CN1482364A

CN1482364A - Compressor

Info

Publication number: CN1482364A
Application number: CNA031385389A
Authority: CN
Inventors: 久保田淳; 夫; 关上和夫; 中村启夫
Original assignee: Hitachi Appliances Inc
Current assignee: Hitachi Johnson Controls Air Conditioning Inc
Priority date: 2002-09-11
Filing date: 2003-06-03
Publication date: 2004-03-17
Anticipated expiration: 2023-06-03
Also published as: JP2004100608A; CN1278042C; JP4045154B2

Abstract

A rotary two-stage compressor comprises: a motor having a rotary shaft; and a rotary compression element where a compression element for low pressure, a middle partition board, and a compression element for high pressure are laminated in lamination successively from the motor side for integration in a closed container, thus performing the eccentric rotation of the compression element for low pressure and the compression element for high pressure for drive by two eccentricity sections being provided at the rotary shaft. The compressor also has a through hole for passing the rotary shaft to the intermediate partition board and the through hole is set to be nearly in a truncated cone shape. To improve the degree of design freedom in an intermediate shaft by reducing the refrigerant leakage loss and mechanical loss of a two-stage compressor.

Description

Compressor

Technical field

The present invention relates to employed rotary compound compressors such as a kind of air conditioner or refrigerating machine, relate in particular to and a kind ofly rotate that axial design freedom is high, high efficiency rotary compound compressor.

Background technique

Figure 14 has shown a kind of structure of existing rotary compound compressor.This compressor 101 in the seal container of being made up of bottom 21, casing 22 and loam cake 12 13, has the motor of being made up of stator 7 and rotor 8 14.Bent axle with the running shaft 2 that is connected with motor 14 is propped up in main bearing 9 and supplementary bearing 19 by axle.Relative rotation axi 2 forms integrated with compressing member 23 is overlapping for stratiform with compressing member 20, intermediate clapboard 15 and high pressure low pressure from motor 14 sides successively.

This rotary compound compressor is used on the compressing member 23 with compressing member 20 and high pressure in low pressure, and 2 the

eccentric part

5a, 5b driving rolls (roller) 11a, the 11b that are located on the bent axle 2 carry out eccentric rotary.On bent axle, has the jack shaft 4 that interconnects eccentric part.Low pressure is with compressing member 20, have be arranged on the cylinder 10a, by the compression volume that eccentric part 5a and roller 11a compress, this compression volume is sealed by the end plate and the intermediate clapboard 15 of a part that constitutes main bearing 9.In addition, high pressure is with compressing member 23, has to be arranged on the compression volume that cylinder 10b goes up, compressed by eccentric part 5b and roller 11b, and this compression volume is sealed by intermediate clapboard 15 and the end plate that constitutes the part of supplementary bearing 19.

The refrigeration agent of low pressure, be inhaled into low pressure with in the compressing member 20 from sucking pipe 25a, and carry out eccentric rotary, and be compressed to intermediate pressure by roller 11a with eccentric part 5a tabling, pass exhaust port 26a and plate 18 and main bearing 9 formed spaces again, discharge from discharge tube 27a.

Secondly, the refrigeration agent of intermediate pressure, be inhaled into high pressure with in the compressing member 23 from intakeport 25b, and carry out eccentric rotary by roller 11b and be compressed to high pressure with eccentric part 5b tabling, pass again by exhaust port 26b, plate 18 and supplementary bearing 19 formed spaces, inner flow passage 30 and confined space 29, discharge from discharge tube 27b.

Bent axle shown in Figure 15 is provided with successively: with the external running shaft 2 of rotor 8, drive low pressure with the eccentric part 5a of compressing member 20, driving high pressure with the eccentric part 5b of compressing member 23 be in front end axle 3 with the front end of the eccentric part 5b of running shaft 2 opposite sides.Further, be provided with the jack shaft 4 that interconnects each

eccentric part

5a, 5b.

At this, the diameter of axle d1 of running shaft 2 is identical with the diameter of axle d2 of front end axle 3.The eccentric amount e 1 of eccentric part 5a is bigger than the eccentric amount e 2 of eccentric part 5b.This be because: because the low pressure density of comparing refrigeration agent with compressing member 23 with compressing member 20 and high pressure is low, so be necessary to increase discharge capacity Vcc.Discharge capacity Vcc and eccentric amount e with the inside diameter D of cylinder 10, height H, and the outside diameter d r of roller 11, have the relation shown in following formula (1), (2).Wherein, δ is small distance.

Vcc = \frac{Π}{4} (D^{2} - {dr}^{2}) \cdot H \cdot \cdot \cdot \cdot \cdot \cdot (1)

e = \frac{D}{2} - \frac{dr}{2} + δ &GreaterEqual; \frac{D}{2} - \frac{dr}{2} \cdot \cdot \cdot \cdot \cdot \cdot \cdot (2)

As shown in figure 14, if the height H of the inside diameter D of cylinder 10a and cylinder 10b then will reduce dr1 in order to increase low pressure with the Vcc of compressing member 20 respectively about equally, it is big that eccentric amount e 1 also becomes thereupon.Eccentric part 5a also has identical outside diameter d c with eccentric part 5b.

Play a part to separate low pressure compressing member 20 and the high pressure intermediate clapboard 15 of compressing member 23, through hole 16 with the inside diameter D 0 that is communicated with front end axle 3 usefulness such as grade.Figure 16 represent will be from main bearing 9 to intermediate clapboard 15 the schematic representation of each component-assembled on bent axle.As shown in figure 16, relative to main bearing 9 cylinder 10a is moved along the arrow A direction and to assemble, roller 11a is moved along the arrow B direction assemble again, running shaft 2 is moved along the arrow C direction assemble.Intermediate clapboard 15 along arrow D, at first makes eccentric part 5b by behind the through hole 16 from the direction of front end axle 3, more as shown in figure 14, assembles with the axle core and a corresponding to substantially state of core of running shaft 2 of through hole 16.

As existing compressor, in order to improve overall adiabatic efficiency and reliability, increase and only the diameter of axle of jack shaft is tried one's best, suppress its resiliently deformable.(for example, with reference to patent documentation 1.) according to the patent documentation shown in Figure 17 1 described technology in the A-A cross section of the appended Figure 15 of expression the present invention, in order to suppress performance degradation by the resiliently deformable generation of jack shaft 4, and, make it to be slightly plurality of stepped serrations shape in the mode of the sectional area that increases jack shaft 4.

[patent documentation 1]

The spy opens 2001-140783 communique (the 3rd page, Fig. 4, Fig. 6)

Because the restriction in the assembling, eccentric part 5b must pass through through hole 16, so can not at random set the sectional area of jack shaft.Thereby, as shown in figure 17, must form slightly ellipticity, have and process the complicated problems that becomes.In addition, as shown in figure 18, when the cross section of jack shaft 4 is circular, because the restriction of assembled shape, so have the problem that can not increase the diameter of axle.That is,, and has the few problem of design freedom of the shape of jack shaft 4 because of the restriction in the assembling.

As mentioned above, bigger in order to make eccentric amount e 1 than eccentric amount e 2, as shown in figure 14, make low pressure littler than high pressure with the minimum seal length L2 of compressing member 23 with the minimum seal length L1 of compressing member 20.Owing to have pressure difference in the seal container and in the compressing member, so produce decreased performance because of freezing medium leakage.Again because minimum seal length is little and pressure difference is big, so will become a reason that further causes decreased performance with the leakage loss at compressing member 20 places in low pressure.That is what, prevent the performance degradation that produced by freezing medium leakage with compressing member 20 places in low pressure is the problem that will solve.

Summary of the invention

The object of the invention is to realize a kind of design freedom that increases jack shaft, and prevents the rotary compound compressor of performance degradation.

Another purpose of the present invention is to realize a kind of air conditioner that improves minimizing to the COP (coefficient of refrigeration) of compressor input.

In order to realize purpose of the present invention, be arranged on the intermediate clapboard between 2 compressing members of rotary compound compressor, have and run through the through hole that bent axle is used, and this through hole is formed slightly round table-like.

In addition, bent axle has eccentric part with 2 corresponding positions of compressing member.Produce resiliently deformable in order to be suppressed on the jack shaft of being located at the bent axle between these eccentric parts, preferably make as interconnect bent axle eccentric part part jack shaft the diameter of axle, liken to into the diameter of axle with the front end axle rightabout front end of motor bent axle big.

And then preferably, the scope of the cone angle of above-mentioned through hole sectional shape is 10 degree≤α≤30 degree.

In order to realize another object of the present invention, in with the air conditioner of rotary compound compressor as a composed component of refrigerant cycle, be arranged on the intermediate clapboard between 2 compressing members of rotary compound compressor, have and pass the through hole that bent axle is used, and this through hole be slightly round table-like.

Description of drawings

Fig. 1 is the longitudinal section of the compressor of the embodiment of the invention.

Fig. 2 is the longitudinal section of the intermediate clapboard of one embodiment of the invention.

Fig. 3 is the plan view of the bent axle of the embodiment of the invention.

Fig. 4 is the A-A sectional view of Fig. 3.

Fig. 5 be the expression present embodiment compressor the 1st the step sequence partial enlarged drawing.

Fig. 6 be the expression present embodiment compressor the 2nd the step sequence partial enlarged drawing.

Fig. 7 be the expression present embodiment compressor the 3rd the step sequence partial enlarged drawing.

Fig. 8 is the schematic representation that concerns of the cone angle of expression present embodiment compressor and overall adiabatic efficiency.

Fig. 9 is the partial enlarged drawing of the compressor of application examples 1 of the present invention.

Figure 10 is the longitudinal section of the intermediate clapboard of application examples 2 of the present invention.

Figure 11 is the loop structure figure of the air conditioner of present embodiment.

Figure 12 is the loop structure figure of existing air conditioner.

Figure 13 is the mollier diagram of the air conditioner of present embodiment.

Figure 14 is the longitudinal section of existing compressor.

Figure 15 is the plan view of the bent axle of existing compressor.

Figure 16 is the part ssembly drawing of existing compressor.

Figure 17 is the A-A sectional view of Figure 15 of existing compressor.

Figure 18 is the A-A sectional view of Figure 15 of the application examples of existing compressor.

Among the figure: 1-compressor, 2-running shaft, 3-front end axle, the 4-jack shaft, 5-eccentric part, 9-main bearing, the 10-cylinder, 11-roller, 14-motor, the 15-intermediate clapboard, 16-through hole, the 17-conical surface, 20-low pressure compressing member, 23-high pressure compressing member, 25-sucking pipe, the 26-exhaust port, the 27-discharge tube.

Embodiment

Below, with reference to accompanying drawing embodiments of the invention are described.Wherein, for Figure 14 in the identical employed symbol of composed component, in order to understand embodiments of the invention easily, and in Fig. 1, also use identical symbol.

In Fig. 1, high pressure is with the outside diameter d c2 of the eccentric part 5b of compressing member 23, sets for a short time than low pressure with the outside diameter d c1 of the eccentric part 5a of compressing member 20.But, eccentric amount e 1, e2, cylinder bore D, height H and roller outside diameter d r, promptly discharge capacity Vcc is with existing identical.

Fig. 2 is the sectional shape of expression intermediate clapboard 15.Intermediate clapboard 15 has front end axle 3, eccentric part 5b and runs through the through hole 16 of jack shaft 4 usefulness.The low pressure of through hole 16 is with the aperture D1 of compressing member 20 sides, and is littler with the aperture D2 of compressing member 23 sides than high pressure, and be formed truncated conical shape.In the present embodiment, the conical surface 17 of through hole 16 is 15 degree with the formed cone angle in axle center.

Fig. 3 is the plan view that is applicable to the bent axle of present embodiment, and Fig. 4 is the A-A sectional view of Fig. 3.The outside diameter d c2 of the eccentric part 5b of front end axle 3 sides that intermediate clapboard 15 passes through is littler than the outside diameter d c1 of eccentric part 5a.The cross section of jack shaft 4 is cylindric, and its outside diameter d 3 is bigger than the diameter of axle d2 of front end axle 3.In the present embodiment, because set identically with the diameter of axle d1 of running shaft 2 diameter of axle d2, so outside diameter d 3 maximums of jack shaft 4.According to present embodiment, the cross section of jack shaft 4 can be configured to circle, processability is good.In addition because compared with running shaft 2 that is connected with rotor 8 and axle the front end axle 3 on supplementary bearing 19, can increase the diameter of axle of jack shaft 4, so, also can reduce the amount of deformation of jack shaft 4 even the power that is applied on each compressing member is excessive.

Secondly, with reference to Fig. 5 to Fig. 7, the sequence of the compressor 1 of present embodiment is described.The sequence of main bearing 9, roller 11a, cylinder 10a and running shaft 2 is with existing identical.At first, along arrow B 1 direction,, move to dotted line position by front end axle 3, eccentric part 5b with the little aperture D1 side of intermediate clapboard 15 from through hole 16.Secondly, be fulcrum with stagger the mutually some a of end difference of jack shaft 4 and eccentric part 5b, intermediate clapboard 15 is rotated along arrow B 2 directions.(Fig. 5)

Then, with intermediate clapboard 15 along the direction of arrow B 3 from the dotted line to the solid line, be moved horizontally to and make the conical surface 17 contact with fulcrum b (Fig. 6).

Further, be fulcrum with a b, the direction of intermediate clapboard 15 along arrow B 4 is rotated, and jack shaft 4 is passed through aperture D1, make intermediate clapboard 15 move to position shown in Figure 1 (Fig. 7).

Roller 11b, cylinder 10b and supplementary bearing 19 move to bearing 9 from the direction of front end axle 3, assemble as Fig. 1.

In addition, cylinder 10, intermediate clapboard 15 and supplementary bearing 19 pass through along the bolt of the length direction of running shaft 2 on length direction, and are fixed on the main bearing 9.

Wherein, the little aperture D1 of through hole 16 as long as satisfy dc2≤D1, can reduce significantly than the aperture D0 of existing through hole 16.Thereby, as shown in Figure 1, can increase the minimum seal length L1 of low pressure with compressing member 20, reduce the leakage loss of refrigeration agent.And on the other hand, owing to can shorten the minimum seal length 12 of high pressure with compressing member 23, so can reduce unnecessary frictional loss.That is,, can improve the efficient of compressor 1 by the intermediate clapboard 15 of present embodiment.

Further, by the intermediate clapboard 15 of present embodiment,, can enlarge the scope of design of diameter of axle d3 again, so can improve design freedom owing to can keep the cross section of jack shaft 4 is configured to the good cylinder of processability.

Further, because the shape of jack shaft 4 is cylinders, so compare easy processing with existing embodiment shown in Figure 17.Based on present embodiment,, in one procedure, jack shaft is processed by grinding machine.

Thereby as shown in Figure 4, the cross section of jack shaft 4 more than or equal to eccentric part 5a and eccentric part zone that 5b comprises jointly, is compared with existing compressor, and the flexural rigidity of jack shaft uprises.Thereby can suppress the freezing medium leakage that produces by the resiliently deformable at jack shaft 4 places and the increase of mechanical loss, improve performance.

Further cone angle is described below.If the effect of the little then present embodiment of cone angle is little, if the big then high pressure of cone angle uses the leakage of compressing member to increase.The relation of having represented the overall adiabatic efficiency of cone angle and compressor among Fig. 8.Wherein, overall adiabatic efficiency defines with (compression work of compressor)/(the input electric weight of compressor).As shown in Figure 8, exist the α that makes overall adiabatic efficiency become maximum, its scope is 10 degree≤α≤30 degree.Thereby,, then can further improve the efficient of the compressor 1 that is suitable for the embodiment of the invention if in this scope, set cone angle.

Fig. 9 has represented another embodiment of the present invention.In this embodiment, on the through hole 16 of intermediate clapboard 15, be provided with parallel portion 18.Curved surface 6 further is set on jack shaft 4.At this moment, owing to can increase allowable tolerance, and the warpage of the intermediate clapboard 15 on little aperture D1 is little, so have the advantage that improves reliability.Parallel portion 18 preferably is located at relative position with curved surface 6.

Figure 10 represents another embodiment of the present invention.Among the embodiment in front, the through hole 16 of intermediate clapboard 15 is configured to has holes parallel portion, that diameter is different.In this embodiment, parallel portion becomes little aperture D1, does not become the inclined-plane from big aperture D2 to parallel portion, and the internal diameter of through hole 16 is formed stairstepping.This shape has been paid attention to the easiness of assembling and the processability of intermediate clapboard 15 forms.

Secondly, with reference to Figure 11 the example that compressor of the present invention is used on the air conditioner is described.On the formation in circulation, at first be communicated with compressor 1 that drives refrigeration agent and the four-way valve 28 that in heater unit running and air-cooling system operation process, switches the refrigerant cycle direction with refrigerant piping 36.Outdoor heat converter 31 is set on the outdoor unit, and outdoor air and refrigeration agent are carried out heat exchange.Indoor heat converter 34 is set on the indoor set, and indoor air and refrigeration agent are carried out heat exchange.The gas-liquid separator 33 that the decompressor 32 that refrigeration agent is reduced pressure is provided with to the liquid state of refrigeration agent is separated with gaseous state is clipped in the middle, and refrigeration agent is back to compressor 1 through suppressing liquid refrigerant inhalant jar 35.And structure separately is communicated with refrigeration pipe arrangement 36 successively.

Below, at the air-cooling system operation process, that is, the action along the air conditioner under the arrow A direction circulating refrigerant situation shown in Figure 11 is described.The gaseous refrigerant (some C ') of the high pressure P d that discharges from compressor 1 heats outdoor air on one side at outdoor heat converter 31 on one side and carries out condensing (putting D).Condensing refrigeration agent carries out adiabatic expansion to intermediate pressure Pm (some E) in decompressor 32, be separated into gaseous state and liquid state (some E ') again in gas-liquid separator 33, and gaseous state is fed to and injects runner 37.Liquid state further is depressurized to low pressure Ps in the decompressor (reduction valve) 32 in gas-liquid separator 33 downstreams after (some F '), carry out carburation by evaporation (some G) on one side Yi Bian in indoor heat converter 34, indoor air is cooled off.

The low pressure Ps refrigeration agent of vaporization by jar 35 back, be inhaled into low pressure with in the compressing member 20 from sucking pipe 25a, carries out off-centre rotation by the roller 11a with eccentric part 5a tabling and is compressed to intermediate pressure Pm, discharges (putting H1 ') from discharge tube 27a again.After this, mix mutually with the gaseous refrigerant of the intermediate pressure Pm that derives from injection runner 37 (some H2 '), and in intakeport 25b is inhaled into high pressure usefulness compressing member 23, the off-centre rotation of being undertaken by the roller 11b with eccentric part 5b tabling is compressed to high pressure, discharges (some C ') from discharge tube 27b again.In addition, in compressing member, separated by panel 38.When heater unit turns round, refrigeration agent by four-way valve 28 along circulating in the route shown in the arrow B of dotted line.

Figure 12 is the structural drawing of existing refrigerant cycle.Compressor 101 shown in the dotted line is represented inapplicable compound compressor of the present invention.Existing circulation is compared with the present invention, because of compressor difference do action point difference.Particularly, low pressure is different with discharge point (put C and put C ') with the suction point (put H2 and put H2 ') of compressing member 23 with high pressure with the discharge point (put H1 and put H1 ') of compressing member 20.

Figure 13 is the mollier diagram of the working state of expression freeze cycle.The circulation of existing air conditioner is dotted, air conditioner of the present invention is represented with solid line.Point C, the C ' etc. of Figure 13, corresponding with Figure 11, state point shown in Figure 12.

Below, when being turned round, air-cooling system describes.Inject the circuit air conditioner at Figure 11, gas shown in Figure 12, only liquid by gas-liquid separator 33 by outdoor heat converter 34 (some F ' is to putting G) as vaporizer, and gaseous refrigerant flows down along injecting runner 37.

The gaseous refrigerant of existing air conditioner is compressed to a some H1 with compressing member 20 from a G by low pressure.Afterwards, mix mutually with gaseous refrigerant, and be cooled to a H2 along the temperature of injecting the some E that runner 37 flows down.Further,, be compressed to a C from a H2 and discharged with compressing member 23 by high pressure.Compressor 101 has increased the leakage loss of refrigeration agent as described in Figure 14 like that, that is, low pressure is big with the input W2 of the input W1 of compressing member 20 and high compression element 23.

In the cyclic process of present embodiment, owing to use compressor 1 of the present invention, can reduce the leakage loss of refrigeration agent, respectively W1, W2 are reduced to W1 ', W2 ' significantly.Particularly, in low pressure with in the compressing member because in the seal container with compressing member in refrigerant pressure poor (Pd-Ps) big, so the minimizing effect of the leakage loss that is produced by the present invention, promptly (W1-W1 ') is big.

Thereby if compare with identical air-cooling system ability, the air conditioner of present embodiment and existing comparing can reduce the input of compressor, and improve the COP (coefficient of refrigeration) of air conditioner significantly.Even compare, because the effect that the input of compressor reduces is big, so can improve COP (coefficient of refrigeration) significantly with identical heater unit ability.

(invention effect)

According to the present invention, in compressor, leakage loss and the machinery that can simultaneously improve cold-producing medium decrease Lose, one side suppresses the performance degradation by the strain generation of jackshaft, raises the efficiency and reliability. In addition, in air-conditioner, can improve significantly COP (coefficient of refrigerating performance).

Claims

1. rotary compound compressor, it is characterized in that: in seal container, comprising: have running shaft motor and from described motor side successively with low pressure with compressing member, intermediate clapboard, and high pressure be the incorporate rotation compressing member of stratiform with compressing member is overlapping;

Drive described low pressure and carry out the off-centre rotation with compressing member and described high pressure with compressing member by being located at 2 eccentric parts on the described running shaft, have the through hole that passes described running shaft on described intermediate clapboard, described through hole is truncated conical shape slightly.

2. rotary compound compressor as claimed in claim 1, it is characterized in that: described running shaft, front end in the direction opposite with described motor has the front end axle, has jack shaft interconnecting on the part of described eccentric part, and the diameter of axle of described jack shaft is bigger than the diameter of axle of described front end axle.

3. rotary compound compressor as claimed in claim 1 is characterized in that: the scope of the cone angle of described through hole is 10 degree≤α≤30 degree.

4. rotary compound compressor, it is characterized in that, comprising: seal container, be arranged in the seal container and the rotation of the motor that can match with running shaft drivingly, the eccentric part by described running shaft and driven a plurality of rotation compressing member and be arranged between the described rotation compressing member and have and make that described running shaft passes, cross section be the dividing plate of the through hole of truncated conical shape slightly with a plurality of eccentric parts.

5. rotary compound compressor as claimed in claim 4, it is characterized in that: described running shaft, front end in the direction opposite with described motor has the front end axle, has jack shaft interconnecting on the part of described eccentric part, and the diameter of axle of described jack shaft is bigger than the diameter of axle of described front end axle.

6. rotary compound compressor as claimed in claim 4 is characterized in that: the side that the through hole radius of described dividing plate is little, in the face of the low pressure compressing member.

7. rotary compound compressor as claimed in claim 4 is characterized in that: described rotation compressing member, form with compressing member with compressing member and high pressure by low pressure.

8. rotary compound compressor as claimed in claim 4 is characterized in that: the scope of the cone angle of described through hole is 10 degree≤α≤30 degree.

9. air conditioner has:

The valve that flow direction from the compressed refrigeration agent of compressor is switched,

Certainly the refrigeration agent that this valve is flowed out carry out heat exchange heat exchanger,

The decompressor that the pressure that has carried out the refrigeration agent of heat exchange through this heat exchanger is reduced pressure,

The gas-liquid separator that gaseous refrigerant in the refrigeration agent that has carried out decompression through this decompressor is separated with liquid refrigerant,

To carry out heat exchange through the liquid refrigerant that this gas-liquid separator has carried out separating and become another heat exchanger of the gaseous refrigerant of the low pressure of compressing with described compressor, it is characterized in that,

Described compressor has: seal container,

The motor that is arranged in the seal container and can cooperates with the running shaft with a plurality of eccentric parts drivingly,

The rotation of the eccentric part by described running shaft and driven a plurality of rotation compressing member and

Be arranged on the described rotation compressing member of forming with compressing member with compressing member and high pressure by low pressure and have pass described running shaft, the cross section is the dividing plate of the through hole of truncated conical shape slightly.

10. air conditioner as claimed in claim 9 is characterized in that: will through the gaseous refrigerant of described gas-liquid separator separates and through described low pressure with the compressing member refrigerant compressed, compress with compressing member with described high pressure.

11. air conditioner as claimed in claim 9, it is characterized in that: the running shaft of described compressor, front end in the direction opposite with described motor has the front end axle, has jack shaft interconnecting on the part of described eccentric part, and the diameter of axle of described jack shaft is bigger than the diameter of axle of described front end axle.

12. an air conditioner has:

The gas-liquid separator that gaseous refrigerant in the refrigerator that has carried out decompression through this decompressor is separated with liquid refrigerant,

Described compressor has: seal container,

Be arranged in the seal container, and the motor that can cooperate with running shaft drivingly with a plurality of eccentric parts,

Be arranged between the described rotation compressing member and have make described running shaft run through, the cross section is the dividing plate of the through hole of truncated conical shape slightly.

13. air conditioner as claimed in claim 12, it is characterized in that: described running shaft, front end in the direction opposite with described motor has the front end axle, has jack shaft interconnecting on the part of described eccentric part, and the diameter of axle of described jack shaft is bigger than the diameter of axle of described front end axle.

14. air conditioner as claimed in claim 12, it is characterized in that: the running shaft of described compressor, front end in the direction opposite with described motor has the front end axle, has jack shaft interconnecting on the part of described eccentric part, and the diameter of axle of described jack shaft is bigger than the diameter of axle of described front end axle.

15. air conditioner as claimed in claim 12 is characterized in that: the side that the through hole radius on the dividing plate of described compressor is little, in the face of the low pressure compressing member.