposition; Purging; Scrubbing; Cleaning
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C29/00—Component parts, details or accessories of pumps or pumping installations, not provided for in groups F04C18/00 - F04C28/00
- F04C29/02—Lubrication; Lubricant separation
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C29/00—Component parts, details or accessories of pumps or pumping installations, not provided for in groups F04C18/00 - F04C28/00
- F04C29/02—Lubrication; Lubricant separation
- F04C29/028—Means for improving or restricting lubricant flow
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C29/00—Component parts, details or accessories of pumps or pumping installations, not provided for in groups F04C18/00 - F04C28/00
- F04C29/06—Silencing
- F04C29/065—Noise dampening volumes, e.g. muffler chambers
Definitions
- the present invention relates to a multistage rotary compressor, and more specifically it relates to a multistage rotary compressor that can increase the amount of oil filled into a closed vessel and can efficiently make oil separation in the closed vessel.
- a multistage rotary compressor including a motor-operating element and a rotary compressing element driven by this motor-operating element disposed in a closed vessel has been known.
- a two-stage rotary compressor shown in FIG. 4 will be described.
- FIG. 4 A two-stage rotary compressor shown in FIG. 4 will be described.
- an upper portion in a closed vessel A is provided with a motor-operating element B composed of a stator and a rotor, the rotor is journalled to an upper end portion of a rotating shaft C, a lower portion in the closed vessel A is provided with a rotary compressing element G composed of a low stage side rotary compressing element E and a high stage side rotary compressing element F through a partition plate D, and supporting members H and I are attached to upper and lower portions of the rotary compressing element G respectively.
- Each of the low stage side rotary compressing element E and the high stage side rotary compressing element F includes a disc-shaped cylinder J and a roller K, which rotates on the inside of the cylinder eccentrically.
- rollers K are fitted on eccentric portions L provided on the rotating shaft C respectively. Further, a low pressure chamber and a high pressure chamber are respectively formed in the cylinders J by the fact that a vane biased with a spring not shown always abuts on an outer circumferential surface of the roller K.
- the upper and lower supporting members H and I are provided with bearing portions M and N at the center portions respectively, and shaft-support the rotating shaft C.
- Muffling chambers P and Q are respectively provided so as to surround outer circumferences of the bearing portions M and N, and cover plates R and S for closing the opening surfaces of the muffling chambers P and Q are respectively attached thereto.
- the intermediate pressure refrigerant gas discharged into the closed vessel A is then taken out of a discharge opening Z of the closed vessel A to the outside and cooled. After that the refrigerant gas is sucked into a suction port provided in the upper supporting member H from a lead-in pipe U, and is sucked into the low pressure chamber in the cylinder J of the high stage side rotary compressing element F, where it is compressed into high pressure by eccentric rotation of the roller K.
- This refrigerant gas compressed into the high pressure is discharged from the high pressure chamber of the cylinder J to a muffling chamber P in the upper supporting member H and is discharged from a discharge port communicating with the muffling chamber P to the outside of the closed vessel A through a lead-out pipe V connected to the closed vessel A.
- the high pressure refrigerant gas discharged to the outside of the closed vessel A is supplied to for example a gas cooler in a refrigeration cycle in an air conditioner or the like. Then after cooling the refrigerant gas by the gas cooler, it is pressure-reduced by an expansion valve and vaporized by an evaporator. Then the refrigerant gas passes through an accumulator to be returned from the lead-in pipe T to the compressor.
- the thus formed two-stage rotary compressors have been disclosed in for example Japanese Patent Laid-Open Publications No. 2003-97479 and No. 02-294587, etc.
- oil for lubrication is filled into a closed vessel A.
- the oil is accumulated on the bottom portion in the closed vessel to form an oil reservoir.
- oil in the oil reservoir is pumped up by an oil pump X to be raised along an inner surface of a hole W formed axially in a rotating shaft C, and then the oil is oozed from the hole W onto an outer surface of the rotating shaft C through a plurality of oil holes Y provided on predetermined portions of the rotating shaft C to lubricate the bearing portions M and N in the supporting members H and I and the rollers K in the high stage side rotary compressing element F and the low stage side rotary compressing element E and the like so that the sliding portion of the rotating shaft C is protected from wear.
- the oil raised along the inner surface of the hole W of the rotating shaft C is discharged into the closed vessel A through the upper end of the rotating shaft C and drops down from a small gap between the stator and rotor in the motor-operating element B to return to the oil reservoir.
- a part of oil discharged into the closed vessel is mixed with intermediate pressure refrigerant gas discharged into the closed vessel A and leaves the closed vessel A together with the intermediate pressure refrigerant gas.
- the oil-mixed intermediate pressure refrigerant gas is cooled as mentioned above and then introduced to the high stage side rotary compressing element F to be compressed into high pressure. Then it is discharged outside the closed vessel A.
- the oil-mixed high pressure refrigerant gas is supplied to a refrigerating cycle in an air conditioner or the like as described above, and is returned from the refrigeration cycle to the compressor through an accumulator. At that time the most part of oil is separated from the refrigerant gas in the accumulator.
- the oil filled in the closed vessel A is decreased little by little with an operation of the compressor.
- the level of the oil surface in the oil reservoir in the closed vessel A is gradually lowered.
- the bearing portions M and N in the supporting members H and I and the rollers K in the high stage side rotary compressing element F and the low stage side rotary compressing element E are in a lack of lubrication and the sliding portion of the rotating shaft C cannot be protected from wear so that the rotation of the rotating shaft C is hindered and compressive performance is lowered.
- the level of the oil surface in the oil reservoir at a bottom portion of the closed vessel A cannot be made at a higher position than the cover plate R. If the level of the oil surface in the oil reservoir exceeds the cover plate R, oil flows into the oil reservoir from an outlet of a passage (not shown) for discharging the intermediate pressure refrigerant gas compressed by the low stage side rotary compressing element into the closed vessel A so that the gas discharge is hindered, resulting in that the compression function is remarkably reduced. To prevent the inflow of oil it is necessary to vertically provide a comparatively high discharge pipe (not shown) at the outlet of the passage (not shown) for example.
- a refrigerant gas which is returned from the refrigerating cycle to the compressor through an accumulator, is oil-separated by the accumulator as described above. Nevertheless the oil cannot be perfectly separated and a part of oil remains in the refrigerant gas.
- the oil-containing refrigerant gas is compressed by the low stage side rotary compressing element E into an intermediate pressure to be discharged into the closed vessel A.
- the intermediate pressure refrigerant gas discharged into the closed vessel A is blown onto a lower end portion of the motor-operating element B so that the oil in the refrigerant gas is separated.
- the outlet of the passage (not shown) is not near to the lower end portion of the motor-operating element B, there is a problem that the oil separation in the refrigerant gas in the closed vessel cannot be efficiently made.
- the present invention was made to solve such a problem in a conventional multistage rotary compressor and the object of the present invention is to provide a multistage rotary compressor in which the amount of oil filled into a closed vessel A can be increased and oil separation in the closed vessel can be efficiently made.
- a multistage rotary compressor comprising a plurality of rotary compressing elements in a closed vessel, discharging a discharge refrigerant gas in any one of said rotary compressing elements into the closed vessel, and discharging the discharge refrigerant gas in other rotary compressing elements outside the closed vessel is characterized in that said rotary compressing elements are positioned on upper and lower portions, a cover material, which has a discharge hole for discharging a refrigerant gas into said closed vessel, and defines a discharge muffling chamber, is mounted onto the upper rotary compressing element, and when oil is filled into said closed vessel, the oil level of said filled oil is designed so as to be slightly lower than the discharge hole in said cover material.
- a multistage rotary compressor configured so that a motor-operating element in a closed vessel and rotary compressing elements driven by said motor-operating element are provided on upper and lower portions respectively, a low stage compressing element in said rotary compressing elements is positioned on the upper side and an high stage compressing element in said rotary compressing elements is positioned is the lower side, an intermediate pressure refrigerant gas compressed by said low stage side rotary compressing element is discharged into said closed vessel, the intermediate pressure refrigerant gas discharged into said closed vessel is taken outside the closed vessel and then is cooled and supplied to said high stage side rotary compressing element to be compressed into high pressure, and the high pressure refrigerant gas is discharged outside said closed vessel is characterized in that an upper supporting member is attached onto the upper side of said low stage side rotary compressing element, and to the upper side of said upper supporting member is attached a substantially cup-shaped cover material, which closes an opening surface of a muffling chamber formed in the upper supporting member, an upper supporting member is attached onto the upper side of
- a multistage rotary compressor configured so that a motor-operating element and rotary compressing elements driven by said motor-operating element are provided on upper and lower portions in a closed vessel, a high stage compressing element in said rotary compressing elements is positioned on the upper side and an low stage compressing element in said rotary compressing elements is positioned is the lower side, intermediate pressure refrigerant gas compressed by said low stage side rotary compressing element is taken outside the closed vessel and is then cooled and supplied to said high stage side rotary compressing element to be compressed into high pressure, and the high pressure refrigerant gas is discharged into said closed vessel and the high pressure refrigerant gas discharged into said closed vessel is discharged outside said closed vessel, is characterized in that an upper supporting member is attached onto the upper side of said high stage side rotary compressing element, and to the upper side of said upper supporting member is attached a substantially cup-shaped cover material, which closes an opening surface of a muffling chamber formed in the upper supporting member, an upper end
- a cover material which defines a discharge muffling chamber, is mounted onto the upper rotary compressing element, and when oil is filled into said closed vessel, the oil level of said filled oil is designed so as to be slightly lower than the discharge hole formed in the cover material, the amount of oil filled into the closed vessel can be made more than that of a conventional case.
- the low stage side rotary compressing element of the rotary compressing elements is positioned on the high stage side rotary compressing element
- the upper supporting member is provided on the low stage side rotary compressing element and the substantially cup-shaped cover material is provided on the upper supporting member in such a manner that the height of the cover material is extended to the position of an upper end of the bearing portion in the upper supporting member, the amount of oil filled into the closed vessel can be made more.
- the intermediate pressure refrigerant gas compressed by the low stage side rotary compressing element is discharged from the discharge hole provided on an upper end surface of the substantially cup-shaped cover material near an outer diameter portion of the bearing portion, the refrigerant gas can be blown onto a lower end portion of the rotor positioned just near the discharge hole. Consequently, oil contained in the intermediate pressure refrigerant gas discharged from the discharge hole can be efficiently separated in the closed vessel.
- the high stage side rotary compressing element of the rotary compressing element is positioned on the low stage side rotary compressing element, the upper supporting member is provided on the high stage side rotary compressing element and the substantially cup-shaped cover material is provided on the upper supporting member in such a manner that the height of the cover material is extended to the position of an upper end of the bearing portion in the upper supporting member, the amount of oil filled into the closed vessel can be made more.
- the multistage rotary compressing element in the multistage rotary compressing element according to the first or second aspect, since the level of oil filled in the closed vessel is set near the upper end of the substantially cup-shaped cover material, the amount of oil in the oil reservoir formed on the bottom portion of the closed vessel can be increased. Accordingly, a suction of oil from the oil reservoir during operation can be ensured, a lack of lubrication in the sliding portion and the like of the rotating shaft is removed to protect them from wear and at the same time the compressive performance can be maintained significantly.
- FIG. 1 is a schematic vertical cross-sectional view showing a first embodiment of a multistage rotary compressor according to the present invention
- FIG. 2 is a schematic vertical cross-sectional view showing a second embodiment of a multistage rotary compressor according to the present invention
- FIG. 3 is a schematic vertical cross-sectional view showing a third embodiment of a multistage rotary compressor according to the present invention.
- FIG. 4 is a schematic vertical cross-sectional view showing one example of a conventional multistage rotary compressor.
- FIG. 1 is a schematic vertical cross-sectional view showing a first embodiment of a multistage rotary compressor according to the present invention
- FIG. 2 is a schematic vertical cross-sectional view showing a second embodiment of a multistage rotary compressor according to the present invention
- FIG. 3 is a schematic vertical cross-sectional view showing a third embodiment of a multistage rotary compressor according to the present invention.
- the reference numeral 1 is a closed vessel.
- the closed vessel 1 is comprised of a cylindrical vessel 2 and end caps 3 , 4 attached to opening end portions of the vessel 2 , and is provided in such a manner that a motor-operating element 5 and a rotary compressing element 6 are positioned at upper and lower portions in this closed vessel 1 respectively.
- the motor-operating element 5 is comprised of an annular stator 5 a fixed to an inner surface of the vessel 2 and a rotor 5 b, which rotates inside the stator 5 a .
- the rotor 5 b is journalled to an upper end portion of a rotating shaft 7 .
- This motor-operating element 5 rotates the rotor 5 b by feed to the stator 5 a through a terminal 8 attached to the end cap 3 .
- the terminal 8 is comprised of a base 8 a fixed to an mounting hole of the end cap 3 and a plurality of connecting terminals 8 b provided on the base 8 a while penetrating through an electric insulating material such as glass, synthetic resin or the like.
- a lower end portion of the connecting terminal 8 b is connected to the stator 5 a of the motor-operating element 5 through an internal lead wire, and an upper end portion of the connecting terminal 8 b is connected to an external power source through an external lead wire.
- the rotary compressing element 6 is comprised of a low stage side rotary compressing element 9 and a high stage side compressing element 11 provided under the low stage side rotary compressing element 9 through a partition plate 10 .
- relationship between the upper and lower positions is reversed to conventional general multistage rotary compressing element by providing the high stage side rotary compressing element 11 at the lower side of the low stage side rotary compressing element 9 .
- the low stage side rotary compressing element 9 includes a cylinder 9 a and a roller 9 b, which rotates eccentrically while being fitted to a low stage side eccentric portion 7 a provided on the rotating shaft 7 .
- the high stage side rotary compressing element 11 includes a cylinder 11 a and a roller 11 b, which rotates eccentrically while being fitted to a high stage side eccentric portion 7 b provided on the rotating shaft 7 .
- a vane biased by a spring not shown always abuts on an outer circumferential surface of the roller 9 b of the low stage side rotary compressing element 9 so that the inside of the cylinder 9 a is defined between a low pressure chamber and a high pressure chamber.
- a vane biased by a spring always abuts on an outer circumferential surface of the roller 11 b of the high stage side rotary compressing element 11 so that the inside of the cylinder 11 a is defined between a low pressure chamber and a high pressure chamber. It is noted that the low stage side eccentric portion 7 a provided on the rotating shaft 7 and the high stage side eccentric portion 7 b are shifted by a phase of 180°.
- an upper supporting member 12 is provided on the low stage side rotary compressing element 9 and below the high stage side rotary compressing element 11 is provided a lower supporting member 13 .
- the upper supporting member 12 and the lower supporting member 13 are integrally fixed to each other by a plurality of through bolts with the low stage side rotary compressing element 9 , the partition plate 10 and the high stage side rotary compressing element 11 sandwiched therebetween.
- the upper supporting member 12 has a bearing portion 12 a at the center.
- the bearing portion 12 a is formed to be thin in thickness and long in size, and fits a sleeve inside to rotatably support the rotating shaft 7 .
- a muffling chamber 12 b along the outer circumference of the bearing portion 12 a, and the muffling chamber 12 b communicates with an outlet of a high pressure chamber in the cylinder 9 a of the low stage side rotary compressing element.
- a suction port 12 c is provided in the upper supporting member 12 .
- the suction port 12 c communicates with an inlet of a low pressure chamber through a passage 9 c formed in the cylinder 9 a and at the same time communicates with a refrigerant gas lead-in pipe 14 connected to a lead-in opening 2 a of the vessel 2 through a sleeve 15 .
- a cover material 16 is attached onto an upper surface of the upper supporting member 12 .
- the cover material 16 defines a muffling chamber 12 b and is provided with a hole 16 a at the center, through which the bearing portion 12 a is penetrated. Also a discharge hole 16 b for discharging refrigerant gas is provided near the hole 16 a.
- the lower supporting member 13 has a bearing portion 13 a at the center, and the bearing portion 13 a is formed in a thick wall and in a short dimension and rotatably supports a lower end portion of the rotating shaft 7 without fitting a sleeve inside. Also on the lower surface side of the lower supporting member 13 is provided a muffling chamber 13 b along the outer circumference of the bearing portion 13 a , and the muffling chamber 13 b communicates with an outlet of a high pressure chamber in the cylinder 11 a of the high stage side rotary compressing element 11 , and at the same time it communicates with a discharge port 13 d formed in the lower supporting member 13 .
- This discharge port 13 d communicates with a refrigerant gas lead-out pipe 17 connected to the lead-out opening 2 b of the vessel 2 through a sleeve 18 .
- a suction port 13 c is provided in the lower supporting member 13 .
- the suction port 13 c communicates with an inlet of a low pressure chamber through a passage 11 c formed in the cylinder 11 a and at the same time communicates with a refrigerant gas return lead-in pipe 19 connected to a return lead-in opening 2 c of the vessel 2 through a sleeve 20 .
- a cover plate 21 is fixed onto a lower surface of the lower supporting member 13 with bolts to define the muffling chamber 13 b, and the cover plate 21 is provided with a hole 21 a at the center. This hole 21 a faces a lower end portion of the rotating shaft 7 . It is noted that in the present embodiment an oil pump is not attached to a lower end portion of the rotating shaft 7 .
- Lubricating oil is filled in the closed vessel 1 and an oil reservoir is formed at the bottom portion.
- the level h of the oil surface in the oil reservoir 22 is set at the oil filling so that it is slightly lower than the discharge hole 16 b of the cover material 16 . Accordingly, the amount of oil in the oil reservoir 22 can be more increased as compared with the conventional case. It is noted that if the discharge hole 16 b of the cover material 16 is raised to form an annular tube shape, the amount of filled oil can be further increased by setting the level h of the oil surface in the oil reservoir 22 at a slightly lower portion than the upper end surface of the annular tube shaped discharge hole 16 a.
- the intermediate pressure refrigerant gas discharged into the closed vessel 1 passes through a small gap between the stator 5 a and rotor 5 b in the motor-operating element 5 and moves into an upper region of the closed vessel 1 . Then the intermediate pressure refrigerant gas is discharged to the outside of the closed vessel 1 from an discharge opening 2 d formed at an upper portion of the vessel 2 and is sent to a cooler (not shown) through a discharge pipe (not shown) connected to the discharge opening 2 d and is cooled in the cooler. After that the intermediate pressure refrigerant gas is introduced to the suction port 13 c in the lower supporting member 13 through the refrigerant gas return lead-in pipe 19 .
- the refrigerant gas led in the suction port 13 c of the lower supporting member 13 passes through the passage 11 c formed in the cylinder 11 a of the high stage side rotary compressing element 11 to be sucked in the low pressure chamber, and is compressed into high pressure by eccentric rotation of the roller 11 b.
- the refrigerant gas compressed into high pressure is discharged to the muffling chamber 13 b in the lower supporting member 13 from the high pressure chamber in the cylinder 11 a and is discharged from the discharge port 13 d communicating with the muffling chamber 13 b to the outside of the closed vessel 1 through the refrigerant gas lead-out pipe 17 .
- the high pressure refrigerant gas discharged outside the closed vessel 1 is supplied to for example a gas cooler in a refrigeration cycle such as an air-conditioner (not shown) and cooled by the gas cooler.
- a gas cooler in a refrigeration cycle such as an air-conditioner (not shown) and cooled by the gas cooler.
- the refrigerant gas is pressure reduced by an expansion valve and is evaporated by an evaporator, and then it passes through an accumulator and is returned to the compressor from the refrigerant gas lead-in pipe 14 .
- an oil reservoir 22 exists at the bottom portion in the closed vessel 1 and oil is pumped up from a lower end portion of the rotating shaft 7 being immersed in the oil reservoir 22 .
- a hole 7 c is formed inside the rotating shaft 7 in the axial direction, and the oil in the oil reservoir 22 is raised along the inner surface of the hole 7 c of the rotating shaft 7 by the rotation of the rotating shaft 7 so that it is oozed out onto an outer surface of the rotating shaft 7 through small holes 7 d formed at a plurality of portions in the rotating shaft 7 .
- the oil oozed out of the small holes 7 d lubricates sliding portions of the rotating shaft 7 in the bearing portion 13 a of the lower supporting member 13 , the bearing portion 12 a of the upper supporting member 12 , the low stage side eccentric portion 7 a and the high stage side eccentric portion 7 b . It is noted that the oil raised along the inner surface of the hole 7 c of the rotating shaft 7 is discharged from an upper end of the rotating shaft 7 into the closed vessel and drops down from a small gap between the stator 5 a and the rotor 5 b in the motor-operating element 5 to return to the oil reservoir 22 .
- a level h of the oil surface in the oil reservoir 22 is positioned at a slightly lower portion than the discharge hole 16 b in the cover material 16 during oil filling, the level h is gradually lowered during operation.
- the level of the oil surface during oil filling is set as high as possible as described above so that the amount of oil in the oil reservoir 22 is increased more than in the conventional case, the level h of the oil surface is not markedly lowered during operation.
- the oil in the oil reservoir 22 can be reliably pumped up from a lower end portion of the rotating shaft 7 . Consequently, the lubrication of the sliding portions in the rotating shaft 7 is sufficiently made to protect the sliding portions from wear and at the same time the compressive performance can be highly maintained.
- FIG. 2 a second embodiment shown in FIG. 2 will be described.
- the components corresponding to the above-mentioned first embodiment are denoted by the same reference numerals as described above.
- the reference numeral 1 is a closed vessel.
- the closed vessel 1 is comprised of a vessel 2 formed into a substantially cylindrical shape and end caps 3 , 4 attached to opening end portions of the vessel 2 , and is provided in such a manner that a motor-operating element 5 and a rotary compressing element 6 are positioned at upper and lower portions in this closed vessel 1 respectively.
- the motor-operating element 5 is comprised of an annular stator 5 a fixed to an inner surface of the vessel 2 and a rotor 5 b , which rotates inside the stator 5 a .
- the rotor 5 b is journalled to an upper end portion of a rotating shaft 7 .
- This motor-operating element 5 rotates the rotor 5 b by feed to the stator 5 a through a terminal 8 attached to the end cap 3 .
- the terminal 8 is comprised of a base 8 a fixed to an mounting hole of the end cap 3 and a plurality of connecting terminals 8 b provided on the base 8 a while penetrating through an electric insulating material such as glass, synthetic resin or the like.
- a lower end portion of the connecting terminal 8 b is connected to the stator 5 a of the motor-operating element 5 through an internal lead wire, and an upper end portion of the connecting terminal 8 b is connected to an external power source through an external lead wire.
- the rotary compressing element 6 is comprised of a low stage side rotary compressing element 9 and a high stage side compressing element 11 provided under the low stage side rotary compressing element 9 through a partition plate 10 .
- relationship between the upper and lower positions is reversed to conventional general multistage rotary compressing element by providing the high stage side rotary compressing element 11 at the lower side of the low stage side rotary compressing element 9 .
- the low stage side rotary compressing element 9 includes a cylinder 9 a and a roller 9 b , which rotates eccentrically while being fitted to a low stage side eccentric portion 7 a provided on the rotating shaft 7 .
- the high stage side rotary compressing element 11 includes a cylinder 11 a and a roller 11 b, which rotates eccentrically while being fitted to a high stage side eccentric portion 7 b provided on the rotating shaft 7 .
- a vane biased by a spring not shown always abuts on an outer circumferential surface of the roller 9 b of the low stage side rotary compressing element 9 so that the inside of the cylinder 9 a is defined between a low pressure chamber and a high pressure chamber.
- a vane biased by a spring always abuts on an outer circumferential surface of the roller 11 b of the high stage side rotary compressing element 11 so that the inside of the cylinder 11 a is defined between a low pressure chamber and a high pressure chamber. It is noted that the low stage side eccentric portion 7 a provided on the rotating shaft 7 and the high stage side eccentric portion 7 b are shifted by a phase of 180°.
- an upper supporting member 12 is provided on the low stage side rotary compressing element 9 and below the high stage side rotary compressing element 11 is provided a lower supporting member 13 .
- the upper supporting member 12 and the lower supporting member 13 are integrally fixed to each other by a plurality of through bolts with the low stage side rotary compressing element 9 , the partition plate 10 and the high stage side rotary compressing element 11 sandwiched therebetween.
- the upper supporting member 12 has a bearing portion 12 a at the center.
- the bearing portion 12 a is formed to be thin in thickness and long in size, and fits a sleeve inside to rotatably support the rotating shaft 7 .
- a muffling chamber 12 b along the outer circumference of the bearing portion 12 a, and the muffling chamber 12 b communicates with an outlet of a high pressure chamber in the cylinder 9 a of the low stage side rotary compressing element.
- a suction port 12 c is provided in the upper supporting member 12 .
- the suction port 12 c communicates with an inlet of a low pressure chamber through a passage 9 c formed in the cylinder 9 a and at the same time communicates with a refrigerant gas lead-in pipe 14 connected to a lead-in opening 2 a of the vessel 2 through a sleeve 15 .
- a substantially cup-shaped cover material 16 is attached onto an upper surface of the upper supporting member 12 in an inverted state by fixing flange portions of the lower end of the cover material 16 with bolts so that an opening surface of the muffling chamber 12 b is closed.
- the cover material 16 is formed in a high dimension so that the upper end of the cover material 16 is positioned at an upper end (or near an upper end) of the bearing portion 12 a in the upper supporting member 12 , and a hole 16 a is provided at the center of the upper end surface so that the bearing portion 12 a is fitted into the hole 16 a.
- a discharge hole 16 b for discharging a refrigerant gas is provided near the hole 16 a (in more details, near an outer diameter portion of the bearing portion 12 a ). Consequently, the discharge hole 16 b of the cover material 16 is positioned just near a lower end portion of the rotor 5 b in the motor-operating element 5 . It is noted that the central hole 16 a of the cover material 16 and the upper end portion of the bearing portion 12 a are gas-sealed.
- the lower supporting member 13 has a bearing portion 13 a at the center, and the bearing portion 13 a is formed in a thick wall and in a short dimension and rotatably supports a lower end portion of the rotating shaft 7 without fitting a sleeve inside. Then on the lower surface side of the lower supporting member 13 is provided a muffling chamber 13 b along the outer circumference of the bearing portion 13 a , and the muffling chamber 13 b communicates with an outlet of a high pressure chamber in the cylinder 11 a of the high stage side rotary compressing element 11 , and at the same time it communicates with a discharge port 13 d formed in the lower supporting member 13 .
- This discharge port 13 d communicates with a refrigerant gas lead-out pipe 17 connected to the lead-out opening 2 b of the vessel 2 through a sleeve 18 .
- a suction port 13 c is provided in the lower supporting member 13 .
- the suction port 13 c communicates with an inlet of a low pressure chamber through a passage 11 c formed in the cylinder 11 a and at the same time communicates with a refrigerant gas return lead-in pipe 19 connected to a return lead-in opening 2 c of the vessel 2 through a sleeve 20 .
- a cover plate 21 is fixed onto a lower surface of the lower supporting member 13 with bolts to close an opening surface of the muffling chamber 13 b , and the cover plate 21 is provided with a hole 21 a at the center. This hole 21 a faces a lower end portion of the rotating shaft 7 . It is noted that in the present embodiment an oil pump is not attached to a lower end portion of the rotating shaft 7 .
- Lubricating oil is filled in the closed vessel 1 and an oil reservoir is formed at the bottom portion.
- the upper end of the substantially cup-shaped cover material 16 is extendedly formed highly to a position of the upper end or near the upper position of the high dimensional bearing portion 13 a, a level h of the oil surface in the oil reservoir 22 during oil filling can be set near the upper end of the cover material 16 . Accordingly, the amount of oil in the oil reservoir 22 can be increased more than the conventional case.
- the level h of the oil surface exceeds the upper end of the cover material 16 , since oil flows inside the cover material 16 through the discharge hole 16 , the level h is unsuitable.
- the refrigerant gas supplied from the refrigerant gas lead-in pipe 14 is a refrigerant gas, gas/liquid-separated by the accumulator as mentioned above.
- the refrigerant gas contains oil without perfect gas/liquid separation. Therefore, oil is contained in intermediate pressure refrigerant gas, which is compressed by the low stage side rotary compressing element 9 and discharged into the closed vessel 1 through the discharge hole 16 b of the cover material 16 .
- the discharge hole 16 b of the cover material 16 is positioned just near a lower end portion of the rotor 5 b in the motor-operating element 5 , the intermediate pressure refrigerant gas discharged from the discharge hole 16 b is strongly blown onto the lower end portion of the rotor 5 b .
- oil contained in the intermediate pressure refrigerant gas is efficiently separated and drops down into the oil reservoir 22 .
- the oil-efficiently-separated intermediate pressure refrigerant gas passes through a small gap between the stator 5 a and rotor 5 b in the motor-operating element 5 and moves into an upper region of the closed vessel 1 . Then the intermediate pressure refrigerant gas is discharged from an discharge opening 2 d formed at an upper portion of the vessel 2 and is sent to a cooler (not shown) through a discharge pipe (not shown) connected to the discharge opening 2 d and is cooled in the cooler. After that the intermediate pressure refrigerant gas is introduced to the suction port 13 c in the lower supporting member 13 through the refrigerant gas return lead-in pipe 19 .
- the refrigerant gas led in the suction port 13 c of the lower supporting member 13 passes through the passage 11 c formed in the cylinder 11 a of the high stage side rotary compressing element 11 to be sucked in the low pressure chamber, and is compressed into high pressure by eccentric rotation of the roller 11 b.
- the refrigerant gas compressed into high pressure is discharged to the muffling chamber 13 b in the lower supporting member 13 from the high pressure chamber in the cylinder 11 a and is discharged from the discharge port 13 d communicating with the muffling chamber 13 b to the outside of the closed vessel 1 through the refrigerant gas lead-out pipe 17 .
- the high pressure refrigerant gas discharged outside the closed vessel 1 is supplied to for example a gas cooler in a refrigeration cycle such as an air-conditioner (not shown) and cooled by the gas cooler.
- a gas cooler in a refrigeration cycle such as an air-conditioner (not shown) and cooled by the gas cooler.
- the refrigerant gas is pressure reduced by an expansion valve and is evaporated by an evaporator, and then it passes through an accumulator and is returned to the compressor from the refrigerant gas lead-in pipe 14 .
- an oil reservoir 22 exists at the bottom portion in the closed vessel 1 and oil is pumped up from a lower end portion of the rotating shaft 7 being immersed in the oil reservoir 22 .
- a hole 7 c is formed inside the rotating shaft 7 in the axial direction, and the oil in the oil reservoir 22 is raised along the inner surface of the hole 7 c of the rotating shaft 7 by the rotation of the rotating shaft 7 so that it is oozed out onto an outer surface of the rotating shaft 7 through small holes 7 d formed at a plurality of portions in the rotating shaft 7 .
- the oil oozed out of the small holes 7 d lubricates sliding portions of the rotating shaft 7 in the bearing portion 13 a of the lower supporting member 13 , the bearing portion 12 a of the upper supporting member 12 , the low stage side eccentric portion 7 a and the high stage side eccentric portion 7 b . It is noted that the oil raised along the inner surface of the hole 7 c of the rotating shaft 7 is discharged from an upper end of the rotating shaft 7 into the closed vessel and drops down from a small gap between the stator 5 a and the rotor 5 b in the motor-operating element 5 to return to the oil reservoir 22 .
- a level h of the oil surface in the oil reservoir 22 is positioned near the upper end of the cover material 16 during oil filling, the level h is gradually lowered during operation.
- the level h of the oil surface during oil filling is set high as described above so that the amount of oil in the oil reservoir 22 is increased.
- the level h of the oil surface is not extremely lowered during operation.
- the oil in the oil reservoir 22 can be reliably pumped up from a lower end portion of the rotating shaft 7 . Consequently, the lubrication of the sliding portions in the rotating shaft 7 is sufficiently made to protect the sliding portions from wear and at the same time the compressive performance can be highly maintained.
- the reference numeral 1 is a closed vessel.
- the closed vessel 1 is comprised of a vessel 2 into a substantially cylindrical shape and end caps 3 , 4 attached to opening end portions of the vessel 2 , and is provided in such a manner that a motor-operating element 5 and a rotary compressing element 6 are positioned at upper and lower portions in this closed vessel 1 respectively.
- the motor-operating element 5 is comprised of an annular stator 5 a fixed to an inner surface of the vessel 2 and a rotor 5 b , which rotates inside the stator 5 a .
- the rotor 5 b is journalled to an upper end portion of a rotating shaft 7 .
- This motor-operating element 5 rotates the rotor 5 b by feed to the stator 5 a through a terminal 8 attached to the end cap 3 .
- the terminal 8 is comprised of a base 8 a fixed to an mounting hole of the end cap 3 and a plurality of connecting terminals 8 b provided on the base 8 a while penetrating through an electric insulating material such as glass, synthetic resin or the like.
- a lower end portion of the connecting terminal 8 b is connected to the stator 5 a of the motor-operating element 5 through an internal lead wire, and an upper end portion of the connecting terminal 8 b is connected to an external power source through an external lead wire.
- the rotary compressing element 6 is comprised of a low stage side rotary compressing element 9 and a high stage side compressing element 11 provided on the low stage side rotary compressing element 9 through a partition plate 10 .
- the high stage side rotary compressing element 11 is provided on an upper side of the low stage side rotary compressing element 9 so that the rotary compressing element 6 has the same positional relationship as the conventional general multistage rotary compressing element without inversing the upper and lower positions as in the above-mentioned embodiments.
- the low stage side rotary compressing element 9 includes a cylinder 9 a and a roller 9 b , which rotates eccentrically inside the cylinder 9 a while being fitted to a low stage side eccentric portion 7 a provided on the rotating shaft 7 .
- the high stage side rotary compressing element 11 includes a cylinder 11 a and a roller 11 b, which rotates eccentrically inside the cylinder 11 a while being fitted to a high stage side eccentric portion 7 b provided on the rotating shaft 7 .
- a vane biased by a spring not shown always abuts on an outer circumferential surface of the roller 9 b of the low stage side rotary compressing element 9 so that the inside of the cylinder 9 a is defined between a low pressure chamber and a high pressure chamber.
- a vane biased by a spring always abuts on an outer circumferential surface of the roller 11 b of the high stage side rotary compressing element 11 so that the inside of the cylinder 11 a is defined between a low pressure chamber and a high pressure chamber. It is noted that the low stage side eccentric portion 7 a provided on the rotating shaft 7 and the high stage side eccentric portion 7 b are shifted by a phase of 180°.
- an upper supporting member 12 is provided on the high stage side rotary compressing element 11 and below the low stage side rotary compressing element 9 is provided a lower supporting member 13 .
- the upper supporting member 12 and the lower supporting member 13 are integrally fixed to each other by a plurality of through bolts with the high stage side rotary compressing element 11 , the partition plate 10 and the low stage side rotary compressing element 9 sandwiched therebetween.
- the upper supporting member 12 has a bearing portion 12 a at the center.
- the bearing portion 12 a is formed to be thin in thickness and long in size, and fits a sleeve inside to rotatably support the rotating shaft 7 .
- On the upper surface side of the upper supporting member 12 is provided a muffling chamber 12 b along the outer circumference of the bearing portion 12 a, and the muffling chamber 12 b communicates with an outlet of a high pressure chamber in the cylinder 11 a of the high stage side rotary compressing element 11 .
- a suction port 12 c is provided in the upper supporting member 12 .
- the suction port 12 c communicates with an inlet of a low pressure chamber through a passage 11 c formed in the cylinder 11 a and at the same time communicates with a refrigerant gas return lead-in pipe 19 connected to a return lead-in opening 2 c of the vessel 2 through a sleeve 20 .
- a substantially cup-shaped cover material 16 is attached onto an upper surface of the upper supporting member 12 in an inverted state by fixing flange portions of the lower end of the cover material 16 with bolts so that an opening surface of the muffling chamber 12 b is closed.
- the cover material 16 is formed in a high dimension so that the upper end of the cover material 16 is positioned at an upper end (or near an upper end) of the bearing portion 12 a in the upper supporting member 12 , and a hole 16 a is provided at the center of the upper end surface so that the bearing portion 12 a is fitted into the hole 16 a.
- a discharge hole 16 b for discharging a refrigerant gas is provided near the hole 16 a.
- the discharge hole 16 b of the cover material 16 is positioned just near a lower end portion of the rotor 5 b in the motor-operating element 5 . It is noted that the central hole 16 a of the cover material 16 and the upper end portion of the bearing portion 12 a are gas-sealed.
- the lower supporting member 13 has a bearing portion 13 a at the center, and the bearing portion 13 a is formed in a thicker wall and in a shorter dimension than the bearing portion 12 a of the upper supporting member 12 and rotatably supports a lower end portion of the rotating shaft 7 without fitting a sleeve inside. Then on the lower surface side of the lower supporting member 13 is provided a muffling chamber 13 b along the outer circumference of the bearing portion 13 a , and the muffling chamber 13 b communicates with an outlet of a high pressure chamber in the cylinder 9 a of the low stage side rotary compressing element 9 , and at the same time it communicates with a discharge port 13 d formed in the lower supporting member 13 .
- This discharge port 13 d communicates with a refrigerant gas lead-out pipe 17 connected to the lead-out opening 2 b of the vessel 2 through a sleeve 18 .
- a suction port 13 c is provided in the lower supporting member 13 .
- the suction port 13 c communicates with an inlet of a low pressure chamber through a passage 9 c formed in the cylinder 9 a and at the same time communicates with a refrigerant gas lead-in pipe 14 connected to a lead-in opening 2 a of the vessel 2 through a sleeve 15 .
- a cover plate 21 is fixed onto a lower surface of the lower supporting member 13 with bolts to close an opening surface of the muffling chamber 13 b , and the cover plate 21 is provided with a hole 21 a at the center. This hole 21 a faces a lower end portion of the rotating shaft 7 . It is noted that in the present embodiment an oil pump is not attached to a lower end portion of the rotating shaft 7 .
- Lubricating oil is filled in the closed vessel 1 and an oil reservoir is formed at the bottom portion.
- the upper end of the substantially cup-shaped cover material 16 is extendedly formed highly to a position of the upper end or near the upper position of the high dimensional bearing portion 13 a , a level h of the oil surface in the oil reservoir 22 during oil filling can be set near the upper end of the cover material 16 . Accordingly, the amount of oil in the oil reservoir 22 can be increased more than the conventional case.
- the level h of the oil surface exceeds the upper end of the cover material 16 , since oil flows inside the cover material 16 through the discharge hole 16 b, the level h is unsuitable.
- the refrigerant gas compressed into the intermediate pressure is discharged to the muffling chamber 13 b in the lower supporting member 13 from the high pressure chamber in the cylinder 9 a and is discharged to the outside of the closed vessel 1 from the discharge port 13 d communicating with the muffling chamber 13 b through the refrigerant gas lead-out pipe 17 .
- the intermediate pressure refrigerant gas discharged outside the closed vessel 1 is sent to a cooler (not shown) through a discharge pipe (not shown) connected to a refrigerant gas lead-out pipe 17 and cooled there. Then the refrigerant gas is introduced to the suction port 12 c in the upper supporting member 12 from the refrigerant gas return lead-in pipe 19 .
- the refrigerant gas introduced to the suction port 12 c is sucked into a low pressure chamber through the passage 11 c formed in the cylinder 11 a of the high stage side rotary compressing element 11 and is compressed into high pressure by eccentric rotation of the roller 11 b.
- the refrigerant gas compressed into the high pressure is discharged into a muffling chamber 12 b in the upper supporting member 12 from the high-pressure chamber in the cylinder 11 a, and is discharged into the closed vessel 1 through the discharge hole 16 b of the cover material 16 communicating with the muffling chamber 12 b. It is noted that since the inner volume of the cover material 16 is added to the inner volume of the muffling chamber 12 b in the upper supporting member 12 , the volume as the muffling chamber is increased. Accordingly, the muffling effect is increased so that the noise during operation can be suppressed.
- the refrigerant gas supplied from the refrigerant gas lead-in pipe 14 to the suction port 13 c of the lower supporting member 13 is a refrigerant gas, gas/liquid-separated by the accumulator as mentioned above.
- the refrigerant gas contains oil without perfect gas/liquid separation. Therefore, oil is contained in intermediate pressure refrigerant gas, which is compressed by the low stage side rotary compressing element 9 and discharged outside the closed vessel 1 .
- the oil-contained intermediate pressure refrigerant gas is cooled by the cooler (not shown) and then sucked into the suction port 12 c of the upper supporting member 12 through a refrigerant gas return lead-in pipe 19 .
- oil is contained in the high-pressure refrigerant gas compressed by the high stage side rotary compressing element 11 and discharged into the closed vessel 1 through the discharge hole 16 b of the cover material 16 .
- the discharge hole 16 b of the cover material 16 is positioned just near a lower end portion of the rotor 5 b in the motor-operating element 5 , the high pressure refrigerant gas discharged from the discharge hole 16 b is strongly blown onto the lower end portion of the rotor 5 b .
- oil contained in the high-pressure refrigerant gas is efficiently separated and drops down into the oil reservoir 22 .
- the oil-efficiently-separated high-pressure refrigerant gas passes through a small gap between the stator 5 a and rotor 5 b in the motor-operating element 5 and moves into an upper region of the closed vessel 1 . Then the high-pressure refrigerant gas is discharged from an discharge opening 2 d formed at an upper portion of the vessel 2 to the outside of the closed vessel 1 and is supplied to for example a gas cooler in a refrigeration cycle such as an air-conditioner not shown through a discharge pipe (not shown) connected to the discharge opening 2 d to be cooled by the gas cooler. After that the high pressure refrigerant gas is pressure-reduced by an expansion valve and is further evaporated by an evaporator and is returned to the compressor from the refrigerant gas lead-in pipe 14 through an accumulator.
- an oil reservoir 22 exists at the bottom portion in the closed vessel 1 and oil is pumped up from a lower end portion of the rotating shaft 7 being immersed in the oil reservoir 22 .
- a hole 7 c is formed inside the rotating shaft 7 in the axial direction, and the oil in the oil reservoir 22 is raised along the inner surface of the hole 7 c of the rotating shaft 7 by the rotation of the rotating shaft 7 so that it is oozed out onto an outer surface of the rotating shaft 7 through small holes 7 d formed at a plurality of portions in the rotating shaft 7 .
- the oil oozed out of the small holes 7 d lubricates sliding portions of the rotating shaft 7 in the bearing portion 13 a of the lower supporting member 13 , the bearing portion 12 a of the upper supporting member 12 , the low stage side eccentric portion 7 a and the high stage side eccentric portion 7 b . It is noted that the oil raised along the inner surface of the hole 7 c of the rotating shaft 7 is discharged from an upper end of the rotating shaft 7 into the closed vessel 1 and drops down from a small gap between the stator 5 a and the rotor 5 b in the motor-operating element 5 to return to the oil reservoir 22 .
- a level h of the oil surface in the oil reservoir 22 is positioned near the upper end of the cover material 16 during oil filling, the level h is gradually lowered during operation.
- the level h of the oil surface during oil filling is set high as described above so that the amount of oil in the oil reservoir 22 is increased.
- the level h of the oil surface is not extremely lowered during operation.
- the oil in the oil reservoir 22 can be reliably pumped up from a lower end portion of the rotating shaft 7 . Consequently, the lubrication of the sliding portions in the rotating shaft 7 is sufficiently made to protect the sliding portions from wear and at the same time the compressive performance can be highly maintained.
- the present invention can be applied to the inside intermediate pressure type multistage rotary compressor, the inside high pressure type multistage rotary compressor, and further the inside high pressure type single stage rotary compressor.
- the multistage rotary compressor according to the present invention can be used in air conditioners for home use and business use, as well as an automobile air conditioner, and further can be used in an icebox, a refrigerator, a vending machine and the like.
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Abstract
The present invention relates to a multistage rotary compressor. In the multistage rotary compressor, a motor-operating element 5 and a rotary compressing element 6 are provided at upper and lower portions in a closed vessel 1. In the rotary compressing element 6, a low stage side rotary compressing element 9 and a high stage side rotary compressing element 11 are positioned on the upper and lower sides respectively. An upper supporting member 12 is attached onto the low stage side rotary compressing element 9, and a substantially cup-shaped cover material 16 is attached onto the upper supporting member 12 to close an opening surface of a muffling chamber 12 b formed in the upper supporting member 12. The substantially cup-shaped cover material 16 is formed in a high dimension so that the upper end of the cover material 16 is positioned at an upper end or near an upper end of a bearing portion 12 a formed in the upper supporting member 12. Further, a discharge hole 16 b for discharging a refrigerant gas is provided in the upper end surface of the cover material 16 near an outer diameter portion of the bearing portion 12 a. Consequently, the level h of the oil surface for oil filled in the closed vessel 1 can be set so as to be near the upper end of the cover material 16. According to the present invention, the amount of oil filled in the closed vessel can be increased and the oil separation in the closed vessel can be efficiently made.
Description
- 1. Field of the Invention
- The present invention relates to a multistage rotary compressor, and more specifically it relates to a multistage rotary compressor that can increase the amount of oil filled into a closed vessel and can efficiently make oil separation in the closed vessel.
- 2. Description of the Related Art
- A multistage rotary compressor including a motor-operating element and a rotary compressing element driven by this motor-operating element disposed in a closed vessel has been known. For example, a two-stage rotary compressor shown in
FIG. 4 will be described. InFIG. 4 , an upper portion in a closed vessel A is provided with a motor-operating element B composed of a stator and a rotor, the rotor is journalled to an upper end portion of a rotating shaft C, a lower portion in the closed vessel A is provided with a rotary compressing element G composed of a low stage side rotary compressing element E and a high stage side rotary compressing element F through a partition plate D, and supporting members H and I are attached to upper and lower portions of the rotary compressing element G respectively. Each of the low stage side rotary compressing element E and the high stage side rotary compressing element F includes a disc-shaped cylinder J and a roller K, which rotates on the inside of the cylinder eccentrically. These rollers K are fitted on eccentric portions L provided on the rotating shaft C respectively. Further, a low pressure chamber and a high pressure chamber are respectively formed in the cylinders J by the fact that a vane biased with a spring not shown always abuts on an outer circumferential surface of the roller K. The upper and lower supporting members H and I are provided with bearing portions M and N at the center portions respectively, and shaft-support the rotating shaft C. Muffling chambers P and Q are respectively provided so as to surround outer circumferences of the bearing portions M and N, and cover plates R and S for closing the opening surfaces of the muffling chambers P and Q are respectively attached thereto. - When a low pressure refrigerant gas is introduced through a lead-in pipe T connected to the closed vessel, this low pressure refrigerant gas is sucked into a suction port in the lower supporting member I and sucked from this suction port to the low pressure chamber in the cylinder J of the low stage side compressing element E where the refrigerant gas is compressed into an intermediate pressure by eccentric rotation of the roller K. The refrigerant gas compressed into the intermediate pressure is discharged from the high pressure chamber of the cylinder J to the muffling chamber Q in the lower supporting member I, and it passes through a passage (not shown) communicating with the muffling chamber Q to be discharged into the closed vessel A. The intermediate pressure refrigerant gas discharged into the closed vessel A is then taken out of a discharge opening Z of the closed vessel A to the outside and cooled. After that the refrigerant gas is sucked into a suction port provided in the upper supporting member H from a lead-in pipe U, and is sucked into the low pressure chamber in the cylinder J of the high stage side rotary compressing element F, where it is compressed into high pressure by eccentric rotation of the roller K. This refrigerant gas compressed into the high pressure is discharged from the high pressure chamber of the cylinder J to a muffling chamber P in the upper supporting member H and is discharged from a discharge port communicating with the muffling chamber P to the outside of the closed vessel A through a lead-out pipe V connected to the closed vessel A.
- Then the high pressure refrigerant gas discharged to the outside of the closed vessel A is supplied to for example a gas cooler in a refrigeration cycle in an air conditioner or the like. Then after cooling the refrigerant gas by the gas cooler, it is pressure-reduced by an expansion valve and vaporized by an evaporator. Then the refrigerant gas passes through an accumulator to be returned from the lead-in pipe T to the compressor. The thus formed two-stage rotary compressors have been disclosed in for example Japanese Patent Laid-Open Publications No. 2003-97479 and No. 02-294587, etc.
- In the above-mentioned conventional multistage rotary compressor, oil for lubrication is filled into a closed vessel A. The oil is accumulated on the bottom portion in the closed vessel to form an oil reservoir. Then during the operation of the multistage rotary compressor oil in the oil reservoir is pumped up by an oil pump X to be raised along an inner surface of a hole W formed axially in a rotating shaft C, and then the oil is oozed from the hole W onto an outer surface of the rotating shaft C through a plurality of oil holes Y provided on predetermined portions of the rotating shaft C to lubricate the bearing portions M and N in the supporting members H and I and the rollers K in the high stage side rotary compressing element F and the low stage side rotary compressing element E and the like so that the sliding portion of the rotating shaft C is protected from wear.
- The oil raised along the inner surface of the hole W of the rotating shaft C is discharged into the closed vessel A through the upper end of the rotating shaft C and drops down from a small gap between the stator and rotor in the motor-operating element B to return to the oil reservoir. However, a part of oil discharged into the closed vessel is mixed with intermediate pressure refrigerant gas discharged into the closed vessel A and leaves the closed vessel A together with the intermediate pressure refrigerant gas. The oil-mixed intermediate pressure refrigerant gas is cooled as mentioned above and then introduced to the high stage side rotary compressing element F to be compressed into high pressure. Then it is discharged outside the closed vessel A. The oil-mixed high pressure refrigerant gas is supplied to a refrigerating cycle in an air conditioner or the like as described above, and is returned from the refrigeration cycle to the compressor through an accumulator. At that time the most part of oil is separated from the refrigerant gas in the accumulator.
- As a result the oil filled in the closed vessel A is decreased little by little with an operation of the compressor. Thus, the level of the oil surface in the oil reservoir in the closed vessel A is gradually lowered. When the level of the oil surface is below a lower end surface of the oil pump X, oil cannot be sucked up from the oil reservoir. In the circumstances, the bearing portions M and N in the supporting members H and I and the rollers K in the high stage side rotary compressing element F and the low stage side rotary compressing element E are in a lack of lubrication and the sliding portion of the rotating shaft C cannot be protected from wear so that the rotation of the rotating shaft C is hindered and compressive performance is lowered.
- If the amount of oil filled into the closed vessel A is increased, the above-mentioned problem can be solved. However, the level of the oil surface in the oil reservoir at a bottom portion of the closed vessel A cannot be made at a higher position than the cover plate R. If the level of the oil surface in the oil reservoir exceeds the cover plate R, oil flows into the oil reservoir from an outlet of a passage (not shown) for discharging the intermediate pressure refrigerant gas compressed by the low stage side rotary compressing element into the closed vessel A so that the gas discharge is hindered, resulting in that the compression function is remarkably reduced. To prevent the inflow of oil it is necessary to vertically provide a comparatively high discharge pipe (not shown) at the outlet of the passage (not shown) for example.
- Further, a refrigerant gas, which is returned from the refrigerating cycle to the compressor through an accumulator, is oil-separated by the accumulator as described above. Nevertheless the oil cannot be perfectly separated and a part of oil remains in the refrigerant gas. The oil-containing refrigerant gas is compressed by the low stage side rotary compressing element E into an intermediate pressure to be discharged into the closed vessel A. The intermediate pressure refrigerant gas discharged into the closed vessel A is blown onto a lower end portion of the motor-operating element B so that the oil in the refrigerant gas is separated. However, since the outlet of the passage (not shown) is not near to the lower end portion of the motor-operating element B, there is a problem that the oil separation in the refrigerant gas in the closed vessel cannot be efficiently made.
- The present invention was made to solve such a problem in a conventional multistage rotary compressor and the object of the present invention is to provide a multistage rotary compressor in which the amount of oil filled into a closed vessel A can be increased and oil separation in the closed vessel can be efficiently made.
- To attain the above-mentioned object a multistage rotary compressor according to the first aspect of the present invention comprising a plurality of rotary compressing elements in a closed vessel, discharging a discharge refrigerant gas in any one of said rotary compressing elements into the closed vessel, and discharging the discharge refrigerant gas in other rotary compressing elements outside the closed vessel is characterized in that said rotary compressing elements are positioned on upper and lower portions, a cover material, which has a discharge hole for discharging a refrigerant gas into said closed vessel, and defines a discharge muffling chamber, is mounted onto the upper rotary compressing element, and when oil is filled into said closed vessel, the oil level of said filled oil is designed so as to be slightly lower than the discharge hole in said cover material.
- Further, a multistage rotary compressor according to the second aspect of the present invention configured so that a motor-operating element in a closed vessel and rotary compressing elements driven by said motor-operating element are provided on upper and lower portions respectively, a low stage compressing element in said rotary compressing elements is positioned on the upper side and an high stage compressing element in said rotary compressing elements is positioned is the lower side, an intermediate pressure refrigerant gas compressed by said low stage side rotary compressing element is discharged into said closed vessel, the intermediate pressure refrigerant gas discharged into said closed vessel is taken outside the closed vessel and then is cooled and supplied to said high stage side rotary compressing element to be compressed into high pressure, and the high pressure refrigerant gas is discharged outside said closed vessel is characterized in that an upper supporting member is attached onto the upper side of said low stage side rotary compressing element, and to the upper side of said upper supporting member is attached a substantially cup-shaped cover material, which closes an opening surface of a muffling chamber formed in the upper supporting member, an upper end of said cover material being positioned on an upper end or near the upper end of a bearing portion formed in said upper supporting member, and a discharge hole for discharging a refrigerant gas is provided on an upper end surface of said cover material and near an outer diameter portion of said bearing portion.
- Further, a multistage rotary compressor according to the third aspect of the invention configured so that a motor-operating element and rotary compressing elements driven by said motor-operating element are provided on upper and lower portions in a closed vessel, a high stage compressing element in said rotary compressing elements is positioned on the upper side and an low stage compressing element in said rotary compressing elements is positioned is the lower side, intermediate pressure refrigerant gas compressed by said low stage side rotary compressing element is taken outside the closed vessel and is then cooled and supplied to said high stage side rotary compressing element to be compressed into high pressure, and the high pressure refrigerant gas is discharged into said closed vessel and the high pressure refrigerant gas discharged into said closed vessel is discharged outside said closed vessel, is characterized in that an upper supporting member is attached onto the upper side of said high stage side rotary compressing element, and to the upper side of said upper supporting member is attached a substantially cup-shaped cover material, which closes an opening surface of a muffling chamber formed in the upper supporting member, an upper end of said cover material being positioned on an upper end or near the upper end of a bearing portion formed in said upper supporting member, and a discharge hole for discharging refrigerant gas is provided on an upper end surface of said cover material and near an outer diameter portion of said bearing portion.
- According to the first aspect of the invention, since in the multistage rotary compressor comprising a plurality of rotary compressing elements in a closed vessel, discharge refrigerant gas in any one of said rotary compressing elements being discharged into the closed vessel, and discharge refrigerant gas in other rotary compressing elements being discharged outside the closed vessel, a cover material, which defines a discharge muffling chamber, is mounted onto the upper rotary compressing element, and when oil is filled into said closed vessel, the oil level of said filled oil is designed so as to be slightly lower than the discharge hole formed in the cover material, the amount of oil filled into the closed vessel can be made more than that of a conventional case. Therefore, even if the level of the oil surface is lowered during the operation, a situation in which oil cannot be sucked up from the oil reservoir does not occur, a lack of lubrication in the sliding portion and the like of the rotating shaft is removed to protect them from wear and at the same time the compressive performance can be maintained significantly.
- Further, according to the second aspect of the invention, since in the inside intermediate pressure type multistage rotary compressor, the low stage side rotary compressing element of the rotary compressing elements is positioned on the high stage side rotary compressing element, the upper supporting member is provided on the low stage side rotary compressing element and the substantially cup-shaped cover material is provided on the upper supporting member in such a manner that the height of the cover material is extended to the position of an upper end of the bearing portion in the upper supporting member, the amount of oil filled into the closed vessel can be made more. Therefore, even if the level of the oil surface is lowered during the operation, a situation in which oil cannot be sucked up from the oil reservoir does not occur, a lack of lubrication in the sliding portion and the like of the rotating shaft is removed to protect them from wear and at the same time the compressive performance can be maintained significantly. Further, since the intermediate pressure refrigerant gas compressed by the low stage side rotary compressing element is discharged from the discharge hole provided on an upper end surface of the substantially cup-shaped cover material near an outer diameter portion of the bearing portion, the refrigerant gas can be blown onto a lower end portion of the rotor positioned just near the discharge hole. Consequently, oil contained in the intermediate pressure refrigerant gas discharged from the discharge hole can be efficiently separated in the closed vessel.
- Further, according to the third aspect of the invention, since in the inside intermediate pressure type multistage rotary compressor, the high stage side rotary compressing element of the rotary compressing element is positioned on the low stage side rotary compressing element, the upper supporting member is provided on the high stage side rotary compressing element and the substantially cup-shaped cover material is provided on the upper supporting member in such a manner that the height of the cover material is extended to the position of an upper end of the bearing portion in the upper supporting member, the amount of oil filled into the closed vessel can be made more. Therefore, even if the level of the oil surface is lowered during the operation, a situation in which oil cannot be sucked up from the oil reservoir does not occur, a lack of lubrication in the sliding portion and the like of the rotating shaft is removed to protect them from wear and at the same time the compressive performance can be maintained significantly. Further, since the high pressure refrigerant gas compressed by the high stage side rotary compressing element is discharged from the discharge hole provided on an upper end surface of the substantially cup-shaped cover material near an outer diameter portion of the bearing portion, the refrigerant gas can be blown onto a lower end portion of the rotor positioned just near the discharge hole. Consequently, oil contained in the high pressure refrigerant gas discharged from the discharge hole can be efficiently separated in the closed vessel.
- Further, according to the third aspect of the invention, in the multistage rotary compressing element according to the first or second aspect, since the level of oil filled in the closed vessel is set near the upper end of the substantially cup-shaped cover material, the amount of oil in the oil reservoir formed on the bottom portion of the closed vessel can be increased. Accordingly, a suction of oil from the oil reservoir during operation can be ensured, a lack of lubrication in the sliding portion and the like of the rotating shaft is removed to protect them from wear and at the same time the compressive performance can be maintained significantly.
-
FIG. 1 is a schematic vertical cross-sectional view showing a first embodiment of a multistage rotary compressor according to the present invention; -
FIG. 2 is a schematic vertical cross-sectional view showing a second embodiment of a multistage rotary compressor according to the present invention; -
FIG. 3 is a schematic vertical cross-sectional view showing a third embodiment of a multistage rotary compressor according to the present invention; and -
FIG. 4 is a schematic vertical cross-sectional view showing one example of a conventional multistage rotary compressor. - Preferred embodiments of the present invention will be described with reference to attached drawings. In the drawings,
FIG. 1 is a schematic vertical cross-sectional view showing a first embodiment of a multistage rotary compressor according to the present invention,FIG. 2 is a schematic vertical cross-sectional view showing a second embodiment of a multistage rotary compressor according to the present invention, andFIG. 3 is a schematic vertical cross-sectional view showing a third embodiment of a multistage rotary compressor according to the present invention. - First, a first embodiment of the present invention shown in
FIG. 1 will be described. Thereference numeral 1 is a closed vessel. Theclosed vessel 1 is comprised of acylindrical vessel 2 andend caps vessel 2, and is provided in such a manner that a motor-operating element 5 and arotary compressing element 6 are positioned at upper and lower portions in thisclosed vessel 1 respectively. - The motor-
operating element 5 is comprised of anannular stator 5 a fixed to an inner surface of thevessel 2 and arotor 5 b, which rotates inside thestator 5 a. Therotor 5 b is journalled to an upper end portion of arotating shaft 7. This motor-operating element 5 rotates therotor 5 b by feed to thestator 5 a through a terminal 8 attached to theend cap 3. - The terminal 8 is comprised of a
base 8 a fixed to an mounting hole of theend cap 3 and a plurality of connectingterminals 8 b provided on thebase 8 a while penetrating through an electric insulating material such as glass, synthetic resin or the like. Although not shown, a lower end portion of the connectingterminal 8 b is connected to thestator 5 a of the motor-operating element 5 through an internal lead wire, and an upper end portion of the connectingterminal 8 b is connected to an external power source through an external lead wire. - The
rotary compressing element 6 is comprised of a low stage siderotary compressing element 9 and a high stageside compressing element 11 provided under the low stage siderotary compressing element 9 through apartition plate 10. In therotary compressing element 6, relationship between the upper and lower positions is reversed to conventional general multistage rotary compressing element by providing the high stage siderotary compressing element 11 at the lower side of the low stage siderotary compressing element 9. The low stage siderotary compressing element 9 includes acylinder 9 a and aroller 9 b, which rotates eccentrically while being fitted to a low stage sideeccentric portion 7 a provided on therotating shaft 7. Also, the high stage siderotary compressing element 11 includes acylinder 11 a and aroller 11 b, which rotates eccentrically while being fitted to a high stage sideeccentric portion 7 b provided on therotating shaft 7. - A vane biased by a spring not shown always abuts on an outer circumferential surface of the
roller 9 b of the low stage siderotary compressing element 9 so that the inside of thecylinder 9 a is defined between a low pressure chamber and a high pressure chamber. Also a vane biased by a spring always abuts on an outer circumferential surface of theroller 11 b of the high stage siderotary compressing element 11 so that the inside of thecylinder 11 a is defined between a low pressure chamber and a high pressure chamber. It is noted that the low stage sideeccentric portion 7 a provided on therotating shaft 7 and the high stage sideeccentric portion 7 b are shifted by a phase of 180°. - Further, on the low stage side
rotary compressing element 9 is provided an upper supportingmember 12 and below the high stage siderotary compressing element 11 is provided a lower supportingmember 13. The upper supportingmember 12 and the lower supportingmember 13 are integrally fixed to each other by a plurality of through bolts with the low stage siderotary compressing element 9, thepartition plate 10 and the high stage siderotary compressing element 11 sandwiched therebetween. - The upper supporting
member 12 has a bearingportion 12 a at the center. The bearingportion 12 a is formed to be thin in thickness and long in size, and fits a sleeve inside to rotatably support therotating shaft 7. Then on the upper surface side of the upper supportingmember 12 is provided amuffling chamber 12 b along the outer circumference of the bearingportion 12 a, and the mufflingchamber 12 b communicates with an outlet of a high pressure chamber in thecylinder 9 a of the low stage side rotary compressing element. Further, asuction port 12 c is provided in the upper supportingmember 12. Thesuction port 12 c communicates with an inlet of a low pressure chamber through apassage 9 c formed in thecylinder 9 a and at the same time communicates with a refrigerant gas lead-inpipe 14 connected to a lead-inopening 2 a of thevessel 2 through asleeve 15. - Further, a
cover material 16 is attached onto an upper surface of the upper supportingmember 12. Thecover material 16 defines a mufflingchamber 12 b and is provided with ahole 16 a at the center, through which the bearingportion 12 a is penetrated. Also adischarge hole 16 b for discharging refrigerant gas is provided near thehole 16 a. - The lower supporting
member 13 has a bearingportion 13 a at the center, and the bearingportion 13 a is formed in a thick wall and in a short dimension and rotatably supports a lower end portion of therotating shaft 7 without fitting a sleeve inside. Also on the lower surface side of the lower supportingmember 13 is provided amuffling chamber 13 b along the outer circumference of the bearingportion 13 a, and the mufflingchamber 13 b communicates with an outlet of a high pressure chamber in thecylinder 11 a of the high stage siderotary compressing element 11, and at the same time it communicates with adischarge port 13 d formed in the lower supportingmember 13. Thisdischarge port 13 d communicates with a refrigerant gas lead-outpipe 17 connected to the lead-outopening 2 b of thevessel 2 through asleeve 18. Further, asuction port 13 c is provided in the lower supportingmember 13. Thesuction port 13 c communicates with an inlet of a low pressure chamber through apassage 11 c formed in thecylinder 11 a and at the same time communicates with a refrigerant gas return lead-inpipe 19 connected to a return lead-inopening 2 c of thevessel 2 through asleeve 20. - Further, a
cover plate 21 is fixed onto a lower surface of the lower supportingmember 13 with bolts to define the mufflingchamber 13 b, and thecover plate 21 is provided with ahole 21 a at the center. Thishole 21 a faces a lower end portion of therotating shaft 7. It is noted that in the present embodiment an oil pump is not attached to a lower end portion of therotating shaft 7. - Lubricating oil is filled in the
closed vessel 1 and an oil reservoir is formed at the bottom portion. However, the level h of the oil surface in theoil reservoir 22 is set at the oil filling so that it is slightly lower than thedischarge hole 16 b of thecover material 16. Accordingly, the amount of oil in theoil reservoir 22 can be more increased as compared with the conventional case. It is noted that if thedischarge hole 16 b of thecover material 16 is raised to form an annular tube shape, the amount of filled oil can be further increased by setting the level h of the oil surface in theoil reservoir 22 at a slightly lower portion than the upper end surface of the annular tube shapeddischarge hole 16 a. - Actions of the thus formed internal intermediate pressure type multistage rotary compressor will be described. When the
stator 5 a of the motor-operating element 5 is energized through the terminal 8, therotor 5 b is rotated and therotary compressing element 6 is driven by the rotation of therotor 5 b as well as therotating shaft 7. Then when low pressure refrigerant gas is introduced through the refrigerant gas lead-inpipe 14 connected to theclosed vessel 1, the low pressure refrigerant gas is sucked to thesuction port 12 c of the upper supportingmember 12 and passes through thepassage 9 c formed in thecylinder 9 a of the low stage siderotary compressing element 9 to be sucked into the low pressure chamber, and the low pressure refrigerant gas is compressed into intermediate pressure by eccentric rotation of theroller 9 b. The refrigerant gas compressed into the intermediate pressure is discharged to the mufflingchamber 12 b in the upper supportingmember 12 from the high pressure chamber in thecylinder 9 a and is discharged to the inside of theclosed vessel 1 from thedischarge hole 16 b of thecover material 16. - The intermediate pressure refrigerant gas discharged into the
closed vessel 1 passes through a small gap between thestator 5 a androtor 5 b in the motor-operating element 5 and moves into an upper region of theclosed vessel 1. Then the intermediate pressure refrigerant gas is discharged to the outside of theclosed vessel 1 from andischarge opening 2 d formed at an upper portion of thevessel 2 and is sent to a cooler (not shown) through a discharge pipe (not shown) connected to thedischarge opening 2 d and is cooled in the cooler. After that the intermediate pressure refrigerant gas is introduced to thesuction port 13 c in the lower supportingmember 13 through the refrigerant gas return lead-inpipe 19. - The refrigerant gas led in the
suction port 13 c of the lower supportingmember 13 passes through thepassage 11 c formed in thecylinder 11 a of the high stage siderotary compressing element 11 to be sucked in the low pressure chamber, and is compressed into high pressure by eccentric rotation of theroller 11 b. The refrigerant gas compressed into high pressure is discharged to the mufflingchamber 13 b in the lower supportingmember 13 from the high pressure chamber in thecylinder 11 a and is discharged from thedischarge port 13 d communicating with the mufflingchamber 13 b to the outside of theclosed vessel 1 through the refrigerant gas lead-outpipe 17. - Then the high pressure refrigerant gas discharged outside the
closed vessel 1 is supplied to for example a gas cooler in a refrigeration cycle such as an air-conditioner (not shown) and cooled by the gas cooler. After that the refrigerant gas is pressure reduced by an expansion valve and is evaporated by an evaporator, and then it passes through an accumulator and is returned to the compressor from the refrigerant gas lead-inpipe 14. - In the operation of the above-mentioned inside intermediate pressure type multistage rotary compressor, an
oil reservoir 22 exists at the bottom portion in theclosed vessel 1 and oil is pumped up from a lower end portion of therotating shaft 7 being immersed in theoil reservoir 22. Ahole 7 c is formed inside therotating shaft 7 in the axial direction, and the oil in theoil reservoir 22 is raised along the inner surface of thehole 7 c of therotating shaft 7 by the rotation of therotating shaft 7 so that it is oozed out onto an outer surface of therotating shaft 7 throughsmall holes 7 d formed at a plurality of portions in therotating shaft 7. The oil oozed out of thesmall holes 7 d lubricates sliding portions of therotating shaft 7 in the bearingportion 13 a of the lower supportingmember 13, the bearingportion 12 a of the upper supportingmember 12, the low stage sideeccentric portion 7 a and the high stage sideeccentric portion 7 b. It is noted that the oil raised along the inner surface of thehole 7 c of therotating shaft 7 is discharged from an upper end of therotating shaft 7 into the closed vessel and drops down from a small gap between thestator 5 a and therotor 5 b in the motor-operating element 5 to return to theoil reservoir 22. - Although a level h of the oil surface in the
oil reservoir 22 is positioned at a slightly lower portion than thedischarge hole 16 b in thecover material 16 during oil filling, the level h is gradually lowered during operation. In the present embodiment, since the level of the oil surface during oil filling is set as high as possible as described above so that the amount of oil in theoil reservoir 22 is increased more than in the conventional case, the level h of the oil surface is not markedly lowered during operation. Thus, the oil in theoil reservoir 22 can be reliably pumped up from a lower end portion of therotating shaft 7. Consequently, the lubrication of the sliding portions in therotating shaft 7 is sufficiently made to protect the sliding portions from wear and at the same time the compressive performance can be highly maintained. - Next, a second embodiment shown in
FIG. 2 will be described. In the second embodiment the components corresponding to the above-mentioned first embodiment are denoted by the same reference numerals as described above. - In
FIG. 2 , thereference numeral 1 is a closed vessel. Theclosed vessel 1 is comprised of avessel 2 formed into a substantially cylindrical shape andend caps vessel 2, and is provided in such a manner that a motor-operating element 5 and arotary compressing element 6 are positioned at upper and lower portions in thisclosed vessel 1 respectively. - The motor-
operating element 5 is comprised of anannular stator 5 a fixed to an inner surface of thevessel 2 and arotor 5 b, which rotates inside thestator 5 a. Therotor 5 b is journalled to an upper end portion of arotating shaft 7. This motor-operating element 5 rotates therotor 5 b by feed to thestator 5 a through a terminal 8 attached to theend cap 3. - The terminal 8 is comprised of a
base 8 a fixed to an mounting hole of theend cap 3 and a plurality of connectingterminals 8 b provided on thebase 8 a while penetrating through an electric insulating material such as glass, synthetic resin or the like. Although not shown, a lower end portion of the connectingterminal 8 b is connected to thestator 5 a of the motor-operating element 5 through an internal lead wire, and an upper end portion of the connectingterminal 8 b is connected to an external power source through an external lead wire. - The
rotary compressing element 6 is comprised of a low stage siderotary compressing element 9 and a high stageside compressing element 11 provided under the low stage siderotary compressing element 9 through apartition plate 10. In therotary compressing element 6, relationship between the upper and lower positions is reversed to conventional general multistage rotary compressing element by providing the high stage siderotary compressing element 11 at the lower side of the low stage siderotary compressing element 9. The low stage siderotary compressing element 9 includes acylinder 9 a and aroller 9 b, which rotates eccentrically while being fitted to a low stage sideeccentric portion 7 a provided on therotating shaft 7. Also, the high stage siderotary compressing element 11 includes acylinder 11 a and aroller 11 b, which rotates eccentrically while being fitted to a high stage sideeccentric portion 7 b provided on therotating shaft 7. - A vane biased by a spring not shown always abuts on an outer circumferential surface of the
roller 9 b of the low stage siderotary compressing element 9 so that the inside of thecylinder 9 a is defined between a low pressure chamber and a high pressure chamber. Also a vane biased by a spring always abuts on an outer circumferential surface of theroller 11 b of the high stage siderotary compressing element 11 so that the inside of thecylinder 11 a is defined between a low pressure chamber and a high pressure chamber. It is noted that the low stage sideeccentric portion 7 a provided on therotating shaft 7 and the high stage sideeccentric portion 7 b are shifted by a phase of 180°. - Further, on the low stage side
rotary compressing element 9 is provided an upper supportingmember 12 and below the high stage siderotary compressing element 11 is provided a lower supportingmember 13. The upper supportingmember 12 and the lower supportingmember 13 are integrally fixed to each other by a plurality of through bolts with the low stage siderotary compressing element 9, thepartition plate 10 and the high stage siderotary compressing element 11 sandwiched therebetween. - The upper supporting
member 12 has a bearingportion 12 a at the center. The bearingportion 12 a is formed to be thin in thickness and long in size, and fits a sleeve inside to rotatably support therotating shaft 7. Then on the upper surface side of the upper supportingmember 12 is provided amuffling chamber 12 b along the outer circumference of the bearingportion 12 a, and the mufflingchamber 12 b communicates with an outlet of a high pressure chamber in thecylinder 9 a of the low stage side rotary compressing element. Further, asuction port 12 c is provided in the upper supportingmember 12. Thesuction port 12 c communicates with an inlet of a low pressure chamber through apassage 9 c formed in thecylinder 9 a and at the same time communicates with a refrigerant gas lead-inpipe 14 connected to a lead-inopening 2 a of thevessel 2 through asleeve 15. - Further, a substantially cup-shaped
cover material 16 is attached onto an upper surface of the upper supportingmember 12 in an inverted state by fixing flange portions of the lower end of thecover material 16 with bolts so that an opening surface of the mufflingchamber 12 b is closed. Thecover material 16 is formed in a high dimension so that the upper end of thecover material 16 is positioned at an upper end (or near an upper end) of the bearingportion 12 a in the upper supportingmember 12, and ahole 16 a is provided at the center of the upper end surface so that the bearingportion 12 a is fitted into thehole 16 a. Also adischarge hole 16 b for discharging a refrigerant gas is provided near thehole 16 a (in more details, near an outer diameter portion of the bearingportion 12 a). Consequently, thedischarge hole 16 b of thecover material 16 is positioned just near a lower end portion of therotor 5 b in the motor-operating element 5. It is noted that thecentral hole 16 a of thecover material 16 and the upper end portion of the bearingportion 12 a are gas-sealed. - The lower supporting
member 13 has a bearingportion 13 a at the center, and the bearingportion 13 a is formed in a thick wall and in a short dimension and rotatably supports a lower end portion of therotating shaft 7 without fitting a sleeve inside. Then on the lower surface side of the lower supportingmember 13 is provided amuffling chamber 13 b along the outer circumference of the bearingportion 13 a, and the mufflingchamber 13 b communicates with an outlet of a high pressure chamber in thecylinder 11 a of the high stage siderotary compressing element 11, and at the same time it communicates with adischarge port 13 d formed in the lower supportingmember 13. Thisdischarge port 13 d communicates with a refrigerant gas lead-outpipe 17 connected to the lead-outopening 2 b of thevessel 2 through asleeve 18. Further, asuction port 13 c is provided in the lower supportingmember 13. Thesuction port 13 c communicates with an inlet of a low pressure chamber through apassage 11 c formed in thecylinder 11 a and at the same time communicates with a refrigerant gas return lead-inpipe 19 connected to a return lead-inopening 2 c of thevessel 2 through asleeve 20. - Further, a
cover plate 21 is fixed onto a lower surface of the lower supportingmember 13 with bolts to close an opening surface of the mufflingchamber 13 b, and thecover plate 21 is provided with ahole 21 a at the center. Thishole 21 a faces a lower end portion of therotating shaft 7. It is noted that in the present embodiment an oil pump is not attached to a lower end portion of therotating shaft 7. - Lubricating oil is filled in the
closed vessel 1 and an oil reservoir is formed at the bottom portion. However, since in the present embodiment the upper end of the substantially cup-shapedcover material 16 is extendedly formed highly to a position of the upper end or near the upper position of the high dimensional bearingportion 13 a, a level h of the oil surface in theoil reservoir 22 during oil filling can be set near the upper end of thecover material 16. Accordingly, the amount of oil in theoil reservoir 22 can be increased more than the conventional case. However, if the level h of the oil surface exceeds the upper end of thecover material 16, since oil flows inside thecover material 16 through thedischarge hole 16, the level h is unsuitable. - Actions of the thus formed internal intermediate pressure type multistage rotary compressor will be described. When the
stator 5 a of the motor-operating element 5 is energized through the terminal 8, therotor 5 b is rotated and therotary compressing element 6 is driven by the rotation of therotor 5 b as well as therotating shaft 7. Then when a low pressure refrigerant gas is introduced through the refrigerant gas lead-inpipe 14 connected to theclosed vessel 1, the low pressure refrigerant gas is sucked to thesuction port 12 c of the upper supportingmember 12 and passes through thepassage 9 c formed in thecylinder 9 a of the low stage siderotary compressing element 9 to be sucked into the low pressure chamber, and the low pressure refrigerant gas is compressed into intermediate pressure by eccentric rotation of theroller 9 b. The refrigerant gas compressed into the intermediate pressure is discharged to the mufflingchamber 12 b in the upper supportingmember 12 from the high pressure chamber in thecylinder 9 a and is discharged to the inside of theclosed vessel 1 from thedischarge hole 16 b of thecover material 16. It is noted that since an inner volume of thecover material 16 is added to the inner volume of the mufflingchamber 12 b in the upper supportingmember 12, the volume as the muffling chamber is increased. Consequently, the muffling effect is increased so that the noise during operation can be suppressed. - The refrigerant gas supplied from the refrigerant gas lead-in
pipe 14 is a refrigerant gas, gas/liquid-separated by the accumulator as mentioned above. However, the refrigerant gas contains oil without perfect gas/liquid separation. Therefore, oil is contained in intermediate pressure refrigerant gas, which is compressed by the low stage siderotary compressing element 9 and discharged into theclosed vessel 1 through thedischarge hole 16 b of thecover material 16. In this embodiment, since thedischarge hole 16 b of thecover material 16 is positioned just near a lower end portion of therotor 5 b in the motor-operating element 5, the intermediate pressure refrigerant gas discharged from thedischarge hole 16 b is strongly blown onto the lower end portion of therotor 5 b. As a result, oil contained in the intermediate pressure refrigerant gas is efficiently separated and drops down into theoil reservoir 22. - The oil-efficiently-separated intermediate pressure refrigerant gas passes through a small gap between the
stator 5 a androtor 5 b in the motor-operating element 5 and moves into an upper region of theclosed vessel 1. Then the intermediate pressure refrigerant gas is discharged from andischarge opening 2 d formed at an upper portion of thevessel 2 and is sent to a cooler (not shown) through a discharge pipe (not shown) connected to thedischarge opening 2 d and is cooled in the cooler. After that the intermediate pressure refrigerant gas is introduced to thesuction port 13 c in the lower supportingmember 13 through the refrigerant gas return lead-inpipe 19. - The refrigerant gas led in the
suction port 13 c of the lower supportingmember 13 passes through thepassage 11 c formed in thecylinder 11 a of the high stage siderotary compressing element 11 to be sucked in the low pressure chamber, and is compressed into high pressure by eccentric rotation of theroller 11 b. The refrigerant gas compressed into high pressure is discharged to the mufflingchamber 13 b in the lower supportingmember 13 from the high pressure chamber in thecylinder 11 a and is discharged from thedischarge port 13 d communicating with the mufflingchamber 13 b to the outside of theclosed vessel 1 through the refrigerant gas lead-outpipe 17. - Then the high pressure refrigerant gas discharged outside the
closed vessel 1 is supplied to for example a gas cooler in a refrigeration cycle such as an air-conditioner (not shown) and cooled by the gas cooler. After that the refrigerant gas is pressure reduced by an expansion valve and is evaporated by an evaporator, and then it passes through an accumulator and is returned to the compressor from the refrigerant gas lead-inpipe 14. - In the operation of the above-mentioned inside intermediate pressure type multistage rotary compressor, an
oil reservoir 22 exists at the bottom portion in theclosed vessel 1 and oil is pumped up from a lower end portion of therotating shaft 7 being immersed in theoil reservoir 22. Ahole 7 c is formed inside therotating shaft 7 in the axial direction, and the oil in theoil reservoir 22 is raised along the inner surface of thehole 7 c of therotating shaft 7 by the rotation of therotating shaft 7 so that it is oozed out onto an outer surface of therotating shaft 7 throughsmall holes 7 d formed at a plurality of portions in therotating shaft 7. The oil oozed out of thesmall holes 7 d lubricates sliding portions of therotating shaft 7 in the bearingportion 13 a of the lower supportingmember 13, the bearingportion 12 a of the upper supportingmember 12, the low stage sideeccentric portion 7 a and the high stage sideeccentric portion 7 b. It is noted that the oil raised along the inner surface of thehole 7 c of therotating shaft 7 is discharged from an upper end of therotating shaft 7 into the closed vessel and drops down from a small gap between thestator 5 a and therotor 5 b in the motor-operating element 5 to return to theoil reservoir 22. - Although a level h of the oil surface in the
oil reservoir 22 is positioned near the upper end of thecover material 16 during oil filling, the level h is gradually lowered during operation. In the present embodiment, since the level h of the oil surface during oil filling is set high as described above so that the amount of oil in theoil reservoir 22 is increased. Also since oil is efficiently separated from the intermediate pressure refrigerant gas discharged into theclosed vessel 1 through thedischarge hole 16 b of thecover material 16 and is returned to theoil reservoir 22, the level h of the oil surface is not extremely lowered during operation. Thus, the oil in theoil reservoir 22 can be reliably pumped up from a lower end portion of therotating shaft 7. Consequently, the lubrication of the sliding portions in therotating shaft 7 is sufficiently made to protect the sliding portions from wear and at the same time the compressive performance can be highly maintained. - Next, a third embodiment shown in
FIG. 3 will be described. In the third embodiment the components (which contain substantially the same components even if their positions are different) corresponding to the above-mentioned first embodiment or second embodiment are denoted by the same reference numerals as described above. - In
FIG. 3 , thereference numeral 1 is a closed vessel. Theclosed vessel 1 is comprised of avessel 2 into a substantially cylindrical shape andend caps vessel 2, and is provided in such a manner that a motor-operating element 5 and arotary compressing element 6 are positioned at upper and lower portions in thisclosed vessel 1 respectively. - The motor-
operating element 5 is comprised of anannular stator 5 a fixed to an inner surface of thevessel 2 and arotor 5 b, which rotates inside thestator 5 a. Therotor 5 b is journalled to an upper end portion of arotating shaft 7. This motor-operating element 5 rotates therotor 5 b by feed to thestator 5 a through a terminal 8 attached to theend cap 3. - The terminal 8 is comprised of a
base 8 a fixed to an mounting hole of theend cap 3 and a plurality of connectingterminals 8 b provided on thebase 8 a while penetrating through an electric insulating material such as glass, synthetic resin or the like. Although not shown, a lower end portion of the connectingterminal 8 b is connected to thestator 5 a of the motor-operating element 5 through an internal lead wire, and an upper end portion of the connectingterminal 8 b is connected to an external power source through an external lead wire. - The
rotary compressing element 6 is comprised of a low stage siderotary compressing element 9 and a high stageside compressing element 11 provided on the low stage siderotary compressing element 9 through apartition plate 10. In therotary compressing element 6, the high stage siderotary compressing element 11 is provided on an upper side of the low stage siderotary compressing element 9 so that therotary compressing element 6 has the same positional relationship as the conventional general multistage rotary compressing element without inversing the upper and lower positions as in the above-mentioned embodiments. The low stage siderotary compressing element 9 includes acylinder 9 a and aroller 9 b, which rotates eccentrically inside thecylinder 9 a while being fitted to a low stage sideeccentric portion 7 a provided on therotating shaft 7. Also, the high stage siderotary compressing element 11 includes acylinder 11 a and aroller 11 b, which rotates eccentrically inside thecylinder 11 a while being fitted to a high stage sideeccentric portion 7 b provided on therotating shaft 7. - A vane biased by a spring not shown always abuts on an outer circumferential surface of the
roller 9 b of the low stage siderotary compressing element 9 so that the inside of thecylinder 9 a is defined between a low pressure chamber and a high pressure chamber. Also a vane biased by a spring always abuts on an outer circumferential surface of theroller 11 b of the high stage siderotary compressing element 11 so that the inside of thecylinder 11 a is defined between a low pressure chamber and a high pressure chamber. It is noted that the low stage sideeccentric portion 7 a provided on therotating shaft 7 and the high stage sideeccentric portion 7 b are shifted by a phase of 180°. - Further, on the high stage side
rotary compressing element 11 is provided an upper supportingmember 12 and below the low stage siderotary compressing element 9 is provided a lower supportingmember 13. The upper supportingmember 12 and the lower supportingmember 13 are integrally fixed to each other by a plurality of through bolts with the high stage siderotary compressing element 11, thepartition plate 10 and the low stage siderotary compressing element 9 sandwiched therebetween. - The upper supporting
member 12 has a bearingportion 12 a at the center. The bearingportion 12 a is formed to be thin in thickness and long in size, and fits a sleeve inside to rotatably support therotating shaft 7. On the upper surface side of the upper supportingmember 12 is provided amuffling chamber 12 b along the outer circumference of the bearingportion 12 a, and the mufflingchamber 12 b communicates with an outlet of a high pressure chamber in thecylinder 11 a of the high stage siderotary compressing element 11. Further, asuction port 12 c is provided in the upper supportingmember 12. Thesuction port 12 c communicates with an inlet of a low pressure chamber through apassage 11 c formed in thecylinder 11 a and at the same time communicates with a refrigerant gas return lead-inpipe 19 connected to a return lead-inopening 2 c of thevessel 2 through asleeve 20. - Further, a substantially cup-shaped
cover material 16 is attached onto an upper surface of the upper supportingmember 12 in an inverted state by fixing flange portions of the lower end of thecover material 16 with bolts so that an opening surface of the mufflingchamber 12 b is closed. Thecover material 16 is formed in a high dimension so that the upper end of thecover material 16 is positioned at an upper end (or near an upper end) of the bearingportion 12 a in the upper supportingmember 12, and ahole 16 a is provided at the center of the upper end surface so that the bearingportion 12 a is fitted into thehole 16 a. Also adischarge hole 16 b for discharging a refrigerant gas is provided near thehole 16 a. Consequently, thedischarge hole 16 b of thecover material 16 is positioned just near a lower end portion of therotor 5 b in the motor-operating element 5. It is noted that thecentral hole 16 a of thecover material 16 and the upper end portion of the bearingportion 12 a are gas-sealed. - The lower supporting
member 13 has a bearingportion 13 a at the center, and the bearingportion 13 a is formed in a thicker wall and in a shorter dimension than the bearingportion 12 a of the upper supportingmember 12 and rotatably supports a lower end portion of therotating shaft 7 without fitting a sleeve inside. Then on the lower surface side of the lower supportingmember 13 is provided amuffling chamber 13 b along the outer circumference of the bearingportion 13 a, and the mufflingchamber 13 b communicates with an outlet of a high pressure chamber in thecylinder 9 a of the low stage siderotary compressing element 9, and at the same time it communicates with adischarge port 13 d formed in the lower supportingmember 13. Thisdischarge port 13 d communicates with a refrigerant gas lead-outpipe 17 connected to the lead-outopening 2 b of thevessel 2 through asleeve 18. Further, asuction port 13 c is provided in the lower supportingmember 13. Thesuction port 13 c communicates with an inlet of a low pressure chamber through apassage 9 c formed in thecylinder 9 a and at the same time communicates with a refrigerant gas lead-inpipe 14 connected to a lead-inopening 2 a of thevessel 2 through asleeve 15. - Further, a
cover plate 21 is fixed onto a lower surface of the lower supportingmember 13 with bolts to close an opening surface of the mufflingchamber 13 b, and thecover plate 21 is provided with ahole 21 a at the center. Thishole 21 a faces a lower end portion of therotating shaft 7. It is noted that in the present embodiment an oil pump is not attached to a lower end portion of therotating shaft 7. - Lubricating oil is filled in the
closed vessel 1 and an oil reservoir is formed at the bottom portion. However, since in the present embodiment, the upper end of the substantially cup-shapedcover material 16 is extendedly formed highly to a position of the upper end or near the upper position of the high dimensional bearingportion 13 a, a level h of the oil surface in theoil reservoir 22 during oil filling can be set near the upper end of thecover material 16. Accordingly, the amount of oil in theoil reservoir 22 can be increased more than the conventional case. However, if the level h of the oil surface exceeds the upper end of thecover material 16, since oil flows inside thecover material 16 through thedischarge hole 16 b, the level h is unsuitable. - Actions of the thus formed inside high pressure type multistage rotary compressor will be described. When the
stator 5 a of the motor-operating element 5 is energized through the terminal 8, therotor 5 b is rotated and therotary compressing element 6 is driven by the rotation of therotor 5 b as well as therotating shaft 7. Then when a low pressure refrigerant gas is introduced through the refrigerant gas lead-inpipe 14 connected to theclosed vessel 1, the low pressure refrigerant gas is sucked to thesuction port 13 c of the lower supportingmember 13 and passes through thepassage 9 c formed in thecylinder 9 a of the low stage siderotary compressing element 9 to be sucked into the low pressure chamber, and the low pressure refrigerant gas is compressed into intermediate pressure by eccentric rotation of theroller 9 b. The refrigerant gas compressed into the intermediate pressure is discharged to the mufflingchamber 13 b in the lower supportingmember 13 from the high pressure chamber in thecylinder 9 a and is discharged to the outside of theclosed vessel 1 from thedischarge port 13 d communicating with the mufflingchamber 13 b through the refrigerant gas lead-outpipe 17. - The intermediate pressure refrigerant gas discharged outside the
closed vessel 1 is sent to a cooler (not shown) through a discharge pipe (not shown) connected to a refrigerant gas lead-outpipe 17 and cooled there. Then the refrigerant gas is introduced to thesuction port 12 c in the upper supportingmember 12 from the refrigerant gas return lead-inpipe 19. The refrigerant gas introduced to thesuction port 12 c is sucked into a low pressure chamber through thepassage 11 c formed in thecylinder 11 a of the high stage siderotary compressing element 11 and is compressed into high pressure by eccentric rotation of theroller 11 b. The refrigerant gas compressed into the high pressure is discharged into a mufflingchamber 12 b in the upper supportingmember 12 from the high-pressure chamber in thecylinder 11 a, and is discharged into theclosed vessel 1 through thedischarge hole 16 b of thecover material 16 communicating with the mufflingchamber 12 b. It is noted that since the inner volume of thecover material 16 is added to the inner volume of the mufflingchamber 12 b in the upper supportingmember 12, the volume as the muffling chamber is increased. Accordingly, the muffling effect is increased so that the noise during operation can be suppressed. - The refrigerant gas supplied from the refrigerant gas lead-in
pipe 14 to thesuction port 13 c of the lower supportingmember 13 is a refrigerant gas, gas/liquid-separated by the accumulator as mentioned above. However, the refrigerant gas contains oil without perfect gas/liquid separation. Therefore, oil is contained in intermediate pressure refrigerant gas, which is compressed by the low stage siderotary compressing element 9 and discharged outside theclosed vessel 1. The oil-contained intermediate pressure refrigerant gas is cooled by the cooler (not shown) and then sucked into thesuction port 12 c of the upper supportingmember 12 through a refrigerant gas return lead-inpipe 19. Therefore, oil is contained in the high-pressure refrigerant gas compressed by the high stage siderotary compressing element 11 and discharged into theclosed vessel 1 through thedischarge hole 16 b of thecover material 16. In this embodiment, since thedischarge hole 16 b of thecover material 16 is positioned just near a lower end portion of therotor 5 b in the motor-operating element 5, the high pressure refrigerant gas discharged from thedischarge hole 16 b is strongly blown onto the lower end portion of therotor 5 b. As a result, oil contained in the high-pressure refrigerant gas is efficiently separated and drops down into theoil reservoir 22. - The oil-efficiently-separated high-pressure refrigerant gas passes through a small gap between the
stator 5 a androtor 5 b in the motor-operating element 5 and moves into an upper region of theclosed vessel 1. Then the high-pressure refrigerant gas is discharged from andischarge opening 2 d formed at an upper portion of thevessel 2 to the outside of theclosed vessel 1 and is supplied to for example a gas cooler in a refrigeration cycle such as an air-conditioner not shown through a discharge pipe (not shown) connected to thedischarge opening 2 d to be cooled by the gas cooler. After that the high pressure refrigerant gas is pressure-reduced by an expansion valve and is further evaporated by an evaporator and is returned to the compressor from the refrigerant gas lead-inpipe 14 through an accumulator. - In the operation of the above-mentioned inside high pressure type multistage rotary compressor, an
oil reservoir 22 exists at the bottom portion in theclosed vessel 1 and oil is pumped up from a lower end portion of therotating shaft 7 being immersed in theoil reservoir 22. Ahole 7 c is formed inside therotating shaft 7 in the axial direction, and the oil in theoil reservoir 22 is raised along the inner surface of thehole 7 c of therotating shaft 7 by the rotation of therotating shaft 7 so that it is oozed out onto an outer surface of therotating shaft 7 throughsmall holes 7 d formed at a plurality of portions in therotating shaft 7. The oil oozed out of thesmall holes 7 d lubricates sliding portions of therotating shaft 7 in the bearingportion 13 a of the lower supportingmember 13, the bearingportion 12 a of the upper supportingmember 12, the low stage sideeccentric portion 7 a and the high stage sideeccentric portion 7 b. It is noted that the oil raised along the inner surface of thehole 7 c of therotating shaft 7 is discharged from an upper end of therotating shaft 7 into theclosed vessel 1 and drops down from a small gap between thestator 5 a and therotor 5 b in the motor-operating element 5 to return to theoil reservoir 22. - Although a level h of the oil surface in the
oil reservoir 22 is positioned near the upper end of thecover material 16 during oil filling, the level h is gradually lowered during operation. In the present embodiment, since the level h of the oil surface during oil filling is set high as described above so that the amount of oil in theoil reservoir 22 is increased. Also since oil is efficiently separated from the high-pressure refrigerant gas discharged into theclosed vessel 1 through thedischarge hole 16 b of thecover material 16 and is returned to theoil reservoir 22, the level h of the oil surface is not extremely lowered during operation. Thus, the oil in theoil reservoir 22 can be reliably pumped up from a lower end portion of therotating shaft 7. Consequently, the lubrication of the sliding portions in therotating shaft 7 is sufficiently made to protect the sliding portions from wear and at the same time the compressive performance can be highly maintained. - The present invention can be applied to the inside intermediate pressure type multistage rotary compressor, the inside high pressure type multistage rotary compressor, and further the inside high pressure type single stage rotary compressor. In addition, the multistage rotary compressor according to the present invention can be used in air conditioners for home use and business use, as well as an automobile air conditioner, and further can be used in an icebox, a refrigerator, a vending machine and the like.
Claims (3)
1. A multistage rotary compressor comprising a plurality of rotary compressing elements in a closed vessel, discharging a discharge refrigerant gas in any one of said rotary compressing elements into the closed vessel, and discharging the refrigerant gas in other rotary compressing elements outside the closed vessel,
wherein said rotary compressing elements are positioned on upper and lower portions, a cover material, which has a discharge hole for discharging a refrigerant gas into said closed vessel, and defines a discharge muffling chamber, is mounted onto the upper rotary compressing element, and when oil is filled into said closed vessel, the oil level of said filled oil is designed so as to be slightly lower than the discharge hole in said cover material.
2. A multistage rotary compressor configured so that a motor-operating element in a closed vessel and rotary compressing elements driven by said motor-operating element are provided on upper and lower portions respectively, a low stage compressing element in said rotary compressing elements is positioned on the upper side and an high stage compressing element in said rotary compressing elements is positioned is on the lower side, an intermediate pressure refrigerant gas compressed by said low stage side rotary compressing element is discharged into said closed vessel, the intermediate pressure refrigerant gas discharged into said closed vessel is taken outside the closed vessel and then is cooled and supplied to said high stage side rotary compressing element to be compressed into high pressure, and the high pressure refrigerant gas is discharged outside said closed vessel,
wherein an upper supporting member is attached onto the upper side of said low stage side rotary compressing element, and to the upper side of said upper supporting member is attached a substantially cup-shaped cover material, which closes an opening surface of a muffling chamber formed in the upper supporting member, an upper end of said cover material being positioned on an upper end or near the upper end of a bearing portion formed in said upper supporting member, and a discharge hole for discharging a refrigerant gas is provided on an upper end surface of said cover material and near an outer diameter portion of said bearing portion.
3. A multistage rotary compressor configured so that a motor-operating element and rotary compressing elements driven by said motor-operating element are provided on upper and lower portions respectively in a closed vessel, a high stage compressing element in said rotary compressing elements is positioned on the upper side and an low stage compressing element in said rotary compressing elements is positioned is on the lower side, an intermediate pressure refrigerant gas compressed by said low stage side rotary compressing element is taken outside the closed vessel and then is cooled and supplied to said high stage side rotary compressing element to be compressed into high pressure, and the high pressure refrigerant gas is discharged into said closed vessel and the high pressure refrigerant gas discharged into said closed vessel is discharged outside said closed vessel,
wherein an upper supporting member is attached onto the upper side of said high stage side rotary compressing element, and to the upper side of said upper supporting member is attached a substantially cup-shaped cover material, which closes an opening surface of a muffling chamber formed in the upper supporting member, an upper end of said cover material being positioned on an upper end or near the upper end of a bearing portion formed in said upper supporting member, and a discharge hole for discharging refrigerant gas is provided on an upper end surface of said cover material and near an outer diameter portion of said bearing portion.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2004-076171 | 2004-03-17 | ||
JP2004076171A JP2005264780A (en) | 2004-03-17 | 2004-03-17 | Multi-stage rotary compressor |
Publications (1)
Publication Number | Publication Date |
---|---|
US20050214138A1 true US20050214138A1 (en) | 2005-09-29 |
Family
ID=34858346
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US11/082,188 Abandoned US20050214138A1 (en) | 2004-03-17 | 2005-03-16 | Multistage rotary compressor |
Country Status (8)
Country | Link |
---|---|
US (1) | US20050214138A1 (en) |
EP (1) | EP1580433A3 (en) |
JP (1) | JP2005264780A (en) |
KR (1) | KR101136678B1 (en) |
CN (1) | CN1670375A (en) |
BR (1) | BRPI0501167A (en) |
MX (1) | MXPA05002924A (en) |
TW (1) | TWI340794B (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20130156617A1 (en) * | 2010-06-15 | 2013-06-20 | Valeo Japan Co., Ltd. | Short-Shaft Electric Compressor |
CN104989644A (en) * | 2015-07-03 | 2015-10-21 | 广东美芝制冷设备有限公司 | Compressor |
Families Citing this family (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103511278B (en) * | 2013-07-15 | 2016-03-16 | 广东美芝精密制造有限公司 | Rotary compressor |
CN108397385A (en) * | 2017-02-06 | 2018-08-14 | 上海海立电器有限公司 | A kind of compressor and refrigeration system |
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US2243466A (en) * | 1940-03-25 | 1941-05-27 | Gen Motors Corp | Refrigerating apparatus |
US4979879A (en) * | 1989-03-09 | 1990-12-25 | Empresa Brasileira De Compressores, S.A. | Discharge system for rolling piston rotary compressor |
US5022146A (en) * | 1989-08-30 | 1991-06-11 | Tecumseh Products Company | Twin rotary compressor with suction accumulator |
US5586876A (en) * | 1995-11-03 | 1996-12-24 | Carrier Corporation | Rotary compressor having oil pumped through a vertical drive shaft |
US5605447A (en) * | 1996-07-03 | 1997-02-25 | Carrier Corporation | Noise reduction in a hermetic rotary compressor |
US6213732B1 (en) * | 1997-08-28 | 2001-04-10 | Matsushita Electric Industrial Co., Ltd. | Rotary compressor |
US6312233B1 (en) * | 1999-02-26 | 2001-11-06 | Lg Electronics Inc. | Rotary compressor |
US20040001762A1 (en) * | 2002-06-05 | 2004-01-01 | Sanyo Electric Co., Ltd. | Internal intermediate pressure multistage compression type rotary compressor, manufacturing method thereof and displacement ratio setting method |
Family Cites Families (3)
Publication number | Priority date | Publication date | Assignee | Title |
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JPH0267497A (en) * | 1988-09-01 | 1990-03-07 | Sanyo Electric Co Ltd | Muffling device for hermetic compressor |
US5597293A (en) * | 1995-12-11 | 1997-01-28 | Carrier Corporation | Counterweight drag eliminator |
JP2000283077A (en) * | 1999-03-26 | 2000-10-10 | Sanyo Electric Co Ltd | Rotary compressor |
-
2004
- 2004-03-17 JP JP2004076171A patent/JP2005264780A/en active Pending
-
2005
- 2005-02-01 TW TW094102992A patent/TWI340794B/en not_active IP Right Cessation
- 2005-03-15 CN CNA2005100550661A patent/CN1670375A/en active Pending
- 2005-03-15 EP EP05005585A patent/EP1580433A3/en not_active Withdrawn
- 2005-03-16 MX MXPA05002924A patent/MXPA05002924A/en not_active Application Discontinuation
- 2005-03-16 US US11/082,188 patent/US20050214138A1/en not_active Abandoned
- 2005-03-16 KR KR1020050021665A patent/KR101136678B1/en not_active IP Right Cessation
- 2005-03-16 BR BR0501167-1A patent/BRPI0501167A/en not_active IP Right Cessation
Patent Citations (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2243466A (en) * | 1940-03-25 | 1941-05-27 | Gen Motors Corp | Refrigerating apparatus |
US4979879A (en) * | 1989-03-09 | 1990-12-25 | Empresa Brasileira De Compressores, S.A. | Discharge system for rolling piston rotary compressor |
US5022146A (en) * | 1989-08-30 | 1991-06-11 | Tecumseh Products Company | Twin rotary compressor with suction accumulator |
US5586876A (en) * | 1995-11-03 | 1996-12-24 | Carrier Corporation | Rotary compressor having oil pumped through a vertical drive shaft |
US5605447A (en) * | 1996-07-03 | 1997-02-25 | Carrier Corporation | Noise reduction in a hermetic rotary compressor |
US6213732B1 (en) * | 1997-08-28 | 2001-04-10 | Matsushita Electric Industrial Co., Ltd. | Rotary compressor |
US6312233B1 (en) * | 1999-02-26 | 2001-11-06 | Lg Electronics Inc. | Rotary compressor |
US20040001762A1 (en) * | 2002-06-05 | 2004-01-01 | Sanyo Electric Co., Ltd. | Internal intermediate pressure multistage compression type rotary compressor, manufacturing method thereof and displacement ratio setting method |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20130156617A1 (en) * | 2010-06-15 | 2013-06-20 | Valeo Japan Co., Ltd. | Short-Shaft Electric Compressor |
CN104989644A (en) * | 2015-07-03 | 2015-10-21 | 广东美芝制冷设备有限公司 | Compressor |
Also Published As
Publication number | Publication date |
---|---|
JP2005264780A (en) | 2005-09-29 |
KR20060043674A (en) | 2006-05-15 |
EP1580433A3 (en) | 2006-07-19 |
MXPA05002924A (en) | 2005-09-21 |
TWI340794B (en) | 2011-04-21 |
KR101136678B1 (en) | 2012-04-18 |
TW200532114A (en) | 2005-10-01 |
EP1580433A2 (en) | 2005-09-28 |
CN1670375A (en) | 2005-09-21 |
BRPI0501167A (en) | 2005-11-01 |
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Legal Events
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AS | Assignment |
Owner name: SANYO ELECTRIC CO., LTD., JAPAN Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:SATO, KAZUYA;REEL/FRAME:016313/0825 Effective date: 20050322 |
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STCB | Information on status: application discontinuation |
Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION |