CN214170818U - Scroll compressor, refrigeration equipment and vehicle - Google Patents

Scroll compressor, refrigeration equipment and vehicle Download PDF

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Publication number
CN214170818U
CN214170818U CN202022230769.6U CN202022230769U CN214170818U CN 214170818 U CN214170818 U CN 214170818U CN 202022230769 U CN202022230769 U CN 202022230769U CN 214170818 U CN214170818 U CN 214170818U
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China
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oil
outlet
scroll compressor
refrigerant
channel
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CN202022230769.6U
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江国彪
杨开成
吴嘉晖
杨江林
钟升
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Guangdong Welling Auto Parts Co Ltd
Anhui Welling Auto Parts Co Ltd
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Guangdong Welling Auto Parts Co Ltd
Anhui Welling Auto Parts Co Ltd
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Abstract

The utility model belongs to the technical field of refrigeration plant, concretely relates to scroll compressor, refrigeration plant and vehicle. The scroll compressor comprises a shell, an oil separation structure, an oil storage pool and an oil outlet channel are arranged in the shell, the oil outlet channel is provided with an oil inlet and an oil outlet, the oil outlet is located above the oil inlet, the oil inlet is communicated with an oil discharge hole of the oil separation structure, and the oil outlet is communicated with the oil storage pool. Through setting up oil drain hole and the oil storage pool that the oil channel connects the oil content structure of producing oil, the oil channel guide of producing oil flows into the oil storage pool from oil drain hole exhaust frozen oil, the frozen oil flows through flow velocity and pressure reduction behind the oil channel, the frozen oil of following oil-out exhaust reduces the impact of having frozen oil in to the oil storage pool, it has frozen oil to remain stable in the oil storage pool, the oil gallery of oil storage pool is by the frozen oil submergence all the time, thereby avoid the refrigerant to reveal to scroll compressor's oil return passage in through the oil gallery, ensure that scroll compressor oil return is sufficient, the friction pair obtains effective lubrication, scroll compressor compression efficiency promotes.

Description

Scroll compressor, refrigeration equipment and vehicle
Technical Field
The utility model relates to a refrigeration plant technical field, concretely relates to scroll compressor, refrigeration plant and vehicle.
Background
The statements herein merely provide background information related to the present disclosure and may not necessarily constitute prior art.
The scroll compressor is a positive displacement compressor with high efficiency, low noise and smooth operation, and is widely used in an automotive air conditioning system as a third-generation vehicle-mounted compressor. During the use process of the scroll compressor, the refrigerant oil is required to be provided to lubricate a friction pair in the scroll compressor so as to reduce noise generated when the friction pair works. In the prior art, as shown in fig. 1, an oil separation structure 100 is provided in a scroll compressor to separate a mixed fluid of a refrigerant and oil discharged from a compression chamber 30 of the scroll compressor, an oil storage tank 12 is provided below the oil separation structure 100 to store the frozen oil separated by the oil separation structure 100; meanwhile, a throttling oil return structure 40 is arranged between the oil storage pool 12 and the oil return channel 20 of the scroll compressor, and an oil return hole 121 formed in the pool bottom of the oil storage pool 12 is connected with the throttling oil return structure 40, so that the refrigeration oil in the oil storage pool 12 finally returns to the oil return channel 20 of the scroll compressor through the throttling oil return structure 40, and each friction pair in the scroll compressor is lubricated.
However, in the actual use process, since the oil discharge hole 1017 of the oil content structure 100 is disposed right opposite to the oil storage pool 12, the fluid discharged from the oil content structure 100 can wash the refrigerant oil in the oil storage pool 12, the refrigerant oil in the oil storage pool 12 overturns due to impact, so that the through hole connecting the oil storage pool 12 and the throttling oil return structure 40 cannot be completely immersed by the refrigerant oil, the refrigerant directly leaks from the throttling oil return structure 40 to the air suction side of the scroll compressor, and the refrigerant leaks to further reduce the refrigerating capacity of the scroll compressor. In addition, the refrigerant occupies a fluid conveying space of the throttling oil return structure 40 when leaking through the throttling oil return structure 40, the amount of the refrigeration oil conveyed to the oil return channel 20 through the throttling oil return structure 40 is reduced, the refrigerant is mixed and dissolved in the refrigeration oil again due to the fact that the refrigeration oil is overturned, the proportion of the refrigeration oil in the oil storage pool 12 is reduced, the proportion of the refrigeration oil in the oil return is further reduced, the friction pair cannot be effectively lubricated, the power consumption of the scroll compressor is increased, the compression efficiency is reduced, and even functional faults can occur in severe cases.
SUMMERY OF THE UTILITY MODEL
An object of the embodiment of the utility model is to provide a scroll compressor, refrigeration plant and vehicle, the vice lubrication of friction that aims at solving the scroll compressor among the prior art is not enough, leads to the technical problem that scroll compressor consumption increase, compression efficiency reduce.
In order to solve the above technical problem, an embodiment of the present invention adopts a technical solution that:
the utility model provides a scroll compressor, includes the casing, is provided with oil content structure and oil storage pool in the casing, still is provided with the passageway of producing oil in the casing, and the passageway of producing oil has oil inlet and oil-out, and the oil-out is located the top of oil inlet, and the oil inlet is linked together with the oil extraction hole of oil content structure, and the oil-out is linked together with the oil storage pool.
In some embodiments, the casing is provided with a refrigerant outlet, and the wall of the oil storage tank is provided with an exhaust hole communicated with the refrigerant outlet.
In some embodiments, the flow area of the oil outlet channel gradually increases along the direction from the oil inlet to the oil outlet.
In some embodiments, the oil outlet passage is a curved passage having at least one curved section.
In some embodiments, a plurality of ribs are spaced on the wall of the oil storage pool, one end of each rib faces the top of the oil storage pool, and the other opposite end of each rib faces the bottom of the oil storage pool.
In some embodiments, the oil outlet is disposed opposite the floor of the oil reservoir.
In some embodiments, the oil outlet is disposed toward the bottom of the oil storage tank, and a buffer portion is disposed on a wall of the oil storage tank, the buffer portion being located below the oil outlet and having a gap with the wall of the oil storage tank.
In some embodiments, the oil outlet channel is an oil outlet pipe, the oil outlet pipe includes an inlet section and a discharge section connected to the inlet section, a port of the inlet section remote from the discharge section forms an oil inlet, and a port of the discharge section remote from the inlet section forms an oil outlet.
In some embodiments, the scroll compressor further comprises a fixed scroll, a first communicating groove and a second communicating groove are formed in the side wall of the fixed scroll facing the oil separating structure, the oil discharging hole is connected with the oil inlet through the first communicating groove, and the air discharging hole is connected with the refrigerant outlet through the second communicating groove.
In some embodiments, the scroll compressor further comprises a sealing element, the sealing element is connected to an end face of the fixed scroll facing the oil separation structure in an abutting mode, a groove with two open ends is formed in the end face of the fixed scroll facing the oil separation structure, the groove and the sealing element are arranged in an enclosing mode to form an oil outlet channel, and the two open ends of the groove form an oil outlet and an oil inlet respectively.
In some embodiments, the scroll compressor further comprises a sealing element, the sealing element is attached to the end face, facing the oil content structure, of the fixed scroll in an abutting manner, a groove with two open ends is arranged on the end face, facing away from the oil content structure, of the sealing element, the groove and the end face of the fixed scroll are defined in an enclosing manner to form an oil outlet channel, and the two open ends of the groove respectively form an oil outlet and an oil inlet.
In some embodiments, the casing includes an oil content housing, the oil content housing has a connection surface adapted to be connected with an end surface of the fixed scroll facing the oil content structure, a groove with two open ends is disposed on the connection surface, the end surface of the fixed scroll abuts against the connection surface and encloses with the groove to form an oil outlet channel, and the two open ends of the groove respectively form an oil inlet and an oil outlet.
In some embodiments, a containing groove for containing the groove is further formed in the oil separation housing, and an oil storage pool is formed by the inner wall surface of the containing groove and the outer wall surface of the groove in an enclosing manner.
In some embodiments, a connecting channel for the separated refrigerant to flow through is further arranged in the oil separation housing, an inlet and an outlet of the connecting channel are respectively connected with the oil outlet and the exhaust hole, and a channel wall of the connecting channel is connected with the pool wall of the oil storage pool.
In some embodiments, an oil blocking portion is arranged on the channel wall of the connecting channel, and a gap is formed between the oil blocking portion and the end face of the oil outlet.
In some embodiments, the oil separation structure includes an oil separation cavity disposed in the oil separation housing, and the oil discharge hole and the refrigerant outlet are disposed on a cavity wall of the oil separation cavity; an oil inlet is further formed in the wall of the oil separation cavity, a mixed fluid outlet is formed in the static vortex disc, and the oil inlet is connected with the mixed fluid outlet.
The utility model provides an above-mentioned one or more technical scheme of scroll compressor has one of following technological effect at least: the utility model provides a scroll compressor is through setting up the oil outlet passageway in that the casing is inside to make the oil inlet of oil outlet passageway be linked together with the oil drain hole of oil content structure, make the oil-out of oil outlet passageway be linked together with the oil storage tank, like this, in the oil inlet got into the oil outlet passageway earlier from oil content structure exhaust refrigeration oil, again via the oil-out of oil outlet passageway flows into to the oil storage tank in. Because the oil outlet of the oil outlet channel is arranged above the oil inlet, the frozen oil entering the oil outlet channel flows along the direction opposite to the gravity direction and is discharged through the oil outlet, thus the outflow pressure and the outflow speed of the frozen oil can be effectively reduced, thus, the flow speed and pressure of the frozen oil discharged from the oil outlet are reduced, the impact force on the frozen oil existing in the oil storage pool when the frozen oil is discharged is reduced, thereby ensuring that the refrigeration oil in the oil storage pool keeps stable, ensuring that the refrigeration oil in the oil storage pool does not tumble due to oil entering, increasing the effective oil storage volume and the oil storage capacity of the oil storage pool, meanwhile, the refrigeration oil in the oil storage tank is kept stable, the oil return hole can be ensured to be immersed by the refrigeration oil all the time, the refrigerant is prevented from leaking into the oil return channel through the oil return hole, the oil return of the scroll compressor is sufficient, the friction pair of the scroll compressor is ensured to be effectively lubricated, and the compression efficiency of the scroll compressor is improved.
The embodiment of the utility model provides an another technical scheme who adopts is:
a refrigeration device comprises the scroll compressor.
The utility model provides a refrigeration plant, through using foretell scroll compressor, because be provided with out oil passage in scroll compressor's the casing, it is popular to go out oil passage guide refrigeration oil against the direction of gravity, thereby can reduce the play flow speed and the pressure of effluenting when refrigeration oil discharges into to the oil storage pool, reduce the impact force that has refrigeration oil in the oil storage pool when refrigeration oil discharges, ensure that refrigeration oil keeps stable in the oil storage pool, the effective oil storage volume of oil storage pool increases, and the oil gallery of refrigeration oil submergence oil storage pool all the time, avoid the refrigerant directly to reveal to scroll compressor in the oil return passageway through the oil gallery, the scroll compressor oil return is sufficient, scroll compressor's compression efficiency improves, refrigeration plant's refrigerating capacity optimization.
The embodiment of the utility model provides an another technical scheme who adopts is:
a vehicle comprises the refrigeration equipment.
The utility model provides a vehicle, through using foretell refrigeration plant, in vehicle refrigeration process, because refrigeration plant's refrigerating output and refrigeration efficiency can maintain higher level all the time to can effectively shorten the inside cooling of vehicle consuming time, the cooling speed of vehicle promotes, and the promotion is experienced with the car.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.
FIG. 1 is a cross-sectional view of a prior art scroll compressor;
fig. 2 is a cross-sectional view of a scroll compressor according to an embodiment of the present invention;
FIG. 3 is a partial cross-sectional view of the scroll compressor shown in FIG. 2;
FIG. 4 is a partial cross-sectional view of a scroll compressor according to another embodiment of the present invention;
FIG. 5 is a schematic view of the seal of the scroll compressor shown in FIG. 4 assembled with the fixed scroll of the scroll compressor;
FIG. 6 is a schematic view of the seal shown in FIG. 4;
fig. 7 is a schematic structural view of a fixed scroll in the structure shown in fig. 4;
FIG. 8 is a schematic diagram showing the relationship between the amount of blow-by gas and the amount of S3/S2;
FIG. 9 is a schematic graph showing the relationship between S4/S3 and the outlet flow rate of the refrigerant oil exiting the oil outlet;
FIG. 10 is a schematic diagram of the relationship between S5/S2 and the pressure difference DeltaP between the oil outlet and the oil inlet of the oil outlet channel.
Wherein, in the figures, the respective reference numerals:
10-a housing; 100-oil content structure; 101-oil containment; 1011-connecting face; 1012-a receiving groove; 1013-connecting channels; 1014-oil blocking part; 1015-oil retaining surface; 1016-oil separation chamber; 1017-oil drain hole; 1018-rectification chamber; 1019-oil inlet; 1020-a mixed fluid inlet; 1021-streamlined wall surface; 11-oil cannula; 111-an air inlet end; 112-air outlet end; 12-an oil reservoir; 121-oil return hole; 122-vent hole; 123-ribs; 13-an oil outlet channel; 131-an oil inlet; 132-an oil outlet; 133-an introduction section; 134-a discharge section; 14-refrigerant outlet; 15-static vortex disc; 151-a first connecting groove; 152-a second communication channel; 153-mixed fluid outlet; 16-a seal; 161-avoidance of vacancy; 17-a groove; 18-an orbiting scroll; 20-an oil return passage; 30-a compression chamber; 40-throttling oil return structure; 50-air entry; 60-an air suction cavity; 70-a compression mechanism; 80-a drive mechanism.
Detailed Description
In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention more clearly understood, the following description is made in conjunction with fig. 1-10 and the embodiments, and the present invention is further described in detail. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
It should be noted that, in the description of the present invention, when an element is referred to as being "fixed" or "disposed" to another element, it may be directly on the other element or be indirectly connected to the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.
It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the invention.
Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.
Reference throughout the specification to "one embodiment," "some embodiments," or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in one or more embodiments of the invention. Thus, appearances of the phrases "in one embodiment," "in some embodiments," "in other embodiments," or the like, in various places throughout this specification are not necessarily all referring to the same embodiment, but rather "one or more but not all embodiments" unless specifically stated otherwise. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
As shown in fig. 2 to 7, an embodiment of the present invention provides a scroll compressor, as shown in fig. 2, the scroll compressor may include, but is not limited to: a casing 10, a suction port 50, a compression mechanism 70, a driving mechanism 80, a refrigerant outlet 14, and the like.
The compression mechanism 70 may include, but is not limited to, an orbiting scroll 18, a fixed scroll 15, and an anti-rotation structure, wherein the fixed scroll 15 may include an end plate and a fixed wrap, and the orbiting scroll 18 may include an end plate and an orbiting wrap, and the fixed wrap and the orbiting wrap are engaged with each other, thereby defining a compression chamber 30 of the scroll compressor (i.e., a working chamber of the scroll compressor) between the fixed scroll and the orbiting scroll. The rotation preventing means serves to limit rotation of the orbiting scroll 18 while allowing the orbiting scroll 18 to perform a revolving translational motion with respect to the fixed scroll 15. The driving mechanism 80 may include, but is not limited to, a motor composed of a stator and a rotor, and a crankshaft, wherein the crankshaft may be integrally rotatable with the rotor, and the crankshaft may be provided at an upper end with an eccentric pin adapted to drive the orbiting scroll 18, and the rotor drives the orbiting scroll 18 to rotate by the eccentric pin. The suction port 50 is opened on the casing 10 and connected to a refrigerant supply port of an external working circuit (for example, an outlet of a system evaporator, etc.), a suction chamber 60 is further provided in the casing 10, the suction chamber 60 communicates with the suction port 50 and the compression chamber 30, and a low-pressure refrigerant (working fluid) from the external working circuit (for example, the system evaporator, etc.) of the casing 10 is sucked through the suction port 50 and enters the compression mechanism 70 through the suction chamber 60 to be compressed. An oil separation structure 100 and an oil storage tank 12 are disposed in the casing 10, a mixed fluid of refrigerant and refrigerant oil discharged from the compression chamber 30 is output to the oil separation structure 100 for oil-gas separation, a refrigerant outlet 14 is opened in the casing 10, a high-pressure refrigerant separated by the oil separation structure 100 is discharged to an external working circuit (such as an inlet of a system evaporator) of the scroll compressor through the refrigerant outlet 14, and the refrigerant oil separated by the oil separation structure 100 is discharged from an oil discharge hole 1017 and flows into the oil storage tank 12 to be stored therein. An oil storage area is formed in the oil storage pool 12, wherein the oil storage area refers to an area where the refrigerant oil is actually stored in the oil storage pool 12 when the scroll compressor of this embodiment is used, an oil return hole 121 for discharging the refrigerant oil is formed in a pool wall of the oil storage pool 12, the oil return hole 121 is located in the oil outlet area, specifically, the oil return hole 121 may be, but is not limited to, being disposed at a pool bottom of the oil storage pool 12, an oil return channel 20 is further formed in the casing 10, the oil return channel 20 is communicated with the oil return hole 121, a throttling oil return structure 40 is disposed between the oil return channel 20 and the oil storage pool 12, and the refrigerant oil in the oil storage pool 12 flows through the throttling oil return structure 40 and is conveyed into the oil return channel 20 to lubricate each friction pair of the scroll compressor.
When the scroll compressor works, under the condition that the motor is electrified, the rotor rotates to drive the crankshaft to synchronously rotate, the crankshaft drives the movable scroll 18 to perform rotary translational motion through the eccentric pin, meanwhile, a refrigerant, namely a working fluid enters the air suction cavity 60 of the compression mechanism 70 through the air suction port 50, the refrigerant is further sucked into the compression cavity 30 from the air suction cavity 60 along with the continuous rotary translational motion of the movable scroll 18, and at the moment, the refrigerant entering the compression cavity 30 is compressed and the pressure is increased. When the refrigerant is compressed to reach a predetermined compression ratio, the refrigerant is discharged from the compression cavity 30, for example, a mixed fluid outlet 153 is formed in the fixed scroll 15, the refrigerant is discharged through the mixed fluid outlet 153, and during the compression of the refrigerant, the refrigerant oil lubricating the friction pair is carried by the refrigerant and enters the compression cavity 30. Therefore, the fluid discharged from the mixed fluid outlet 153 of the fixed scroll 15 is a mixed fluid of the refrigerant and the refrigeration oil, and needs to be processed after being discharged to separate the refrigerant and the refrigeration oil, so that the mixed fluid of the refrigerant and the refrigeration oil is conveyed to the oil separating structure 100 to separate the refrigerant and the refrigeration oil, the separated refrigerant is discharged from the scroll compressor from the refrigerant outlet 14, the separated refrigeration oil enters the oil storage tank 12, further flows into the throttling oil return structure 40 through the oil return hole 121, and enters the oil return channel 20 to lubricate the friction pair, thereby realizing the recycling of the refrigeration oil.
In an embodiment of the present invention, as shown in fig. 2, 3 and 4, an oil outlet channel 13 is further disposed in the casing 10 of the scroll compressor, and the oil outlet channel 13 is used for guiding the refrigeration oil discharged from the oil discharge hole 1017 of the oil separation structure 100 to enter the oil storage tank 12. Specifically, the oil outlet channel 13 has an oil inlet 131 and an oil outlet 132 which are oppositely arranged, and the oil outlet 132 is located above the oil inlet 131, specifically, in this embodiment, the oil outlet 132 is located above the oil inlet 131, which means that the oil outlet 132 is located directly above or obliquely above the oil inlet 131 in the gravity direction, and after the frozen oil flows into the oil outlet channel 13 from the oil inlet 131, the frozen oil needs to flow to be discharged from the oil outlet 132 against the flow direction of the gravity direction. The oil inlet 131 is communicated with the oil drainage hole 1017 of the oil content structure 100, the oil inlet 131 is used for allowing the frozen oil discharged from the oil drainage hole 1017 of the oil content structure 100 to flow in, the oil outlet 132 is communicated with the oil storage pool 12, and the oil outlet 132 is used for guiding the frozen oil into the oil storage pool 12.
Further, in the present embodiment, the oil outlet 132 is located above the oil storage area of the oil storage pool 12, so that the oil outlet 132 is located above the oil storage area, and it is ensured that the oil outlet 132 is always located above the liquid level of the refrigeration oil in the oil storage pool 12, so that the refrigeration oil does not flood the oil outlet 132 all the time along with the increase of the storage amount of the refrigeration oil in the oil storage pool 12, thereby preventing the oil outlet 132 from extending into the refrigeration oil to discharge the refrigeration oil, and preventing the refrigeration oil from generating bubbles when discharging to cause the refrigeration oil to tumble, or preventing the bubbles from entering the throttling oil return structure 40 through the oil return hole 121, and occupying the internal space of the throttling oil return structure 40.
The embodiment of the utility model provides a scroll compressor, through setting up oil channel 13 in casing 10's inside, and make oil inlet 131 of oil channel 13 and scroll compressor's oil content structure 100's oil drain 1017 intercommunication, oil outlet 132 of oil channel 13 and scroll compressor's oil storage pool 12 intercommunication, like this, the refrigerated oil who discharges from oil drain 1017 of oil content structure 100 gets into in oil channel 13 through oil inlet 131 earlier, flow into to oil storage pool 12 through oil outlet 132 of oil channel 13 again, in this embodiment, the flow path of refrigerated oil is as shown by the dotted arrow in fig. 2, fig. 3 and fig. 4. Because the oil outlet 132 of the oil outlet channel 13 is arranged above the oil inlet 131 along the gravity direction, the refrigerant oil entering the oil outlet channel 13 flows along the direction opposite to the gravity direction, so that the pressure of the refrigerant oil can be effectively reduced, the outflow speed of the refrigerant oil is reduced, the flow speed and the pressure of the refrigerant oil discharged from the oil outlet 132 are reduced, the impact force of the refrigerant oil on the existing refrigerant oil in the oil storage pool 12 is reduced when the refrigerant oil is discharged, the refrigerant oil in the oil storage pool 12 can be ensured to be stable, the refrigerant oil in the oil storage pool 12 is ensured not to be overturned due to the oil entering, the effective oil storage volume and the oil storage amount of the oil storage pool 12 are also increased, meanwhile, the refrigerant oil in the oil storage pool 12 is kept stable, the oil return hole 121 can be ensured to be always immersed by the refrigerant oil, the refrigerant is prevented from directly leaking into the oil return channel 20 through the oil return hole 121, the oil return of the scroll compressor is ensured to be sufficient, and the friction pair of the scroll compressor is effectively lubricated, thereby improving the compression efficiency of the scroll compressor.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, a refrigerant outlet 14 is provided on the casing 10, the refrigerant separated by the oil separation structure 100 is discharged through the refrigerant outlet 14, further, since the refrigerant flows through the oil channel 13 and the flow rate and pressure thereof are reduced, and therefore, a portion of the refrigerant dissolved in the refrigerant is separated out, and therefore, an exhaust hole 122 for discharging the separated refrigerant is provided on the wall of the oil storage tank 12, the exhaust hole 122 is communicated with the refrigerant outlet 14 on the casing 10, the refrigerant separated out from the refrigerant and entering the oil storage tank 12 is collected into the refrigerant outlet 14 through the exhaust hole 122 and discharged from the refrigerant outlet 14, in this embodiment, the flow path of the refrigerant is shown by solid arrows in fig. 2, fig. 3 and fig. 4. In the embodiment, when the refrigerant oil flows through the oil outlet channel 13, the refrigerant dissolved in the refrigerant oil is separated out due to the pressure reduction of the refrigerant oil, and the separated refrigerant is discharged through the exhaust hole 122, so as to avoid the refrigerant from staying in the oil storage tank 12 to increase the internal pressure of the oil storage tank 12 until the separated refrigerant is dissolved in the refrigerant oil again; more importantly, the vent hole 122 is arranged to discharge the refrigerant, so that the pressure Pk ' at the oil inlet 131 of the oil outlet channel 13 is always greater than the pressure Pd ' at the oil outlet 132, that is, a pressure difference (Pk-Pd ' >0) is formed between the oil outlet 132 and the oil inlet 131 of the oil outlet channel 13, and under the action of the pressure difference, the refrigerant oil is ensured to be discharged from the oil outlet 132 of the oil outlet channel 13, so that even if the refrigerant oil flows along the direction opposite to the gravity direction, the refrigerant oil can still smoothly flow out of the oil outlet 132, and the condition of flow breaking or backflow is avoided.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, the exhaust hole 122 and the oil return hole 121 are disposed at an interval from top to bottom along the gravity direction, the oil outlet channel 13 is disposed between the exhaust hole 122 and the oil return hole 121, the oil inlet 131 is disposed near the oil return hole 121, the oil outlet 132 is disposed near the exhaust hole 122, that is, the oil inlet 131 is located above the oil return hole 121, and the exhaust hole 122 is located above the oil outlet 132. Thus, the vent hole 122 is provided above the oil outlet 132, so that the refrigerant oil discharged from the oil outlet 132 is prevented from entering the vent hole 122 and being discharged along the refrigerant through the vent hole 122 when flowing along the wall of the oil reservoir 12.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, along the direction from the oil inlet 131 to the oil outlet 132 of the oil outlet channel 13, the flow area of the oil outlet channel 13 is gradually increased, that is, along the flow direction of the refrigeration oil, the flow area of the oil outlet channel 13 is gradually increased. In this way, in the process that the frozen oil flows along the oil outlet channel 13, along with the gradual increase of the flow area, the flow speed of the frozen oil is gradually reduced, and the speed of the frozen oil discharged from the oil outlet 132 is reduced, so that the impact on the liquid level when the frozen oil is discharged from the oil outlet 132 can be further reduced; furthermore, the refrigerant flow rate is reduced, and the amount of refrigerant precipitated during the flow of refrigerant can be further increased, thereby further reducing the amount of refrigerant dissolved in the refrigerant entering the oil reservoir 12 and increasing the ratio of refrigerant entering the oil return passage 20 of the scroll compressor.
Of course, in other embodiments, the flow area of the oil outlet channel 13 from the oil inlet 131 to the oil outlet 132 may also be constant, that is, the flow area of the oil outlet channel 13 is constant along the flow direction of the refrigerant oil, so that the flow rate of the refrigerant oil can also gradually decrease as the refrigerant oil flows through the oil outlet channel 13 due to the on-way resistance of the oil outlet channel 13.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, the oil outlet channel 13 is a curved channel having at least one curved section, the oil outlet channel 13 is set to be a curved channel having a curved section, the refrigerant oil flows into the oil outlet channel 13 at a high speed, and hits the channel wall when the curved section turns, the local resistance received by the refrigerant oil during the flowing process is increased, so as to further reduce the flow rate and pressure of the refrigerant oil. So, the setting has the area of the crooked section of the play oil passageway 13 of crooked section can enough rational utilization, makes the dwell time of refrigeration oil in the passageway 13 of producing oil increase, and more messenger's precipitation of the refrigerant in the refrigeration oil can increase the local resistance of passageway 13 of producing oil again, effectively reduces the velocity of flow and the pressure of refrigeration oil.
Further, in this embodiment, the oil outlet channel 13 is preferably an "L" shaped channel provided with a curved section, and the curved section of the "L" shaped channel is rounded to avoid the refrigerant oil from impacting the channel wall too much and wearing the channel. Of course, in other embodiments, the oil outlet channel 13 may also be an "S" shaped channel provided with a plurality of curved sections, or the like, or other channels with one or more curved sections, and the specific arrangement form of the oil outlet channel 13 is not limited herein.
In another embodiment of the present invention, as shown in fig. 2 and 3, a plurality of ribs 123 are disposed on the wall of the oil storage pool 12 at intervals, one end of each rib 123 faces the top of the oil storage pool 12, and the other end of each rib 123 faces the bottom of the oil storage pool 12, i.e. each of the plurality of ribs 123 extends from one end of the oil storage pool 12 to the other end along the gravity direction. The ribs 123 are arranged on the wall of the oil storage pool 12, on one hand, the ribs 123 can be used for guiding the frozen oil discharged from the oil outlet 132 to the oil storage pool 12, and further reducing the scouring of the oil discharged from the oil outlet 132 to the frozen oil in the oil storage pool 12, on the other hand, the ribs 123 can also be used for further absorbing the heat of the frozen oil, and further reducing the temperature of the frozen oil entering the oil storage pool 12, so that the precipitation amount of the refrigerant is increased.
Further, in the present embodiment, as shown in fig. 2 and 3, an end of the rib 123 facing away from the oil outlet 132 extends to the bottom of the oil storage tank 12, that is, when the frozen oil is stored in the oil storage tank 12, an end of the rib 123 facing away from the oil outlet 132 extends to a position below the liquid level of the frozen oil, so that the frozen oil sprayed from the oil outlet 132 is directly guided to join with the frozen oil in the oil storage tank 12, and the flushing of the frozen oil in the oil storage tank 12 by the frozen oil is reduced to the maximum extent.
Furthermore, in the present embodiment, the plurality of ribs 123 may be, but not limited to, integrally formed on the wall of the oil storage pool 12, so that the processing process is simple and the forming and manufacturing are convenient.
In another embodiment of the present invention, as shown in fig. 2 and 3, the oil outlet 132 is arranged at the bottom of the oil storage tank 12, that is, when the freezing oil is stored in the oil storage tank 12, the oil outlet 132 is arranged at the bottom of the freezing oil liquid level, so the setting of the oil outlet channel 13 can change the outflow direction of the freezing oil, the freezing oil discharged from the oil outlet 132 is not directly opposite to the freezing oil liquid level, so that the freezing oil liquid level can not be directly washed away, thereby further reducing the impact of the freezing oil discharged from the oil outlet 132 on the existing freezing oil in the oil storage tank 12, and better providing a guarantee for maintaining the stability of the existing freezing oil in the oil storage tank 12.
Further, in the present embodiment, the oil outlet 132 is located below the air outlet 122 along the gravity direction, so that the frozen oil discharged from the oil outlet 132 is prevented from entering the air outlet 122 and being discharged along the refrigerant through the air outlet 122 while flowing along the wall of the oil storage tank 12. Preferably, in this embodiment, a valve structure for stopping the outflow of the refrigerant oil may be further disposed in the air vent 122, so as to prevent the refrigerant oil from being sprayed to be discharged through the air vent 122 due to an excessive outflow speed.
Of course, in other embodiments, the venting hole 122 may be disposed below the oil outlet 132, and in this case, a valve for stopping the outflow of the refrigerant oil needs to be disposed in the venting hole 122 to prevent the refrigerant oil from flowing out through the venting hole 122.
Optionally, in another embodiment of the present invention, the oil outlet 132 may not be disposed away from the bottom of the oil storage pool 12, that is, the oil outlet 132 is disposed toward the bottom of the oil storage pool 12, at this time, a buffer portion (not shown) may be disposed between the oil storage area of the oil storage pool 12 and the oil outlet 132, that is, between the refrigerant oil level and the oil outlet 132, and it is ensured that a gap is formed between the buffer portion and the pool wall of the oil outlet pool 12 for the refrigerant oil to flow through. Thus, the frozen oil discharged from the oil outlet 132 hits the buffer portion and then falls into the oil reservoir 12, and the shock of the frozen oil can be further buffered by the buffer portion, so that even if the oil outlet 132 faces the frozen oil liquid surface, the influence of the shock on the existing frozen oil in the oil reservoir 12 is relatively small.
Further, in the present embodiment, the buffer portion is a buffer baffle protruding from the wall of the oil storage tank 12, and the side wall of the buffer baffle and the side wall of the oil storage tank 12 are spaced apart from each other to form a gap for the refrigerant oil to flow through. Or the buffer part is a pore plate which is convexly arranged on the wall of the oil storage pool 12, a plurality of through holes are arranged on the pore plate, and the refrigerant oil flows out through the through holes on the pore plate.
In another embodiment of the present invention, as shown in fig. 2, the oil outlet channel 13 is configured as an oil outlet pipe, the oil outlet pipe includes an introducing section 133 and a discharging section 134 connected to the introducing section 133, the port of the introducing section 133 far away from the discharging section 134 forms the oil inlet 131, and the port of the discharging section 134 far away from the introducing section 133 forms the oil outlet 132. Therefore, the oil outlet channel 13 adopts a pipeline type channel, and a proper pipeline is selected to be arranged in the shell 10 of the scroll compressor, so that the oil outlet channel 13 can be formed, and the oil outlet channel 13 has a relatively simple structure and is convenient to manufacture and form.
Further, in the present embodiment, the discharge section 134 is connected to the introduction section 133 at an angle, and forms a bent section of the oil outlet passage 13 at a position of the connection angle, and particularly, in the present embodiment, the connection angle between the introduction section 133 and the discharge section 134 may be an acute angle, a right angle, or an obtuse angle.
Further, in the present embodiment, the discharge section 134 penetrates through the wall of the oil storage pool 12, so that the oil outlet 132 extends into the oil storage pool 12, i.e. the discharge section 134 is inserted into the wall of the oil storage pool 12, so as to ensure that the discharge port 132 extends into the oil storage pool 12. Or, the introducing section 133 penetrates through the wall of the oil storage pool 12, that is, the introducing section 133 is inserted into the wall of the oil storage pool 12, the portion of the introducing section 133 connected with the discharging section 134 extends into the oil storage pool 12, and the discharging section 134 is located in the oil storage pool 12 as a whole, so that the upper non-oil storage space of the oil storage pool 12 can be reasonably utilized, and the space occupied by the oil outlet channel 13 can be reduced as much as possible.
As shown in fig. 4 to 7, in another embodiment of the present invention, as an alternative to the above embodiment, a first communicating groove 151 and a second communicating groove 152 are disposed on the side wall of the fixed scroll 15 facing the oil separating structure 100 of the scroll compressor of the present embodiment, as shown in fig. 7, the first communicating groove 151 is close to the oil inlet 131, the second communicating groove 152 is close to the refrigerant outlet 14, the oil drain hole 1017 is connected to the oil inlet 131 through the first communicating groove 151, and the exhaust hole 122 is connected to the refrigerant outlet 14 through the second communicating groove 152. Through set up first intercommunication groove 151 and second intercommunication groove 152 on fixed scroll 15, the refrigeration oil that discharges from oil drain 1017 flows into the oil inlet 131 of oil outlet channel 131 through first intercommunication groove 151, and the refrigerant that discharges from the exhaust hole 122 of oil storage pool 12 discharges through second intercommunication groove 152, like this, need not to set up extra pipeline or pipeline in scroll compressor's casing 10 and guide refrigeration oil or refrigerant fashion, the existing structure of rational utilization scroll compressor simplifies the scroll compressor's of this embodiment overall structure.
In the present embodiment, as shown in fig. 5 and 6, the scroll compressor further includes a sealing member 16, the sealing member 16 abuts against an end surface of the fixed scroll 15 facing the oil separating structure 100 (i.e., a side wall surface of the fixed scroll 15 facing away from the orbiting scroll 18), and the shape of the sealing member 16 is substantially the same as that of the end surface of the fixed scroll 15, and the size of the sealing member 16 is substantially the same as that of a side wall surface of the fixed scroll 15, so that the overall appearance of the scroll compressor is ensured to be more beautiful. Further, a groove 17 is provided on an end surface of the fixed scroll 15 facing the oil separating structure 100, two ends of the groove 17 are opened, the groove 17 and the sealing member 16 surround to form the oil outlet channel 13, an opening at one end of the groove 17 forms an oil outlet 132 of the oil outlet channel 13, and an opening at the other end of the groove 17 forms an oil inlet 131 of the oil outlet channel 13. Therefore, the sealing piece 16 is arranged to be attached to the end face of the fixed scroll 15, the sealing piece 16 is in sealing attachment connection with the end face of the fixed scroll 15, the end face of the groove wall of the groove 17 is abutted against the sealing piece 16, the oil outlet channel 13 can be formed in the casing 30, and the oil outlet channel 13 is simple in arrangement form.
Alternatively, the above-mentioned groove 17 may also be disposed on the sealing member 16, that is, the end surface of the sealing member 16 facing away from the oil content structure 100 is provided with a groove 17 with two open ends, the groove 17 and the end surface of the fixed scroll 15 are surrounded to form the above-mentioned oil outlet channel 13, and the two open ends of the groove 17 respectively form the oil inlet 131 and the oil outlet 132 of the oil outlet channel 13. In this way, the sealing member 16 is arranged to abut against and be connected to the end surface of the fixed scroll 15, the sealing member 16 is in sealing and abutting connection with the end surface of the fixed scroll 15, the end surface of the groove wall of the groove 17 abuts against the sealing member 16, and the oil outlet channel 13 can be formed in the casing 30.
In the present embodiment, the seal 16 may be, but is not limited to, a gasket or the like that is sealingly attached to the side wall surface of the fixed scroll 15.
In the above two embodiments, the oil return hole 121 and the air exhaust hole 122 both penetrate the sealing member 16, so as to avoid the influence of the arrangement of the sealing member 16 on the normal discharge of the refrigerant oil and the refrigerant.
In another embodiment of the present invention, as another alternative to the above embodiment, as shown in fig. 4, the casing 10 of the scroll compressor includes an oil content casing 101, the oil content casing 101 has a connection surface 1011, the connection surface 1011 and the fixed scroll 15 are connected in an end face adapting manner toward the oil content structure 100, wherein the connection surface 1011 and the end face adapting manner of the fixed scroll 15 mean that the shape of the connection surface 1011 is the same as or similar to the shape of the end face of the fixed scroll 15, and the size of the connection surface 1011 is substantially the same as the size of the end face of the fixed scroll 15. Further, a groove with two open ends is arranged on the connecting surface 1011, specifically, the connecting surface 1011 is recessed into the groove 17 away from the fixed scroll 15, the end surface of the fixed scroll 15 abuts against the connecting surface 1011 and surrounds the groove 17 to form the oil outlet channel 13, one end of the groove 17 is open to form the oil outlet 132 of the oil outlet channel 13, and the other end of the groove 17 is open to form the oil inlet 131 of the oil outlet channel 13. The oil outlet channel 13 can be formed by arranging the groove 17 on the connecting surface 1011 of the oil content casing 101, and when the connecting surface 1011 of the oil content casing 101 is attached to the end surface of the fixed scroll 15, the end surface of the groove wall of the groove 17 is abutted against the end surface of the fixed scroll 15, and the arrangement form of the oil outlet channel 13 is relatively simple.
In this embodiment, as shown in fig. 4, a receiving groove 1012 for receiving the concave groove 17 is further provided in the oil enclosure 101, an inner wall surface of the receiving groove 1012 and an outer wall surface of the concave groove 17 surround to form the oil reservoir 12, and the oil return hole 121 and the exhaust hole 122 are both provided in the oil enclosure 101. Thus, by arranging the separate oil content housing 101 for arranging the oil outlet channel 13, the oil content housing 101 is formed independently, so that the oil outlet channel 13, the oil storage tank 12, the exhaust hole 122 and the like can be more conveniently disassembled and assembled, and the maintenance and the like of the oil outlet channel 13, the oil storage tank 12 and the like can be more conveniently carried out.
In this embodiment, as shown in fig. 4, a connecting channel 1013 is further provided in the oil housing 101, the connecting channel 1013 is used for the precipitated refrigerant to flow through, an inlet of the connecting channel 1013 is connected to the oil outlet 132, an outlet of the connecting channel 1013 is connected to the gas exhaust hole 122, and the refrigerant discharged from the oil outlet 132 of the oil outlet channel 13 flows through the connecting channel 1013 and then is discharged through the gas exhaust hole 122. The connecting channel 1013 can increase the distance between the air outlet 122 and the oil outlet 132 of the oil outlet channel 13, so as to prevent the frozen oil discharged from the oil outlet 132 from entering the air outlet 122; on the other hand, the channel wall of the connecting channel 1013 is communicated with the tank wall of the oil storage tank 12, and the separated refrigerant is in contact with the channel wall of the connecting channel 1013, so that the connecting channel 1013 can further cool the separated refrigerant, so that the gaseous refrigerant oil mixed in the refrigerant is condensed on the channel wall and flows back to the oil storage tank 12, thereby better preventing the refrigerant oil from being discharged along with the refrigerant.
In this embodiment, as shown in fig. 4, an oil blocking portion 1014 is provided on the channel wall surface of the connecting channel 1013, and the oil blocking portion 1014 is used for blocking the refrigerant oil flowing out from the oil outlet 132 from flowing into the air outlet 122 through the connecting channel 1013. In the present embodiment, oil blocking portion 1014 is disposed near oil outlet 132, and a gap is formed between oil blocking portion 1014 and the end surface of oil outlet 132, ensuring smooth discharge of the freezing oil flowing out from oil outlet 132. Thus, the oil blocking portion 1014 can effectively block the refrigerant oil from entering the connecting channel 1013, and the refrigerant oil and the precipitated refrigerant can be normally discharged through the gap between the oil blocking portion 1014 and the end surface of the oil outlet 132, so that the refrigerant oil can be effectively blocked from entering the air vent 122 by the oil blocking portion 1014, and the normal discharge of the refrigerant oil and the refrigerant is not hindered.
Further, in the present embodiment, an oil blocking surface 1015 is formed on a surface of oil blocking portion 1014 facing oil outlet 132, and oil blocking surface 1015 is spaced from an end surface of oil outlet 132, that is, a gap is ensured between oil blocking portion 1014 and the end surface of oil outlet 132. Specifically, oil outlet 132 may be partially or completely blocked by oil blocking surface 1015, so as to ensure that the frozen oil discharged from oil outlet 132 hits oil blocking surface 1015 and falls back into oil reservoir 12.
Further, in the present embodiment, the oil blocking portion 1014 is a rib-like structure integrally formed on the channel wall of the connecting channel 1013.
In this embodiment, as shown in fig. 4, the oil content structure 100 includes an oil content chamber 1016 disposed in the oil content housing 101, and the oil drain hole 1017 and the refrigerant outlet 14 are both disposed on a wall of the oil content chamber 1016, such that the oil drain hole 1017 is connected to the first connecting groove 151, and the refrigerant oil discharged from the oil drain hole 1017 enters the oil inlet 131 of the oil outlet channel 13 through the first connecting groove 151.
Further, an oil inlet 1019 is further provided on a wall of the oil dividing chamber 1016, the oil inlet 1019 is connected to the mixed fluid outlet 153 provided on the fixed scroll 15, so that the mixed fluid of the refrigerant and the refrigerant oil discharged from the compression chamber 30 of the scroll compressor enters the oil dividing chamber 1016 and is processed by the oil, and in this embodiment, a flow path of the mixed fluid is shown by a dotted arrow in fig. 4. In this way, the mixed fluid discharged from the mixed fluid outlet 153 of the fixed scroll 15 directly enters the oil separation chamber 1016, the separated refrigerant oil enters the oil inlet 131 of the oil outlet passage 13 through the oil discharge hole 1017, and the separated refrigerant is discharged through the refrigerant outlet 14.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, the oil content structure 100 further includes an oil content insertion tube 11 disposed in the oil content chamber 1016, the oil content insertion tube 11 has an air inlet end 111 and an air outlet end 112, the air inlet end 111 of the oil content insertion tube 11 is disposed toward one side of the oil discharge hole 1017, the air outlet end 112 of the oil content insertion tube 11 is communicated with the refrigerant outlet 14, and the mixed fluid enters the oil content chamber 1016 from the oil content inlet 1019 and then spirally flows and collides with the chamber wall of the oil content chamber 1016 and the oil content insertion tube 11, so as to separate the refrigerant from the refrigeration oil.
Further, in the present embodiment, the flow area S1 of the refrigerant outlet 14, the flow area S2 of the air inlet end 111 of the oil content insertion tube 11, and the flow area S3 of the oil drain hole 1017 satisfy a proportional relationship: S2/S1 is more than or equal to 0.05 and less than or equal to 0.5, and S3/S1 is more than or equal to 0.02 and less than or equal to 0.3. The proportional relation of 0.05-0.5 of the flow area S2/S1 and 0.02-0.3 of the flow area S3 of the oil inlet end 111 of the oil insertion pipe 11, S2 of the air inlet end 111 of the oil outlet hole 1017 is satisfied, namely the ratio of the flow area S2 of the air inlet end 111 of the oil insertion pipe 11 to the flow area S1 of the refrigerant outlet hole 14 is designed within the range of 0.05-0.5, and the ratio of the flow area S3 of the oil outlet hole 1017 to the flow area S1 of the refrigerant outlet hole 14 is designed within the range of 0.02-0.3. Like this, the area of overflowing of refrigerant export 14 is greater than the area of overflowing of the inlet end 111 of oil content intubate 11, the area of overflowing of refrigerant export 14 is greater than the area of overflowing of oil drain hole 1017, like this, the refrigerant of separation can discharge through refrigerant export 14 with faster speed, thereby in time reduce the pressure in oil content chamber 1016, reduce the pressure that acts on through the discharge of oil drain hole 1017's frozen oil, thereby make the velocity of flow of the frozen oil of discharging from oil drain hole 1017 reduce, better for guaranteeing that the frozen oil in the oil storage pool 12 submerges oil return hole 121 all the time and provide the guarantee.
In some embodiments, the ratio between the flow area S2 of the air inlet end 111 of the oil insertion tube 11 and the flow area S1 of the refrigerant outlet 14, i.e., S2/S1, may be 0.05, 0.1, 0.2, 0.3, 0.4, or 0.5, and the ratio between the flow area S3 of the oil drain hole 1017 and the flow area S1 of the refrigerant outlet 14, i.e., S3/S1, may be 0.02, 0.05, 0.08, 0.1, 0.15, 0.2, 0.25, or 0.3.
Further, in the present embodiment, as shown in fig. 2, 3 and 4, a proportional relationship of 0.08 ≦ S3/S2 ≦ 0.8 is satisfied between the flow area S2 of the air inlet end 111 of the oil insertion tube 11 and the flow area S3 of the oil drain hole 1017, that is, a ratio of the flow area S3 of the oil drain hole 1017 to the flow area S2 of the air inlet end 111 of the oil insertion tube 11 is designed within a range of 0.08 to 0.8. In particular, such asFIG. 8 shows S3/S2 with blow-by amount q3(i.e., the amount of refrigerant leaking into the oil return passage 20 of the scroll compressor through the oil return hole 121), it is easy to see that the blow-by amount gradually increases with the increase of S3/S2, and thus, the ratio of S3 to S2 is selected and designed within the range of 0.08 to 0.8, and on the premise of considering the manufacturing error of the parts, the blow-by amount is relatively small, so that the adverse effect on the backflow volume of the refrigerant oil is not generated, that is, within this range, the blow-by amount leaking through the oil return hole 121 of the oil storage tank 12 has little influence on the ratio of the refrigerant oil in the oil return.
In some specific embodiments, the ratio of the flow area S3 of the oil drainage hole 1017 to the flow area S2 of the air inlet end 111 of the oil insertion tube 11, i.e., S3/S2, may be 0.08, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, or 0.8, etc.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, a proportional relationship of 1 ≤ S4/S3 ≤ 7 is satisfied between the flow area S4 of the oil outlet 132 of the oil outlet channel 13 and the flow area S3 of the oil drain hole 1017, i.e., a ratio of the flow area S4 of the oil outlet 132 of the oil outlet channel 13 to the flow area S3 of the oil drain hole 1017 is designed within a range of 1-7. In this way, the flow area S4 of the oil outlet 132 of the oil outlet passage 13 is larger than the flow area S3 of the oil drain hole 1017, and when the frozen oil flows out from the oil outlet 132, the flow area suddenly increases, the flow speed is further slowed, and the frozen oil discharged from the oil outlet 132 is further reduced in impact on the frozen oil level in the oil storage pool 12.
Specifically, as shown in fig. 9, which shows the relationship between S4/S3 and the outlet flow rate of the refrigerant flowing out of the oil outlet 132, it is apparent from the figure that the outlet flow rate gradually decreases with the increase of S4/S3, and thus, the ratio of S4 to S3 is selected and designed within the range of 1 to 7, and under the premise of considering the manufacturing error of the component, the flow rate of the refrigerant flowing out of the oil outlet 132 of the oil outlet channel 13 is small, so as not to adversely affect the return volume of the refrigerant, that is, within this range, the proportion of the amount of blowby gas leaking through the oil return hole 121 of the oil reservoir 12 to the refrigerant in the return oil is not greatly affected.
In some specific embodiments, the ratio between the flow area S4 of the oil outlet 132 of the oil outlet channel 13 and the flow area S3 of the oil drain hole 1017, i.e., S4/S3, may be 1, 2, 3, 4, 0.4, 5, 6, or 7, etc.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, a proportional relationship of 0.015 ≤ S5/S2 ≤ 1 is satisfied between the flow area S5 of the vent hole 122 and the flow area S2 of the air inlet end 111 of the oil insertion tube 11, that is, a ratio of the flow area S5 of the vent hole 122 to the flow area S2 of the air inlet end 111 of the oil insertion tube 11 is designed within a range of 0.015-1. Specifically, as shown in fig. 10, which shows a relationship between S5/S2 and Pk-Pd' (a pressure difference Δ P between the oil outlet 132 and the oil inlet 131 of the oil outlet channel 13), it is apparent from the figure that the values of S5/S2 are in the range of 0.015 to 1, and the pressure difference Δ P is greater than zero, that is, the refrigerant precipitated from the frozen oil can be discharged through the air outlet 122 under the pressure action; moreover, as the greater the pressure difference Δ P, the faster the flow speed of the refrigeration oil in the oil outlet channel 13, on the premise that the pressure difference Δ P meets the refrigerant discharge requirement, the ratio of S5/S2 is prevented from being set too large, so that the refrigeration oil in the oil outlet channel 13 is prevented from accelerating to flow under the action of too large pressure, the flow speed of the refrigeration oil along the oil outlet channel 13 is ensured, and the oil outlet stability of the oil outlet channel 13 is ensured; in addition, the ratio of S5/S2 is selected in the value range, so that overflow from the oil outlet 132 of the oil outlet channel 13 through the vent hole 122 due to overlarge hole diameter of the vent hole 122 is avoided.
In some specific embodiments, the ratio of the flow area S5 of the vent hole 122 to the flow area of the air inlet end 111 of the oil insertion tube 11, i.e., S5/S2, may be 0.015, 0.01, 0.02, 0.03, 0.04, 0.05, 0.06, 0.07, 0.08, 1.0, or the like.
In another embodiment of the present invention, as shown in fig. 2, fig. 3 and fig. 4, a rectification chamber 1018 is further disposed in the oil content casing 101, and the rectification chamber 1018 is disposed near the oil content chamber 1016, and the rectification chamber 1018 is used for performing a first-stage pressure-reducing and speed-reducing process on the mixed fluid of the refrigerant and the refrigeration oil before the mixed fluid enters the oil content chamber 1016. In this embodiment, the mixed fluid inlet 1020 communicates the mixed fluid outlet 153 of the fixed scroll 15 with the rectifying chamber 1018, so that the mixed fluid discharged from the compression chamber 30 is introduced into the rectifying chamber 1018, the mixed fluid discharged from the compression chamber 30 of the scroll compressor enters the rectifying chamber 1018 through the mixed fluid inlet 1020, and the mixed fluid discharged from the rectifying chamber 1018 enters the oil separating chamber 1016 through the oil separating inlet 1019 to be subjected to oil-gas separation, and in particular, when the rectifying chamber 1018 is provided, the flow path of the mixed fluid is as indicated by the dotted arrows in fig. 2 and 4.
In this embodiment, the oil inlet 1019 is provided above the mixed fluid inlet 1020 in the direction of gravity, so that the mixed fluid entering the rectifying chamber 1018 from the oil inlet 1019 is prevented from directly entering the oil chamber 1016 through the oil inlet 1019 without flowing through the rectifying chamber 1018, that is, the mixed fluid is prevented from short-circuiting, thereby ensuring that the rectifying chamber 1018 can reliably and effectively rectify and depressurize the mixed fluid. When in use, the mixed fluid inlet 1020 arranged on the oil content shell 101 is connected with the mixed fluid outlet 153 arranged on the static scroll 15, so that the mixed fluid of the refrigerant and the refrigeration oil discharged from the compression cavity 30 of the scroll compressor enters the rectification chamber 1018 through the mixed fluid inlet 1020, the rectification chamber 1018 can rectify the discharged mixed fluid, the flow rate of the mixed fluid is reduced, the pressure pulsation is weakened, and the primary pressure reduction of the mixed fluid is realized, therefore, when the mixed fluid rectified by the rectification chamber 1018 enters the oil content cavity 1016 to carry out oil content treatment, the pressure of the mixed fluid is greatly reduced due to the primary pressure reduction, when the mixed fluid collides with the cavity wall in the oil content cavity 1016 and the oil content insertion pipe 11, the pressure pulsation of the mixed fluid is weakened, the flow rate is reduced, the impact force of the mixed fluid on the cavity wall of the oil content cavity 1016 and the oil content insertion pipe 11 is reduced, the impact noise is reduced, the impact loss of the oil content insertion pipe 11 is reduced, and the service life is prolonged.
Further, in the present embodiment, as shown in fig. 4, the rectifying chamber 1018 is a chamber having a streamline wall 1021, specifically, the streamline wall 1021 is provided at a side portion of the mixed fluid inlet 1020, and the mixed fluid flowing in through the mixed fluid inlet 1020 flows in the rectifying chamber 1018 under the guide of the streamline wall 1021, so that the mixed fluid flows along the streamline wall 1021, the fluid flow becomes smoother, the impact of the mixed fluid on the inner wall surface of the rectifying chamber 1018 can be further reduced, and the noise reduction effect of the rectifying chamber 1018 can be further effectively improved.
Further, in the present embodiment, as shown in fig. 5 and 6, when the sealing member 16 is provided in the scroll compressor, the position of the sealing member 16 facing the mixed fluid inlet 1020 is hollowed out, so that a clearance 161 is formed at the position of the sealing member 16 facing the mixed fluid inlet 1020, which avoids the mixed fluid inlet 1020, thereby ensuring that the discharge of the mixed fluid is not blocked by the sealing member 16, and ensuring that the mixed fluid can be discharged into the rectification chamber 1018 through the mixed fluid inlet 1020.
In another embodiment of the present invention, the oil enclosure 101 and the sealing element 16 are made of materials with strong impact resistance, so as to ensure that the oil enclosure 101 and the sealing element 16 are not deformed by the impact of the mixed fluid, the refrigerant or the refrigerant oil, thereby prolonging the service life of the oil enclosure 101 and the sealing element 16.
In another embodiment of the present invention, the refrigerant outlet 14 is set to be gradually flared, that is, the flow area of the refrigerant outlet 14 increases gradually along the refrigerant flowing direction, so that at least a portion of the refrigerant outlet 14 forms a trumpet shape, the flow speed of the refrigerant decreases gradually when flowing in the refrigerant outlet 14, thereby reducing the speed and pressure of the air flow at the outlet of the refrigerant outlet 14, playing a role of rectification to a certain extent, further making the refrigerant discharge more stable, and reducing the impact of the refrigerant to the casing 10 along the flowing and discharging process of the refrigerant outlet 14.
In the embodiment of the present invention, when the refrigerant outlet 14 is formed as a gradually expanding opening, the flow area S1 of the refrigerant outlet 14 is the flow area of the inlet end of the refrigerant outlet 14.
Another embodiment of the present invention further provides a refrigeration device (not shown), which includes the above scroll compressor.
The refrigeration equipment of the embodiment, through using the above scroll compressor, because the oil outlet channel 13 is arranged in the casing 10 of the scroll compressor, the oil outlet channel 13 can guide the refrigerant oil to flow against the direction of gravity, thereby the outflow speed and the outflow pressure of the refrigerant oil discharged into the oil storage pool 12 can be reduced, the impact force of the refrigerant oil in the oil storage pool 12 when the refrigerant oil is discharged is reduced, thereby the refrigerant oil in the oil storage pool 12 is ensured to be kept stable, the effective oil storage volume of the oil storage pool 12 is improved, the refrigerant oil is always immersed in the oil return hole 121 of the oil storage pool 12, the refrigerant is prevented from being directly leaked into the oil return channel 20 of the scroll compressor through the oil return hole 121, the oil return of the scroll compressor is sufficient, the compression efficiency of the scroll compressor is improved, and the refrigeration capacity of the refrigeration equipment is optimized.
Another embodiment of the present invention further provides a vehicle, which includes the above-mentioned refrigeration equipment.
The vehicle that this embodiment provided, through using foretell refrigeration plant, at vehicle refrigeration in-process, because refrigeration plant's refrigeration capacity and refrigeration efficiency can maintain higher level all the time to can effectively shorten the inside cooling of vehicle consuming time, the cooling speed of vehicle promotes, and the promotion is experienced with the car.
It should be noted that, in the present embodiment, the specific type of the vehicle is not limited, for example, the vehicle may be a conventional fuel vehicle, and may also be a new energy vehicle, where the new energy vehicle includes, but is not limited to, a pure electric vehicle, an extended range electric vehicle, a hybrid electric vehicle, a fuel cell electric vehicle, a hydrogen engine vehicle, and the like, and the present embodiment is not particularly limited thereto.
The above are merely examples of the present invention and are not intended to limit the present invention. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (18)

1. The utility model provides a scroll compressor, includes the casing, be provided with oil content structure and oil storage pool in the casing, its characterized in that, still be provided with out oil channel in the casing, it has oil inlet and oil-out to go out oil channel, the oil-out is located the top of oil inlet, the oil inlet with the oil drain hole of oil content structure is linked together, the oil-out with the oil storage pool is linked together.
2. The scroll compressor of claim 1, wherein the housing defines a refrigerant outlet, and wherein the oil reservoir defines an air vent in a wall thereof, the air vent being in communication with the refrigerant outlet.
3. The scroll compressor of claim 2, wherein an open area of the oil outlet passage increases gradually in a direction from the oil inlet to the oil outlet.
4. The scroll compressor of claim 2, wherein the oil outlet passage is a curved passage having at least one curved section.
5. The scroll compressor of claim 2, wherein a plurality of ribs are spaced apart along the wall of the oil storage tank, one end of the ribs facing the top of the oil storage tank and the other end of the ribs facing the bottom of the oil storage tank.
6. The scroll compressor of claim 2, wherein the oil outlet is disposed opposite a floor of the oil reservoir.
7. The scroll compressor of claim 2, wherein the oil outlet is disposed toward a floor of the oil storage tank, and a buffer portion is disposed on a wall of the oil storage tank, the buffer portion being located below the oil outlet and forming a gap with the wall of the oil storage tank.
8. The scroll compressor of any one of claims 1 to 7, wherein the oil outlet passage is an oil outlet pipe, the oil outlet pipe comprising an intake section and a discharge section connected to the intake section, a port of the intake section remote from the discharge section forming the oil inlet, and a port of the discharge section remote from the intake section forming the oil outlet.
9. The scroll compressor according to any one of claims 2 to 7, further comprising a fixed scroll, wherein a side wall of the fixed scroll facing the oil separation structure is provided with a first communicating groove and a second communicating groove, the oil discharge hole is connected to the oil inlet through the first communicating groove, and the air discharge hole is connected to the refrigerant outlet through the second communicating groove.
10. The scroll compressor of claim 9, further comprising a sealing member, wherein the sealing member is attached to an end surface of the fixed scroll facing the oil content structure in an abutting manner, a groove with two open ends is disposed on the end surface of the fixed scroll facing the oil content structure, the groove and the sealing member are enclosed to form the oil outlet channel, and the two open ends of the groove respectively form the oil outlet and the oil inlet.
11. The scroll compressor of claim 9, further comprising a sealing member, wherein the sealing member is attached to an end surface of the fixed scroll facing the oil content structure, a groove with two open ends is disposed on an end surface of the sealing member facing away from the oil content structure, the groove and the end surface of the fixed scroll surround to form the oil outlet channel, and the two open ends of the groove respectively form the oil outlet and the oil inlet.
12. The scroll compressor of claim 9, wherein the casing comprises an oil content housing, the oil content housing has a connection surface adapted to be connected with an end surface of the fixed scroll facing the oil content structure, the connection surface is provided with a groove with two open ends, the end surface of the fixed scroll abuts against the connection surface and encloses with the groove to form the oil outlet channel, and the two open ends of the groove respectively form the oil outlet and the oil inlet.
13. The scroll compressor of claim 12, wherein a receiving groove for receiving the groove is further provided in the oil housing, and an inner wall surface of the receiving groove and an outer wall surface of the groove enclose the oil reservoir.
14. The scroll compressor of claim 13, wherein a connecting channel is further provided in the oil enclosure for the separated refrigerant to flow through, an inlet and an outlet of the connecting channel are connected to the oil outlet and the gas discharge hole, respectively, and a channel wall of the connecting channel is connected to a wall of the oil storage tank.
15. The scroll compressor of claim 14, wherein an oil dam is provided on a channel wall of the connecting channel, and a gap is formed between the oil dam and an end surface of the oil outlet.
16. The scroll compressor of any one of claims 12 to 15, wherein the oil separation structure includes an oil separation chamber disposed in the oil separation housing, and the oil discharge hole and the refrigerant outlet are disposed on a wall of the oil separation chamber; an oil separation inlet is further formed in the wall of the oil separation cavity, a mixed fluid outlet is formed in the static scroll disc, and the oil separation inlet is communicated with the mixed fluid outlet.
17. A refrigeration apparatus comprising a scroll compressor as claimed in any one of claims 1 to 16.
18. A vehicle comprising a refrigeration unit as claimed in claim 17.
CN202022230769.6U 2020-09-30 2020-09-30 Scroll compressor, refrigeration equipment and vehicle Active CN214170818U (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115773247A (en) * 2022-11-08 2023-03-10 上海本菱涡旋压缩机有限公司 Scroll compressor
WO2023240969A1 (en) * 2022-06-16 2023-12-21 珠海格力电器股份有限公司 Oil return structure of compressor, compressor, and air conditioner

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2023240969A1 (en) * 2022-06-16 2023-12-21 珠海格力电器股份有限公司 Oil return structure of compressor, compressor, and air conditioner
CN115773247A (en) * 2022-11-08 2023-03-10 上海本菱涡旋压缩机有限公司 Scroll compressor
CN115773247B (en) * 2022-11-08 2024-05-31 上海本菱涡旋压缩机有限公司 Vortex compressor

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