KR20170069899A - Apparatus for storing oil of a refrigerant circuit - Google Patents

Abstract

The present invention particularly relates to an oil storage device (7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b') in a refrigerant circulation system (1) for an automotive air conditioning system. The refrigerant circulation system 1 has a compressor 2, an oil separator 3 in the flow direction, and a heat exchanger for cooling and / or liquefying the refrigerant. The device (7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b') has an oil retention volume (15) having an inlet (16) and an outlet (17) Respectively. In this case the flow path extends in the flow direction in the oil separator 3 to a mixing point 8 arranged in front of the compressor. The device (7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b') also has an adjustable flow cross section of the outlet (17) to regulate the mass flow of recirculated oil, The cross section of the outlet 17 can be varied and closed by a variable arrangement of the floats 18a, 18b between the wall and the floats 18a, 18b.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an oil storage device for a refrigerant circulation system,

The present invention relates in particular to an oil storage device in a refrigerant circulation system for an automotive air conditioning system. The refrigerant circulation system includes a compressor, an oil separator, and a heat exchanger for cooling and / or liquefying the refrigerant. The apparatus has a storage volume for oil having an inlet and an outlet, and is disposed in a flow path for oil recirculation. In which case the flow path extends in the flow direction in the oil separator to a mix point located in front of the compressor.

The oil has a number of functions within the refrigerant circulation system. This oil is used, on the one hand, for the lubrication function of the movable parts disposed inside the compressor, thus reducing the friction between parts, especially formed of metal parts. This reduces the wear of the compressor. On the other hand, the oil improves the sealing of the compressor to the periphery and the internal sealing between the high and low pressure regions of the refrigerant inside the compressor. Another function of the oil inside the refrigerant circulation system is to absorb and release the heat generated inside the compressor, for example due to friction between the moving parts of the compressor.

Although oil is primarily required only inside the compressor, it is inevitable that the oil also circulates within the refrigerant circulation system. In this case, the amount of oil circulated and circulated within the refrigerant circulation system depends on many factors. These factors include, inter alia, the design and construction and construction of the compressor and its peripheral components, in particular the refrigerant circulation system, the aging and conditions associated with the wear of the compressor, the operating and operating conditions, and the mixing of refrigerant and oil.

In the refrigerant circulation systems known in the prior art, the oil circulation rate varies between 1% and 15% of the mass flow of the refrigerant. The oil of the compressor circulating through the refrigerant circulation system together with the refrigerant has various effects. The oil thus changes, for example, the quality and physical and thermodynamic properties of the refrigerant-oil mixture. The presence of oil reduces the effectiveness of the heat exchangers of the refrigerant circulation system because the oil film acts like an additional insulating layer so that heat transfer inside the heat exchanger when the heat transfer surfaces are covered with the oil film, This is because it is affected. The oil may, in some cases, remain in the oil traps of the so-called refrigerant circulation system, in which the oil traps are formed, in particular, in regions with low refrigerant velocities. The oil collected in the oil traps can suddenly overflow like a liquid vibration column and return to the compressor. In this case, a pressure wave may be generated, which again causes a fluid lock. In low temperature applications, the likelihood of oil movement within the refrigerant circulation system is significantly limited due to the relatively higher viscosity at low temperatures. Reduced oil level inside the compressor can cause irreversible mechanical damage of the compressor. In addition, essentially incompressible oils are not cooled during the inflation process to a lesser degree. The oil is mixed with the refrigerant, in which case the refrigerant partially evaporates. Here, some cooling capacity of the refrigerant, i.e., about 8% to 10%, is used to cool the compressor oil.

US 6,058, 727 A describes a refrigerant circulation system for cooling air with a compressor, a condenser, an expansion member and an evaporator. The refrigerant circulation system also has a flow path for recirculating the oil from the outlet of the compressor to the inlet of the compressor, together with the oil separator and the oil cooler. During the refrigerant compression in the gaseous state, the heated oil is cooled in front of the inlet leading into the compressor. In this case, heat is transferred from the oil to the refrigerant drawn from the compressor. The oil cooler has an internal heat exchanger as a heat exchanger unit, in which case the heat exchanger unit can be located inside the accumulator of refrigerant.

US 2010/0251756 A1 also discloses a refrigerant for cooling air, comprising a compressor, a condenser, an expansion member and an evaporator, and a flow path for recirculating oil from an outlet of the compressor to an inlet of the compressor together with an oil separator and an oil cooler Describe the circulatory system. The oil cooler is formed as an air-oil heat exchanger and is arranged after the evaporator in the direction of air flow. Heat is transferred from the oil to the cooled air during evaporator perfusion.

In the case of the refrigerant circulations shown in the above US 6,058,727 A and US 2010/0251756 A1, the oil mass flow recirculated to the compressor can not be regulated.

US 6,579,335 B2 discloses an apparatus for compressing gaseous fluid with components for compressing the gas and separating the oil from the compressed gas, for cooling the oil and for storing the oil. The oil is again supplied to the compressor together with the gaseous fluid to be compressed. The oil is guided through a heat exchanger for such oil cooling. In this case, the heat is transferred from the oil to the gaseous fluid to be compressed. The gaseous fluid is then compressed. The oil separator, oil cooler and oil reservoir are arranged in such a way that they are integrated into one common housing. The oil is directed from the oil reservoir to the compressor via a connecting line. A valve for regulating the mass flow of the oil to be recirculated is disposed in the connection line.

In the case of conventional refrigerant circulations having a system for recirculating oil (the oil flows through the compressor with the refrigerant) from the outlet of the compressor to the inlet of the compressor, on the one hand, the oil mass flow recirculated to the compressor is regulated I can not. The refrigerant circulation systems known in the prior art for oil recirculation on the other hand do not have means to prevent bypassing between the high pressure side refrigerant at the outlet of the compressor through oil recirculation and the high pressure side refrigerant at the inlet of the compressor.

An object of the present invention is to provide an oil storage device of a refrigerant circulation system so that a sufficient lubricating function of the compressor is ensured by the oil. The device must be designed in a manner that does not take up much space and at the same time must enable efficient and safe operation of the refrigerant circulation system. In addition, there must be a minimum cost in terms of manufacturing, maintenance and assembly of the device. The device should also be configured to prevent refrigerant bypassing from the high pressure side to the low pressure side of the refrigerant circulation system. In addition, the oil must have a certain degree of purity as a lubrication means to prevent the destruction of the moving parts of the compressor.

This problem is solved by the object having the features of the independent claim. Improvements are set forth in the dependent claims.

The above object is solved in particular by an oil storage device in a refrigerant circulation system according to the present invention for an automotive air conditioning system. The refrigerant circulation system has a compressor, an oil separator and a heat exchanger for cooling and / or liquefying the refrigerant in the flow direction. The apparatus has an oil retention volume having an inlet and an outlet, and is disposed in a flow path for oil recirculation. Wherein the flow path extends from the oil separator to a mixing point located in front of the compressor in the flow direction.

According to the inventive concept, the oil storage device has an adjustable outlet perfusion cross-section to regulate the mass flow of recirculated oil. In this case, the perfusion cross-section of the outlet can be changed and closed by the variable arrangement of the float between the wall and the float.

According to a first alternative embodiment of the present invention, the float is formed in a circular sphere shape. And the spherical surface of the float contacts the wall when the outlet of the oil storage device is closed.

According to a second alternative embodiment of the present invention, the float is formed in a truncated cone shape and has a base surface, a cover surface and an (external) side surface. When the outlet of the oil storage device is closed, the side surface of the float contacts the wall. In this case, the side surface obliquely disposed between the base surface and the cover surface protrudes into the free transverse section of the outlet, the cover surface is aligned in the direction of the outlet, and the base surface is aligned in the storage volume direction of the oil storage device . The base surface has a larger surface area than the cover surface.

According to another first alternative embodiment of the present invention, the float is arranged in a manner supported by the guide member and the spring member. In this case, the spring member is formed as a cylindrical coil spring. The guide member is used to guide the float with respect to the outlet, especially when the fill level of the oil is low inside the reservoir volume. The spring member causes a force action on the float in the direction of the outlet closing using elastic force.

According to yet another second alternative embodiment of the present invention, the float is arranged in a manner supported by a spring member. In this case, the spring member is formed of a spring steel sheet. Wherein the spring member formed of a spring steel sheet is used on one hand to guide the float in relation to the outlet, especially when the filling level of the oil is low inside the stocking volume, and is used to guide the float in the outlet closing direction It causes the force action on. The spring steel sheet is bent, so that the initial stress of the spring steel sheet causes elastic force.

According to the present invention, a sealing member having a filter function is disposed between the connection line of the refrigerant circulation system and the inlet of the storage volume of the oil storage device. In this case, the sealing member is formed in such a manner that a filter member for filtering separated oil mixed with impurities is incorporated, so that the oil storage device is connected to the connection line in a fluid sealing manner, And is introduced into the storage volume through the sealing member with the filter function. As an alternative to the sealing member with a filter function, the inlet region is provided with a filter element for filtering the separated oil, which is mixed with impurities, so that the oil flows into the storage volume through the filter element. The oil reservoir is connected to the connection line in a fluid-tight manner via a separate seal.

In a further preferred embodiment of the invention, the oil storage device is formed as a connecting block between the components of the refrigerant circulation system. In which case the connecting block is preferably threaded with the adjacently disposed components of the refrigerant circuit.

The connecting block preferably has locking means in the form of a code pin so that the connecting block is a step of assembling the refrigerant circulation system with the adjacently disposed components of the refrigerant circulation system, And then fixed. The connecting block preferably has threaded bores for threaded engagement with the adjacently disposed components of the refrigerant circuit.

As the refrigerant circulation system can be operated not only as a component of a compression chiller but also as a component of a heat pump, consequently the device according to the invention can be used not only as a component of a compression chiller, but also as a component of a heat pump system It can be seen that it can also be used as a component part. Further, the refrigerant circulation system may include an internal heat exchanger not shown in the figure. In this case, the internal heat exchanger means a heat exchanger disposed inside the circulation system, and the heat exchanger is used for heat transfer between the high pressure side refrigerant and the low pressure side refrigerant. On the other hand, in this case, for example, the liquid refrigerant or the supercritical refrigerant is cooled again after the condensation and, on the other hand, the suction gas is overheated in front of the compressor.

The oil storage device may preferably be used for a variety of refrigerants such as R134a, R1234yf, R744, R600a, R290, R152a, R32, and mixtures thereof, and may be suitably adjusted for the refrigerants.

In conclusion, the oil storage device according to the present invention has the following additional advantages:

Since the refrigerant-oil mixture, i.e. the non-oil refrigerant, is guided through the heat exchanger, it is possible to reduce the pressure loss of the refrigerant during the perfusion of the heat exchangers,

- heat exchangers. Since the oil no longer needs to be cooled or heated during perfusion, the efficiency of the system, especially the refrigerant circulation system,

- The amount of oil is optimized and minimized with it, thus reducing the cost of manufacturing, maintenance and operation of the system,

- By integrating the filter function and the bypass prevention function of the refrigerant, the parts for oil separation in the refrigerant circulation system can have a simple structure,

- It can be applied flexibly without requiring much space in installation space and adjustment side when inserting into the car coolant circulation system, and

- To reduce the size of the oil storage device itself, a connection line to the inlet of the device can be used as a storage volume if necessary.

Further details, features and advantages of embodiments of the present invention will be apparent from the following detailed description of embodiments with reference to the accompanying drawings. Explanation of drawings:
1 is a view showing an oil storage device incorporated in a refrigerant circulation system,
2 is a view showing an oil storage device including a spherical float having a cylindrical coil spring and a filter member incorporated in the sealing member,
3 is a view showing an oil storage device including a spherical float having a cylindrical coil spring and a filter member,
4 is a view showing an oil storage device including a truncated float having a cylindrical coil spring and a filter member,
5 is a view showing an oil storage device including a spherical float having a spring steel sheet and a filter member, and Fig.
6 is a view showing an oil storage device including a frustoconical float having a spring steel sheet and a filter member.

Fig. 1 shows a compressor 2, an oil separator 3, a heat exchanger 4 acting as a condenser / gas cooler, a first expansion member 5 and a heat exchanger 6 acting as an evaporator, 1 shows a refrigerant circulation system 1 having an apparatus 7 for storing oil separated in the oil separator 3, arranged in an integrated manner.

The oil storage device 7 is formed within the assembly or within the flow path for oil recirculation, wherein the flow path extends from the oil separator 3 in the flow direction to a mixing point 8 located in front of the compressor . The connecting lines 10, 11 and 12 are respectively flowed in the direction of the arrows, in which case the connecting lines 10 are connected by a refrigerant-oil mixture, the connecting lines 11 by refrigerant, ) Are perfused by oil.

The oil passes through the compressor 2 in the flow direction inside the refrigerant circulation system 1 and is separated from the refrigerant-oil mixture G after passing through the refrigerant compression process. The separated oil is guided to the device 7 via the connection line 12 while the refrigerant KM is guided to the heat exchanger 4 via the connection line 11.

2 shows an oil storage device 7.1a including a spherical float 18a having a guide member 19 and a spring member 20 and a sealing member 21. As shown in Fig. In this case, the spring member 20 is formed of a cylindrical coil spring. A filter member is incorporated in the sealing member 21, so that the sealing member 21 has a filter function.

The oil separated in the oil separator 3 flows through the inlet 16 into the oil storage device 7.1a, which is preferably formed as a connection block. The device (7.1a) is connected in fluid sealing manner to the connecting line (12) of the refrigerant circulation system (1). The device (7.1a) and the connection line (12) are sealed by a sealing member (21) having a filter function. In this case, the oil passes through a filter element, in particular a sieve, formed in such a way that it is integrated in the interior of the sealing member 21, in order to suppress impurities of the oil, such as chips or other similar substances. The filter element may also be formed in a manner that is integrated directly into the inlet 16.

The oil is introduced into the oil storage device 7.1a and then stored in the storage volume 15 surrounded by the wall of the device 7.1a. The storage volume 15 has two openings for oil passage with the inlet 16 and the outlet 17. The outlet 17 may be closed by a float 18a in the direction of the connecting line 12. The float 18a is disposed in such a manner that it is supported by a guide member 19 formed of a guide pin. The guide member 19 preferably has a spring member 20, in which case the resilient force acts on the float 18a in a manner that closes the outlet 17. The guide member 19 is used to keep the position of the float 18a constant for closing the outlet 17, especially in the operating states in which oil does not collect in the storage volume 15. [ The float 18a closes the mixing point 8 and the connection line 12 communicating therewith to the compressor 2, especially when the oil filling level is low inside the oil storage device 7.1a, The refrigerant bypassing from the high pressure side of the refrigerant circulation system 1 through the device 7.1a to the low pressure side of the refrigerant circulation system 1 can be prevented.

When the float 18a is closed, the oil flowing through the inlet 16 is collected in the storage volume 15. The float 18a floats on the oil and is urged upwardly against the force provided by the spring member 20 along the guide member 19. In this way, The float 18a opens the oil outlet 17 and at least a portion of the oil collected in the device 7.1a flows through the connecting line 12, the mixing point 8 and the connecting line 10 into the compressor 2). When the charge level of the oil is too low, the float 18a is pressed down by the spring member 20 in such a manner as to close the outlet 17.

The oil storage device (7.1a), which is specially formed as a connection block, is screwed into the adjacent parts of the refrigerant circulation system (1). To ensure accurate and secure assembly of the connection block between the connection lines 12, the connection block has locking means in the form of a cord pin. Adjacent components of the refrigerant circulation system 1 are screwed to each other after the adjacent connection lines 12 and the connection block are fixed by pin insertion. Threaded bores 14 are formed on both sides of the connecting block for threaded engagement of the connecting lines 12 with the connecting block.

The formation of the device 7 in relation to the locking means 13 and the threaded bores 14 is the same in all of the following embodiments.

3 shows an oil storage device 7.2a including a spherical float 18a having a guide member 19 and a spring member 20 and a filter member 22. In the oil storage device 7.2a shown in Fig. In this case, the spring member 20 is formed of a cylindrical coil spring.

Thus, the embodiment of the device 7.2a of FIG. 3 basically corresponds to the embodiment of the device 7.1a according to FIG. The difference from the device 7.1a of FIG. 2 lies in the arrangement and formation of the filter element 22. In this case, the filter element 22 is preferably formed in a sieve and arranged in such a way that it is integrated into the inlet 16. The connection line 12 and the device 7.2a are connected to each other in a fluid-tight manner through a seal not shown in the figure. The seal does not need to have a filter function.

Figure 4 shows an oil reservoir 7.2b including a frusto-shaped float 18b and a filter element 22 having a guide member 19 and a spring member 20. The spring member 20 is formed of a cylindrical coil spring.

Thus, the embodiment of the apparatus 7.2b of FIG. 4 basically corresponds to the embodiment of the apparatus 7.2a according to FIG. The difference from the device 7.2a of FIG. 3 lies in the formation of the float 18b. The frustum-shaped float 18b has a conical cross-section with a base surface and a cover surface, in which case the base surface and the cover surface are arranged parallel to each other. The side of the obliquely arranged float 18b abuts the wall forming the outlet 17 when the device 7.2b is closed. The elastic force provided by the spring member 20 acts on the base surface of the float 18b and presses the side surface of the float 18b against the wall of the outlet 17 in the closed state.

5 shows an oil storage device 7.2a 'including a spherical float 18a having a spring member 20' and a filter member 22. The oil storage device 7.2a '

Thus, the embodiment of the apparatus 7.2a 'of FIG. 5 basically corresponds to the embodiment of the apparatus 7.2a according to FIG. The difference from the device 7.2a of FIG. 3 lies in the formation of a spring member 20 'formed of a spring steel sheet instead of a cylindrical coil spring. Since the spring member 20 'is formed of a spring steel sheet, the arrangement of the guide member 19 for the float 18a can be omitted because the spring steel sheet is not only the function of the spring member 20' This is because the function of the guide member 19 is also satisfied. Thus, the embodiment of the device 7.2a 'preferably has fewer parts than the embodiment of the device 7.2a of Fig. 3.

6 , An oil reservoir 7.2b 'including a truncated float 18b with a spring member 20' and a filter member 22 is shown.

 Thus, the embodiment of the device 7.2b 'of FIG. 6 basically corresponds to the embodiment of the device 7.2b according to FIG. The difference from the device 7.2b of FIG. 4 is the formation of a spring member 20 'which is likewise formed of a spring steel sheet instead of a cylindrical coil spring. Since the spring member 20 'is formed of a spring steel sheet, the arrangement of the guide member 19 for the float 18b can be omitted in the present embodiment because the spring steel sheet 20' As well as the function of the guide member 19. Thus, the embodiment of the device 7.2b 'preferably has fewer parts than the embodiment of the device 7.2b of FIG.

All embodiments of the oil storage device 7 are formed to the size required to provide an adequate retention volume 15 for the oil while minimizing the external dimensions for minimizing the installation space, It is effective in forming a size for optimally utilizing the installation space in the case of the present invention. The floats 18a, 18b are preferably formed of metal, but can be made of any other material that is resistant to oil as well as to refrigerant. The floats 18a and 18b may be formed in a spherical shape or a conical shape or a frustum shape as well as any other shape for surely closing the outlet 17. The spring members 20 and 20 'may be formed not only by a cylindrical coil spring or a spring steel sheet, but also in any other spring form. The spring members 20 and 20 'are preferably formed of metal such as the guide member 19, but may be formed of any other material resistant to oil as well as refrigerant. The components of the filter member 22 or of the sealing member 21 meeting the filter function are also preferably made of metal, but can be made of any other material that is resistant to oil as well as refrigerant. The device 7 is formed from a metal such as aluminum, steel or stainless steel as a connecting block.

: 오일1: Refrigerant circulation system
2: Compressor
3: Oil separator
4: Heat exchanger
5: Expansion member
6: Heat exchanger
7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b'
8: Mixing point
10: Refrigerant-oil mixture connection line
11: Refrigerant connection line
12: Oil connection line
13: Locking means
14: thread bore
15: Storage volume
16: Inlet
17: Outlet
18a and 18b: float
19: Float guide member
20, 20 ': spring member
21: Sealing member with filter function
22: Filter element
G: Refrigerant-oil mixture
KM: Refrigerant

: oil

Claims (10)

As an oil storage device (7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b') in a refrigerant circulation system (1)
- the refrigerant circulation system (1) has a compressor (2), an oil separator (3) in the flow direction and a heat exchanger for cooling and / or liquefying the refrigerant, and
The device (7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b') comprises an oil retention volume (15) having an inlet (16) and an outlet (17) And wherein the flow path extends from the oil separator (3) to a mix point (8) disposed in front of the compressor in the flow direction. An oil storage device (7, 7.1a, 7.2a, 7.2b, 7.2a ', and 7.2b'
Characterized in that the device (7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b') has an adjustable cross section of the outlet (17) for regulating the mass flow of the recirculated oil, ) Can be varied and closed by variable placement of the float (18a, 18b) between the wall and the float (18a, 18b). The method according to claim 1,
Characterized in that the float (18a) is formed in a circular sphere shape and the spherical surface of the float (18a) is in contact with the wall with the outlet (17) closed. a, 7.2a '). The method according to claim 1,
The float 18b is formed in a truncated cone shape and the float 18b has a base surface, a cover surface and a side surface, and the side surface of the float 18b is in contact with the wall 18b with the outlet 17 closed (7.2b, 7.2b '). 4. The method according to any one of claims 1 to 3,
Characterized in that the floats are disposed in such a manner that the floats are supported by a guide member and a spring member and the spring member is formed by a cylindrical coil spring. Oil storage (7, 7.1a, 7.2a, 7.2b). 4. The method according to any one of claims 1 to 3,
Characterized in that the float (18a, 18b) is arranged in such a way that it is supported by a spring member (20 ') and the spring member (20') is formed of a spring steel sheet (7.2a ', 7.2b'). 4. The method according to any one of claims 1 to 3,
A sealing member 21 having a filter function is disposed between the connection line 12 and the inlet 16 of the refrigerant circulation system 1 and is formed in such a manner that a filter member is incorporated in the sealing member 21 , Whereby the device (7, 7.1a) is connected in fluid sealing manner with the connection line (12) and the oil flows into the storage volume (15) through the sealing member (21) (7, 7.1a). 4. The method according to any one of claims 1 to 3,
Characterized in that a filter element (22) is arranged in the region of the inlet (16) so that oil flows into the storage volume (15) through the filter element (22) b, 7.2a ', 7.2b'). 4. The method according to any one of claims 1 to 3,
The device 7, 7.1a, 7.2a, 7.2b, 7.2a ', 7.2b is formed as a connecting block between the components of the refrigerant circulation system 1, Characterized in that it is threadedly engaged with adjacent parts of the refrigerant circulation system (1). 9. The method of claim 8,
The connecting block has locking means in the form of a code pin so that the connecting block can move the pin as a step of assembling the refrigerant circulation system 1 with the adjacent parts of the refrigerant circulation system 1 And is then locked. 9. The method of claim 8,
Characterized in that the connecting block has threaded bores (14) for threaded engagement with adjacent parts of the refrigerant circulation system (1).

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