CN204877943U - Rotation -type compressor - Google Patents

Abstract

The utility model discloses a rotation -type compressor, include: cylinder, supplementary bearing and float subassembly. Be equipped with the compression chamber in the cylinder, be equipped with compression chamber sunction inlet on the internal perisporium in compression chamber. The supplementary bearing is established on the terminal surface of cylinder, is equipped with in supplementary bearing and/or the cylinder and compresses the spaced apart stock solution chamber in chamber, and the stock solution chamber has stock solution chamber sunction inlet, and the stock solution chamber is through compression chamber sunction inlet and compression chamber intercommunication. The float subassembly includes that elasticity leads oil and buoyant member, and buoyant member floats on the fluid of stock solution intracavity, and the one end that oil was led to elasticity is connected to buoyant member, elasticity lead oil construct along with buoyant member's fluctuation flexible inhale compression chamber sunction inlet with the refrigerant oil with the stock solution intracavity in. According to the utility model discloses a rotation -type compressor, can with refrigerant oil continuous inhale the compression intracavity, the oil return structure of the compressor in perfect built -in stock solution chamber has reduced the wearing and tearing of spare part, has improved the compressor reliability.

Description

Rotary compressor

Technical field

The utility model relates to compressor field, especially relates to a kind of rotary compressor.

Background technique

Liquid-storage container is the vitals of high back pressure rolling rotor type compressor, has impurity screening, stores unnecessary liquid refrigerants, separation gas liquid refrigerants occurs the functions such as hydraulic compression to prevent compressor.In recent years, air-conditioning system price reduces year by year, and the compressor cost as its core component also needs corresponding reduction.

Liquid-storage container is always the important consideration point that compressor reduces costs.Cost for liquid-storage container reduces, and mainly contains following method in technology disclosed in associated materials: one, liquid-storage container miniaturization; Two, liquid-storage container is cancelled (here, the cancellation not referred to truly cancelled by liquid-storage container, but the redundant space found on compressor replaces liquid-storage container); Three, the optimization of liquid-storage container material, manufacture, assembly technology aspect.

Conventional compressor is positioned at outside compressor body due to liquid-storage container, and the spill port height on the vertical sucking pipe of liquid-storage container is usually above cylinder suction port height, the refrigerator oil be namely stored in liquid-storage container is turned back in compressor body in time by the effect of cylinder inhalation power and gravity.But when compressor adopts the built-in structure of liquid storage cylinder, because the storage location of refrigerant and refrigerator oil mixing material is lower than cylinder cold media air suction port, gravity is to the event resolves of oil return, therefore refrigerator oil cannot rely on gravity to enter compression chamber.In addition, when not having mixed liquid to be full of in liquid storage space, the inlet port lower end on supplementary bearing and liquid levels depart from, and there will be the problem that compression chamber cannot aspirate refrigerator oil, and causing can not continuously oil suction.

Model utility content

The utility model is intended to solve the technical problem existed in prior art.For this reason, the utility model aims to provide a kind of rotary compressor of built-in liquid storage cylinder, to ensure that compression chamber is to refrigerator oil continuous sucking in liquid storage cylinder.

According to the rotary compressor of the utility model embodiment, comprising: cylinder, be provided with compression chamber in described cylinder, the inner circle wall of described compression chamber is provided with compression chamber suction port; Supplementary bearing, described supplementary bearing is located on the end face of described cylinder, be provided with liquid storage cylinder isolated with described compression chamber in described supplementary bearing and/or described cylinder, described liquid storage cylinder has liquid storage cylinder suction port, and described liquid storage cylinder is communicated with described compression chamber by described compression chamber suction port; Floater component, described floater component comprises elasticity oil-deflecting element and buoyant member, described buoyant member swims on the fluid in described liquid storage cylinder, one end of described elasticity oil-deflecting element is connected to described buoyant member, described elasticity oil-deflecting element be configured to described buoyant member fluctuate and flexible so that the refrigerator oil in described liquid storage cylinder is drawn onto in described compression chamber suction port.

According to the rotary compressor of the utility model embodiment, liquid storage cylinder is provided with in supplementary bearing and/or cylinder, by arranging floater component, floater component comprises the buoyant member of drifting along with liquid level height variation, comprise the telescopic elasticity oil-deflecting element be connected refrigerator oil to be sucked compression chamber with buoyant member simultaneously, thus refrigerator oil is drawn in compression chamber continuously, refrigerator oil can lubricate the component in compression chamber, the oil-returning structure of the compressor of perfect built-in liquid storage cylinder, reduce the wearing and tearing of component, improve compressor reliability.

In certain embodiments, the circulation passage that is radially spaced with described compression chamber is provided with in described cylinder to be configured to described liquid storage cylinder at least partially.

Particularly, described cylinder comprises: outer cylinder body, and described liquid storage cylinder suction port is located on the sidewall of described outer cylinder body; Inner cylinder body, described inner cylinder body is located at the inner side of described outer cylinder body, a described inner cylinder body part is circumferentially connected cylinder body with being provided with between described outer cylinder body, described inner cylinder body has through center hole to form described compression chamber, described outer cylinder body, limit described circulation passage between described inner cylinder body and described connection cylinder body, described compression chamber suction port is located on the sidewall of described inner cylinder body.

In certain embodiments, groove is provided with in described supplementary bearing to be configured to described liquid storage cylinder at least partially.

Particularly, described supplementary bearing comprises: the flange of annular, and described flange is located on the end face of described cylinder; Axle journal, described axle journal extends from the inner circumference edge edge of described flange towards the direction away from described cylinder; Peripheral board, described peripheral board extends from the outer periphery edge of described flange towards the direction away from described cylinder, and described peripheral board, described axle journal and described flange limit described groove; Described rotary compressor also comprises end plate, and described end plate buckle is combined on described peripheral board and described axle journal to close described groove.

In certain embodiments, the perisporium of described compression chamber suction port is provided with the first attachment hole, described supplementary bearing is provided with the second attachment hole being communicated with described first attachment hole and described liquid storage cylinder respectively, and the upper end of described elasticity oil-deflecting element is fixed in described second attachment hole or described first attachment hole.Wherein, because compression chamber suction port place air pressure is lower, therefore the first attachment hole and the second attachment hole are set, and the upper end of elasticity oil-deflecting element is fixed in above described holes, pressure reduction can produce the effect of suction to the fluid in elasticity oil-deflecting element, refrigerator oil is sucked in compression chamber with gaseous coolant automatically.

Particularly, described first attachment hole and/or described second attachment hole be configured to pore at least partially, the aperture of described pore is 0.1-2mm, and described pore is between described compression chamber suction port and the upper end of described elasticity oil-deflecting element.Thus, under the pumping action and capillarity of cylinder, the refrigerator oil entered in elasticity oil-deflecting element upwards can move, thus automatically enter into compression chamber.

In certain embodiments, described elasticity oil-deflecting element is spring.Thus, the telescopic direction of elasticity oil-deflecting element is fixed substantially, structural stability, and reliability is high.And spring cost is lower, elastic force is high, and structural strength is large, long service life.

Particularly, described floater component also comprises: sleeve pipe, to be enclosed within described spring and to connect described buoyant member outside described sleeve pipe.Thus, the refrigerator oil be drawn in spring can be made can not to leak away from the gap location between spring adjacent windings, thus improve the oil absorption of cylinder.

More specifically, the upper end of described spring is fixed on the end face of described cylinder, the end face of described cylinder is also provided with the receiving groove for holding described sleeve pipe.Thus receiving groove can play good leading role to moving up and down of sleeve pipe.

In certain embodiments, described buoyant member is annular, and the inner circle wall of described buoyant member is provided with the draw-in groove for fixing described spring.Thus, formation hole, the center portion of buoyant member sucks in elasticity oil-deflecting element from hole portion to facilitate cooling machine oil.Wherein, draw-in groove is set, the connection of buoyant member and elasticity oil-deflecting element can be facilitated, avoid buoyant member disengaging elasticity oil-deflecting element and oil suction was lost efficacy.

Advantageously, the upper and lower surface of described buoyant member is non-planar surface.Thus, the change rapid floating riser of buoyant member with fluid liquid level height can be realized.

Preferably, the surface of described buoyant member is provided with and hates oil based material layer.Thus, refrigerator oil can be avoided to be adsorbed on buoyant member surface and cannot compression chamber to be sucked.

Preferably, the internal diameter of described spring is 0.1-2mm.Thus, spring is equivalent to capillary tube, thus makes refrigerator oil automatically upwards suck compression chamber along spring.

Additional aspect of the present utility model and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by practice of the present utility model.

Accompanying drawing explanation

Above-mentioned and/or additional aspect of the present utility model and advantage will become obvious and easy understand from accompanying drawing below combining to the description of embodiment, wherein:

Fig. 1 is the structural representation of the rotary compressor according to the utility model embodiment;

Fig. 2 is the structural representation of cylinder according to the utility model embodiment and suction pipe;

Fig. 3 is the structural representation of cylinder, supplementary bearing and end plate according to the utility model embodiment;

In Fig. 4, Fig. 1 centre circle shows D portion enlarged view;

Fig. 5 is the structural representation of (during without fluid mixture) when sinking according to the buoyant member of the utility model embodiment;

Fig. 6 is the buoyant member embodiment illustrated in fig. 5 structural representation of (when fluid mixture is full of) when floating;

In Fig. 7, Fig. 5 centre circle shows E portion enlarged view;

Fig. 8 is the structural representation of (during without fluid mixture) when sinking according to the buoyant member of another embodiment of the utility model;

Fig. 9 is the buoyant member embodiment illustrated in fig. 8 structural representation of (when fluid mixture is full of) when floating;

Figure 10 is the structural representation of (during without fluid mixture) when sinking according to the buoyant member of another embodiment of the utility model;

Figure 11 is the structural representation of the buoyant member according to the utility model embodiment;

Figure 12 is the structural representation of the buoyant member according to another embodiment of the utility model.

Reference character:

100: rotary compressor;

1: exhaust manifolds; 2: upper shell; 3: middle shell; 4: stator; 5: rotor; 6: bent axle; 7: main bearing; 10: lower shell body; 11: piston; 12: slide plate; 15: end plate; 16: suction pipe;

A: shell; B: electric machine assembly; C: compression assembly; V: receiving cavity;

8: cylinder; P: compression chamber; A: compression chamber suction port; 81: outer cylinder body; 82: inner cylinder body; 820: center hole; 83: connect cylinder body; 84: the first attachment holes; 841: pore; 85: vane slot; 86: receiving groove;

9: supplementary bearing; 91: flange; 92: axle journal; 93: peripheral board; 94: the second attachment holes;

Q: liquid storage cylinder; B: liquid storage cylinder suction port; Q1: circulation passage; Q2: groove; Q3: through hole;

17: floater component; 171: elasticity oil-deflecting element; 172: buoyant member; 173: draw-in groove; 174: sleeve pipe; 1721: hole portion;

M: fluid mixture;

W: the A/F of draw-in groove; D: the wire diameter of spring; L: the free length of spring.

Embodiment

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Be exemplary below by the embodiment be described with reference to the drawings, be intended to for explaining the utility model, and can not be interpreted as restriction of the present utility model.

In description of the present utility model, it will be appreciated that, term " " center ", " length ", " highly ", " thickness ", " on ", D score, " vertically ", " level ", " top ", " end ", " interior ", " outward ", " axis ", " radial direction ", orientation or the position relationship of the instruction such as " circumference " are based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, instead of indicate or imply that the device of indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.

In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or imply the quantity indicating indicated technical characteristics.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise one or more these features.In description of the present utility model, except as otherwise noted, the implication of " multiple " is two or more.

In description of the present utility model, unless otherwise clearly defined and limited, term " installation ", " being connected ", " connection ", " fixing " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or integral; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals or the interaction relationship of two elements.For the ordinary skill in the art, concrete condition the concrete meaning of above-mentioned term in the utility model can be understood.

In the utility model, unless otherwise clearly defined and limited, fisrt feature second feature it " on " or D score can comprise the first and second features and directly contact, also can comprise the first and second features and not be directly contact but by the other characterisation contact between them.And, fisrt feature second feature " on ", " top " and " above " comprise fisrt feature directly over second feature and oblique upper, or only represent that fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " below " and " below " comprise fisrt feature immediately below second feature and tiltedly below, or only represent that fisrt feature level height is less than second feature.

Below with reference to Fig. 1-Figure 12, the rotary compressor 100 according to the utility model embodiment is described.

According to the rotary compressor 100 of the utility model embodiment, as shown in Figure 1, rotary compressor 100 comprises: shell A, electric machine assembly B and compression assembly C.Shell A is seal container, limits receiving cavity V in shell A.Electric machine assembly B and compression assembly C is all located in shell A, and namely electric machine assembly B and compression assembly C is all located in receiving cavity V.In the example illustrated in figure 1, shell A comprises middle shell 3, upper shell 2 and lower shell body 10, and middle shell 3 is formed as the tubular of upper and lower both ends open, and upper shell 2 and lower shell body 10 are located at the two ends up and down of middle shell 3 respectively.Rotary compressor 100 also comprises exhaust manifolds 1, and exhaust manifolds 1 to be located on shell A and to be communicated with receiving cavity V.

As shown in Figure 1, electric machine assembly B comprises stator 4 and coordinates the rotor 5 rotated with stator 4.In the example of Fig. 1, electric machine assembly B is positioned at the top of compression assembly C, and stator 4 is fixed on shell A, and rotor 5 is located in stator 4 rotationally, and namely electric machine assembly B is inner rotor motor.

As depicted in figs. 1 and 2, compression assembly C comprises bent axle 6, cylinder assembly, supplementary bearing 9, main bearing 7, piston 11 and slide plate 12 etc., and cylinder assembly can comprise one or more cylinder 8, is provided with compression chamber P in cylinder 8, when cylinder 8 is multiple, between adjacent two cylinders 8, be provided with dividing plate.Wherein, bent axle 6 runs through cylinder assembly and is enclosed within outside rotor 5 on bent axle 6, bent axle 6 be fixedly connected with rotor 5 with rotor 5 synchronous rotary.Main bearing 7 and supplementary bearing 9 are located at the two ends of cylinder assembly respectively, and main bearing 7 and/or supplementary bearing 9 are provided with the exhaust port (scheming not shown) being communicated with compression chamber P, and bent axle 6 coordinates to be located at rotationally in shell A with main bearing 7 and supplementary bearing 9 respectively.Be located in compression chamber P to piston 11 eccentric rotary, bent axle 6 is connected with piston 11 with driven plunger 11 eccentric rotary, and bent axle 6 drives piston 11 to rotate and compresses the refrigerant in compression chamber P.Cylinder interior space is divided into hyperbaric chamber and low-pressure cavity by slide plate 12, compression refrigerant in piston rotation process, and the pressure in hyperbaric chamber is raised, and when pressure is increased to the pressure outside slightly larger than compression assembly C, namely pressurized gas refrigerant discharges by exhaust port.

With reference to Fig. 1-Fig. 3, cylinder 8 is provided with compression chamber suction port a on the inner circle wall of compression chamber P, be provided with isolated liquid storage cylinder Q, liquid storage cylinder Q with compression chamber P in supplementary bearing 9 and/or cylinder 8 and have liquid storage cylinder suction port b, liquid storage cylinder Q is communicated with compression chamber P by compression chamber suction port a.

Here, liquid storage cylinder Q can be located in cylinder 8, and liquid storage cylinder Q also can be located on supplementary bearing 9, also can be equipped with liquid storage cylinder Q in supplementary bearing 9 and cylinder 8, not do concrete restriction here.

Particularly, as depicted in figs. 1 and 2, liquid storage cylinder suction port b is connected with suction pipe 16, and simultaneously suction pipe 16 stretches out shell A and is connected with the circulatory system refrigerant pipeline of rotary compressor 100 outside.Rotary compressor 100 flows in liquid storage cylinder Q (as shown in arrow d1 in Fig. 1,2) by the gas-liquid mixture that suction pipe 16 sucks, and in the gas-liquid mixture of suction, gaseous coolant flows into compression chamber P to be compressed into high pressure refrigerant (as shown in arrow d2, d3 in Fig. 1,2) by compression chamber suction port a.And gravitate impact, in the gas-liquid mixture of suction, liquid refrigerants and refrigerator oil landing converge in liquid storage cylinder Q.Certainly, the heat of vaporization that liquid refrigerants absorbs cylinder 8 in liquid storage cylinder Q is after gaseous state, and still can flow into compression chamber P to compress by compression chamber suction port a, the evaporation of liquid refrigerants simultaneously also can prevent cylinder 8 temperature too high.

Wherein, liquid storage cylinder Q has certain volume, a certain amount of liquid refrigerants can be held, thus effectively prevent hydraulic compression, can play the effect of air-breathing buffering, the noise that during reduction compressor air suction, air-breathing pulsation produces, and liquid storage cylinder Q also can be used as the liquid-storage container in traditional compressor simultaneously, namely the external liquid-storage container of traditional compressor can not be set according to the rotary compressor 100 of the utility model embodiment, and replace liquid-storage container by liquid storage cylinder Q and maintain the normal work of rotary compressor 100.

With reference to Fig. 1 and Fig. 3, Fig. 4, rotary compressor 100 also comprises floater component 17, floater component 17 comprises elasticity oil-deflecting element 171 and buoyant member 172, buoyant member 172 swims in the fluid mixture M in liquid storage cylinder Q, one end of elasticity oil-deflecting element 171 is connected to buoyant member 172, elasticity oil-deflecting element 171 be configured to buoyant member 172 fluctuate and flexible, so that the refrigerator oil in liquid storage cylinder Q is drawn onto in compression chamber suction port a.The refrigerator oil sucked flows into compression chamber P with gaseous coolant, lubricates movable members such as the piston 11 in compression chamber P, slide plate 12 and bent axles 6.That is, floater component 17 is equivalent to the return tube in traditional liquid-storage container.

Wherein, floater component 17 demand fulfillment condition: buoyancy >=G (elasticity oil-deflecting element 171+ the buoyant member 172)+F elasticity oil-deflecting element 171 suffered by floater component 17, wherein, G (elasticity oil-deflecting element 171+ buoyant member 172) represents the total force of elasticity oil-deflecting element 171 and buoyant member 172, and F elasticity oil-deflecting element 171 represents the elastic force of elasticity oil-deflecting element 171.That is, the buoyancy suffered by floater component 17 is more than or equal to the gravity of elasticity oil-deflecting element 171 and buoyant member 172 and the elastic force sum of elasticity oil-deflecting element 171, ensures that buoyant member 172 can be elevated with the change of the liquid level height of liquid storage cylinder Q inner fluid mixture M.

Wherein, in the utility model embodiment, the density of the liquid refrigerants that rotary compressor 100 adopts is greater than the density of refrigerator oil, and such as, refrigerant can be R410A.Like this, fluid mixture M is because of the different easily layering of density, and in the liquid of layering in liquid storage cylinder Q, upper strata is refrigerator oil, and lower floor is liquid refrigerants.Use buoyant member 172, buoyant member 172 can be risen and fallen up and down with the lifting of the fluid in liquid storage cylinder Q, ensures that buoyant member 172 contacts with the refrigerator oil in fluid mixture M all the time.And elasticity oil-deflecting element 171 due to have can with buoyant member 172 fluctuate and flexible, thus ensure that the refrigerator oil in liquid storage cylinder Q can suck in compression chamber suction port a with elasticity oil-deflecting element 171.

Simultaneously, when liquid storage cylinder Q inner fluid mixture liquid level height changes, buoyant member 172 contacts with the refrigerator oil in fluid mixture M all the time, therefore refrigerator oil can be drawn in compression chamber P by elasticity oil-deflecting element 171 continuously, ensure the continuity of compression chamber P absorption refrigerating machine oil, improve rotary compressor 100 reliability of operation, avoid refrigerator oil and accumulate in a large number in liquid storage cylinder Q, when especially compressor starts under the low ambient temperature of pole.

According to the rotary compressor 100 of the utility model embodiment, liquid storage cylinder Q is provided with in supplementary bearing 9 and/or cylinder 8, by arranging floater component 17, floater component 17 comprises the buoyant member 172 of drifting along with liquid level height variation, comprise the telescopic elasticity oil-deflecting element 171 be connected refrigerator oil to be sucked compression chamber P with buoyant member 172 simultaneously, thus refrigerator oil is drawn into continuously in compression chamber P, refrigerator oil can lubricate the component in compression chamber P, the oil-returning structure of the compressor of perfect built-in liquid storage cylinder Q, reduce the wearing and tearing of component, improve compressor reliability.

In certain embodiments, as shown in Figure 2, the circulation passage Q1 that is radially spaced with compression chamber P is provided with in cylinder 8 to be configured to liquid storage cylinder Q at least partially.

Wherein, circulation passage Q1 can be formed in the inside of cylinder 8, and circulation passage Q1 also can upwards or downwards open wide.When circulation passage Q1 is open upwards, main bearing 7 or dividing plate can close circulation passage Q1.When circulation passage Q1 opens wide downwards, supplementary bearing 9 can close circulation passage Q1.

In a specific embodiment, as shown in Figures 2 and 3, cylinder 8 comprises: outer cylinder body 81, inner cylinder body 82 be connected cylinder body 83.Inner cylinder body 82 is located at the inner side of outer cylinder body 81, and inner cylinder body 82 part is circumferentially connected cylinder body 83 with being provided with between outer cylinder body 81, outer cylinder body 81, inner cylinder body 82 and connect between cylinder body 83 and limit circulation passage Q1.In the embodiment shown in Fig. 3 and Fig. 1, circulation passage Q1 is through cylinder 8 in the vertical direction, and the upper end of circulation passage Q1 is closed by main bearing 7.

Wherein, as shown in Figures 2 and 3, inner cylinder body 82 has through center hole 820 to form compression chamber P, and compression chamber suction port a is located on the sidewall of inner cylinder body 82, and liquid storage cylinder suction port b is located on the sidewall of outer cylinder body 81.Alternatively, compression chamber suction port a is along the sidewall of the through inner cylinder body 82 of radial direction of cylinder 8, and liquid storage cylinder suction port b is along the sidewall of the through outer cylinder body 81 of radial direction of cylinder 8.Preferably, compression chamber suction port a is positioned at liquid storage cylinder suction port b the both sides being connected cylinder body 83 in the circumferential.Thus, gas-liquid mixture circulation path in liquid storage cylinder Q can be extended, improve gas-liquid separation effect.

Particularly, the axial cross section of outer cylinder body 81 can be circle, and namely outer cylinder body 81 is formed as circular cylinder body, and the axial cross section of inner cylinder body 82 also can be circle, and namely inner cylinder body 82 is also formed as circular cylinder body.Liquid storage cylinder Q is formed as the C shape chamber around inner cylinder body 82 circumference.

Conveniently cylinder body and inner cylinder body 82, outer cylinder body 81 and the production and processing being connected cylinder body 83, enhance productivity, and ensures the intensity of cylinder body, preferably, inner cylinder body 82, outer cylinder body 81 be connected cylinder body 83 and can be integrally formed.

As shown in Figure 2, connect on cylinder body 83 and be formed with vane slot 85, one end of vane slot 85 communicates with compression chamber P.Slide plate 12 is located in vane slot 85 diametrically slidably, and one end of slide plate 12 to extend in compression chamber P and is only against on piston 11.

In certain embodiments, as shown in Figure 3, groove Q2 is provided with in supplementary bearing 9 to be configured to liquid storage cylinder Q at least partially.Wherein, groove Q2 can be located on the end face of connection cylinder 8 of supplementary bearing 9, and groove Q2 also can be located on the end face away from cylinder 8 of supplementary bearing 9, does not do concrete restriction here.

In a specific embodiment, as shown in Figure 3, supplementary bearing 9 comprises: annular flange 91, axle journal 92 and peripheral board 93.With the compression chamber P on closed cylinder 8 on the end face that flange 91 is located at cylinder 8, axle journal 92 is from the inner circumference edge of flange 91 along extending towards the direction away from cylinder 8, and bent axle 6 is engaged in axle journal 92.Peripheral board 93 extends from the outer periphery edge of flange 91 towards the direction away from cylinder 8, peripheral board 93, axle journal 92 and flange 91 limit groove Q2, that is, the groove Q2 that opens wide towards the side away from cylinder 8 is provided with in supplementary bearing 9 to be configured to liquid storage cylinder Q at least partially.Rotary compressor 100 also comprises: end plate 15, and end plate 15 is fastened on peripheral board 93 and axle journal 92 with closed pockets Q2.Thus, greatly can increase the capacity of liquid storage cylinder Q, improve gas-liquid separation ability and the liquid storage capacity of liquid storage cylinder Q.

In the specific embodiment shown in Fig. 3, cylinder 8 is provided with the circulation passage Q1 of up/down perforation, supplementary bearing 9 is provided with the groove Q2 opened wide downwards, and the flange 91 of supplementary bearing 9 is also provided with the through hole Q3 of axially through flange 91, circulation passage Q1 is communicated with to form liquid storage cylinder Q with groove Q2 by through hole Q3.Wherein, the upper end of circulation passage Q1 is closed by main bearing 7, and the lower end of groove Q2 is closed by end plate 15.

In certain embodiments, as shown in Fig. 1, Fig. 4-Figure 10, elasticity oil-deflecting element 171 is spring, and thus, the telescopic direction of elasticity oil-deflecting element 171 is fixed substantially, structural stability, and reliability is high.And spring cost is lower, elastic force is high, and structural strength is large, long service life.

Preferably, spring is precision spring, in the example of fig. 1, and the preferred cylindrical spring of spring.

The scheme of the utility model embodiment also can be not limited thereto, and such as, elasticity oil-deflecting element 171 also can adopt crane structure, and this crane structure volume is little.

In certain embodiments, as shown in Figure 7, buoyant member 172 is annular, and the inner circle wall of buoyant member 172 is provided with the draw-in groove 173 for fixing spring.Like this, formation hole, the center portion of buoyant member 172 sucks in elasticity oil-deflecting element 171 from hole portion to facilitate cooling machine oil.Wherein, draw-in groove 173 is set, the connection of buoyant member 172 and elasticity oil-deflecting element 171 can be facilitated, avoid that buoyant member 172 departs from elasticity oil-deflecting element 171 and oil suction was lost efficacy.

Particularly, draw-in groove 173 is annular, and advantageously, the A/F W of draw-in groove 173 is less than the wire diameter d of spring.

Here, as shown in Figure 7, the upper and lower surface of buoyant member 172 can be plane, and thus, the structure of buoyant member 172 is simple, and processing cost is low.

Certainly, for ensureing when buoyant member 172 sinks to the bottom (time in such as liquid storage cylinder Q without fluid), buoyant member 172 can not be adsorbed on end plate 15, and therefore preferably the lower surface of buoyant member 172 is non-planar surface.

Again for ensureing when buoyant member 172 floats to peak (when such as liquid storage cylinder Q inner fluid is full of), buoyant member 172 can not be adsorbed on flange 91, and therefore preferably the upper surface of buoyant member 172 is non-planar surface.

For ensureing that buoyant member 172 both can not be adsorbed on end plate 15, also can not be adsorbed on flange 91, the upper and lower surface of preferred buoyant member 172 can be non-planar surface.

It should be noted that, when the lower surface of buoyant member 172 touches end plate 15, easily form oil film between lower surface and end plate 15, under capillary effect, buoyant member 172 is not easy to float.In addition, when operating mode switches, when having a large amount of liquid refrigerantss to pour in suddenly in liquid storage cylinder Q, fluid mixture M may cover the upper surface of buoyant member 172.Therefore in like manner, easily forming oil film between the upper surface of buoyant member 172 and flange 92 causes buoyant member 172 not easily to be landed.In order to realize floating rapidly of buoyant member 172, need the upper and lower surface of buoyant member 172 to be set to non-planar surface.

Wherein, it is multiple that the upper surface of buoyant member 172 and/or lower surface are that nonplanar structural type has, such as shown in figure 11, the lower surface of buoyant member 172 can be the conical surface or inclined-plane, again as shown in figure 12, the upper surface of buoyant member 172 and lower surface connect to form by multiple inclined-plane, and adjacent two inclined-planes have angle.

Certainly, the utility model is embodiment be not limited thereto, such as, the upper surface of buoyant member 172 and/or lower surface can be provided with shrinkage pool or convex closure, again such as, the upper surface of buoyant member 172 and/or lower surface can be round table surface or ladder surface, or, the upper surface of buoyant member 172 and/or lower surface are curved surface at least partially.

Preferably, compression chamber P can be inhaled in order to realize refrigerator oil, ensure being separated of this floatation element 17 and refrigerator oil, therefore needing to do certain chemical treatment to floatation element 17, hating oil-based ingredient etc. as added.Such as, can be provided with on the surface of buoyant member 172 and hate oil based material layer, like this, refrigerator oil can be avoided to be adsorbed on buoyant member 172 surface and compression chamber P cannot be sucked.

Referring to the different specific embodiments shown in Fig. 1, Fig. 4-Figure 10, describe the floater component 17 according to the utility model embodiment and corresponding mounting structure in detail.It should be noted that, in different embodiment, label identical from start to finish represents identical element or has the element of identical function.

Embodiment one

In this embodiment, as shown in Figure 1 and Figure 4, the perisporium of compression chamber suction port a is provided with the first attachment hole 84, and supplementary bearing 9 is provided with the second attachment hole 94 being communicated with the first attachment hole 84 and liquid storage cylinder Q respectively, and the upper end of elasticity oil-deflecting element 171 is fixed in the second attachment hole 94.

Here, because compression chamber suction port a place air pressure is lower, the active force of suction can be produced to the fluid in elasticity oil-deflecting element 171, therefore the upper end of elasticity oil-deflecting element 171 is located in the second attachment hole 94, fluid in elasticity oil-deflecting element 171 can be inhaled in the first attachment hole 84, and then refrigerator oil sucks in compression chamber P with gaseous coolant.

Wherein, the end face of supplementary bearing flange 91 is H1 to the distance of the diapire of liquid storage cylinder Q, and the axial height of the second attachment hole 94 is H2, and the free length L of spring is H1 and H2 sum.That is, when spring is in free state, the lower end of spring is extending on end plate 15, and like this, when liquid storage cylinder Q inner fluid is less, buoyant member 172 can be down to minimum point in liquid storage cylinder Q, to ensure constant absorption refrigerator oil as far as possible.

In addition, the axial height of long=the second attachment hole 94 of adherence of spring is H2, and here, the adherence length=d*n of spring, wherein d is spring wire diameter, and n is the number of coils, and namely the adherence of spring is long is length when spring compresses completely.That is, when being full of fluid in liquid storage cylinder Q2, spring can be fully retracted in the second attachment hole 94.

Particularly, the first attachment hole 84 and/or the second attachment hole 94 be configured to pore 841 at least partially, the aperture of pore 841 is 0.1-2mm, and pore 841 is between compression chamber suction port a and the upper end of elasticity oil-deflecting element 171.

It should be noted that, capillary energy makes the liquid of its tube wall wetting naturally rise.And less pore 841 part of the first attachment hole 84 mesoporous is equivalent to capillary tube, under the pumping action and capillarity of cylinder 8, the refrigerator oil entered in elasticity oil-deflecting element 171 can upwards move, thus automatically enters into compression chamber P.

In embodiment one, as shown in Figure 4, the flange 92 of the through in the axial direction supplementary bearing 9 of the second attachment hole 94, namely the axial length H2 of the second attachment hole 94 is the thickness of flange 92.And the first attachment hole 84 all forms pore 841.

In embodiment one, as shown in Figure 4, the internal diameter of spring is 0.1-2mm.Like this, spring is also equivalent to capillary tube, thus makes refrigerator oil automatically upwards suck compression chamber P along spring.

In addition, the diameter in the hole portion 1721 of the buoyant member 172 of annular is that 0.1-2mm is to form capillary tube.

Embodiment two

In this embodiment, as shown in Figure 5 and Figure 6, structure and the corresponding mounting structure of floater component 17 are substantially identical with embodiment one, repeat no more here.

Difference is, in embodiment two, the upper end of elasticity oil-deflecting element 171 is fixed in the first attachment hole 84.And in embodiment two, as shown in Figure 5, a part for the first attachment hole 84 is configured to pore 841.

In embodiment two, as shown in Figure 5 and Figure 6, when in liquid storage cylinder Q without liquid refrigerants and refrigerator oil time, spring is in nature elongation state, and buoyant member 172 sinks down into and contacts with liquid storage cylinder Q interior bottom wall.

When having liquid refrigerants and refrigerator oil to flow in liquid storage cylinder Q gradually, along with the change of liquid refrigerants height in liquid storage cylinder Q, floatation element 17 moves upward under the effect of buoyancy, and spring is compressed, and buoyant member 172 entirety moves up.When being full of by liquid refrigerants in liquid storage cylinder Q, amount of spring compression reaches maximum value, and the gravity of its downward elastic force and buoyant member 172, spring is less than or equal to the maximum buoyancy that liquid refrigerants produces, now spring is compressed in the first attachment hole 84 and the second attachment hole 94 completely.

Embodiment three

In this embodiment, as shown in Figure 8 and Figure 9, structure and the corresponding mounting structure of floater component 17 are substantially identical with embodiment one, repeat no more here.

Difference is, in embodiment two, in embodiment three, floater component 17 also comprises: sleeve pipe 174, to be enclosed within spring and to connect buoyant member 172 outside sleeve pipe 174.Thus, the refrigerator oil be drawn in spring can be made can not to leak away from the gap location between spring adjacent windings, thus improve the oil absorption of cylinder 8.

In embodiment three, as shown in Figure 8, when buoyant member 172 is positioned at the bottom of liquid storage cylinder Q (when sinking to the bottom), the upper end of sleeve pipe 174 is positioned at the second attachment hole 94, and the upper end of sleeve pipe 174 is concordant with the upper-end surface of flange 91.Certainly, when buoyant member 172 is positioned at the bottom of liquid storage cylinder Q, the upper end of sleeve pipe 174 also can lower than or higher than the upper-end surface of flange 91, or sleeve pipe 174 is positioned at the below of flange 91, is not construed as limiting here.

In embodiment three, as shown in Figure 8 and Figure 9, the upper end of spring is fixed on the end face of cylinder 8, the end face of cylinder 8 is also provided with the receiving groove 86 for holding sleeve pipe 174, thus receiving groove 86 can play good leading role to moving up and down of sleeve pipe 94.

In embodiment three, as shown in Figure 8 and Figure 9, buoyant member 172 is subject to the effect meeting Compress Spring of buoyancy, and spring contraction drives sleeve pipe 174 to move upward.When spring compresses completely, sleeve 174 is received in the second attachment hole 94 and receiving groove 86 completely.When the liquid level in liquid storage cylinder Q reduces, buoyancy reduces to cause spring elongates, and now buoyant member 172 moves down, and sleeve pipe 174 skids off in receiving groove 86, and moves downward.

In the above-described embodiments, spring can be equal pitch spring, and namely the distance of spring when free length between adjacent windings is equal.Here, pitch=(L-d)/(n-1) of spring, wherein, L is the free length of spring, and d is spring wire diameter, and n is the number of coils.

In order to ensure that the refrigerator oil be drawn in spring can not fall from the clearance leakage between spring adjacent windings, cause the oil absorption reducing cylinder 8, floatation element 17 spring used is variable-pitch spring, and as shown in Figure 10, namely the distance of spring when free length between adjacent windings is not exclusively equal.

Preferably, as shown in Figure 10, the pitch of the part of the contiguous upper end of spring is greater than the pitch of the part of contiguous lower end.

Further preferably, spring, under natural elongation state, is positioned at the pitch of pitch much larger than the part be positioned at below the second attachment hole 94 of the second attachment hole 94 scope.

Still more preferably, the pitch of the part be positioned at below the second attachment hole 94 of spring equals the wire diameter d of spring, that is, and the part be positioned at below the second attachment hole 94 of spring, gapless between adjacent windings, the part be positioned at below the second attachment hole 94 of spring is equivalent to pipe fitting.

According to the rotary compressor 100 of the utility model embodiment, by arranging floater component 17 in built-in liquid storage cylinder Q, liquid storage cylinder Q has the function of traditional external liquid-storage container storing liquid cooling liquid, make compressor without the need to arranging external liquid-storage container, improve the loop structure of cooling machine oil simultaneously, and simple and reasonable for structure.

In the description of this specification, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, identical embodiment or example are not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.

Although illustrate and described embodiment of the present utility model, those having ordinary skill in the art will appreciate that: can carry out multiple change, amendment, replacement and modification to these embodiments when not departing from principle of the present utility model and aim, scope of the present utility model is by claim and equivalents thereof.

Claims (14)

1. a rotary compressor, is characterized in that, comprising:

Cylinder, is provided with compression chamber in described cylinder, and the inner circle wall of described compression chamber is provided with compression chamber suction port;

Supplementary bearing, described supplementary bearing is located on the end face of described cylinder, be provided with liquid storage cylinder isolated with described compression chamber in described supplementary bearing and/or described cylinder, described liquid storage cylinder has liquid storage cylinder suction port, and described liquid storage cylinder is communicated with described compression chamber by described compression chamber suction port;

Floater component, described floater component comprises elasticity oil-deflecting element and buoyant member, described buoyant member swims on the fluid in described liquid storage cylinder, one end of described elasticity oil-deflecting element is connected to described buoyant member, described elasticity oil-deflecting element be configured to described buoyant member fluctuate and flexible so that the refrigerator oil in described liquid storage cylinder is drawn onto in described compression chamber suction port.

2. rotary compressor according to claim 1, is characterized in that, is provided with the circulation passage that is radially spaced with described compression chamber to be configured to described liquid storage cylinder at least partially in described cylinder.

3. rotary compressor according to claim 2, is characterized in that, described cylinder comprises:

Outer cylinder body, described liquid storage cylinder suction port is located on the sidewall of described outer cylinder body;

Inner cylinder body, described inner cylinder body is located at the inner side of described outer cylinder body, a described inner cylinder body part is circumferentially connected cylinder body with being provided with between described outer cylinder body, described inner cylinder body has through center hole to form described compression chamber, described outer cylinder body, limit described circulation passage between described inner cylinder body and described connection cylinder body, described compression chamber suction port is located on the sidewall of described inner cylinder body.

4. the rotary compressor according to any one of claim 1-3, is characterized in that, is provided with groove to be configured to described liquid storage cylinder at least partially in described supplementary bearing.

5. rotary compressor according to claim 4, is characterized in that,

Described supplementary bearing comprises:

The flange of annular, described flange is located on the end face of described cylinder;

Axle journal, described axle journal extends from the inner circumference edge edge of described flange towards the direction away from described cylinder;

Peripheral board, described peripheral board extends from the outer periphery edge of described flange towards the direction away from described cylinder, and described peripheral board, described axle journal and described flange limit described groove;

Described rotary compressor also comprises: end plate, and described end plate buckle is combined on described peripheral board and described axle journal to close described groove.

6. rotary compressor according to claim 1, it is characterized in that, the perisporium of described compression chamber suction port is provided with the first attachment hole, described supplementary bearing is provided with the second attachment hole being communicated with described first attachment hole and described liquid storage cylinder respectively, and the upper end of described elasticity oil-deflecting element is fixed in described second attachment hole or described first attachment hole.

7. rotary compressor according to claim 6, it is characterized in that, described first attachment hole and/or described second attachment hole be configured to pore at least partially, the aperture of described pore is 0.1-2mm, and described pore is between described compression chamber suction port and the upper end of described elasticity oil-deflecting element.

8. rotary compressor according to claim 6, is characterized in that, described elasticity oil-deflecting element is spring.

9. rotary compressor according to claim 8, is characterized in that, described floater component also comprises: sleeve pipe, to be enclosed within described spring and to connect described buoyant member outside described sleeve pipe.

10. rotary compressor according to claim 9, is characterized in that, the upper end of described spring is fixed on the end face of described cylinder, the end face of described cylinder is also provided with the receiving groove for holding described sleeve pipe.

11. rotary compressors according to claim 8, is characterized in that, described buoyant member is annular, and the inner circle wall of described buoyant member is provided with the draw-in groove for fixing described spring.

12. rotary compressors according to claim 1, is characterized in that, the upper and lower surface of described buoyant member is non-planar surface.

13. rotary compressors according to claim 1, is characterized in that, the surface of described buoyant member is provided with hates oil based material layer.

14. rotary compressors according to claim 8, is characterized in that, the internal diameter of described spring is 0.1-2mm.