KR20110013444A - Discharge valve arrangement for a hermetic compressor - Google Patents

Abstract

The device is for example applied to a hermetic compressor for use in household refrigeration systems, which device closes the end of the compression cylinder 1 and has inlets and outlets 11, 12 provided in the compression cylinder 1. A valve plate 10, the inlet 11 occupying an annular sector external to the axial projection of the outlet 12 and closed by a soft intake vane 21 having a flexing intermediate 23. . The valve plate 10 has a plurality of outlets 12 distributed in at least one of the areas formed outside and inside the contour of the soft suction vane 21, and inside the contour of the soft suction vane 21. Each outlet 12 of is aligned in line with the respective through holes 25 provided in the bending intermediate portion 23 in the axial direction.

Description

Discharge valve device for hermetic compressor {DISCHARGE VALVE ARRANGEMENT FOR A HERMETIC COMPRESSOR}

The present invention relates to a discharge valve arrangement for a hermetic compressor for use in a cooling device, for example a domestic cooling system such as a refrigerator, a freezer, a cold water machine, or even an electronic device using a compact compressor having a reduced size. The invention applies in particular to a hermetic compressor comprising a cylinder block which forms a compression cylinder having an end closed by a valve plate with an inlet and an outlet provided in the inner contour of the axial protection of the compression cylinder. At least one intake port occupies an annular sector and is closed by an intake valve comprising a mounting end attached to the valve plate, a flexure intermediate portion and a soft intake vane operatively associated with the intake port.

The energy efficiency of a small hermetic refrigeration compressor is mainly due to the good performance of the intake and discharge systems (including intake and discharge ports, respective intake and discharge valves, and damping filters) of the compressor, in particular the gas flow. It depends on the performance of the valve of the system in controlling. Some of the energy loss in these compressors is caused by load losses in the intake and discharge systems. Thus, a solution aimed at reducing this loss directly affects the increase in compressor efficiency. Optimizations that are usually made consist of reducing losses by increasing the gas passage area as well as reducing the rigidity of the valve. The major constraints imposed on the gas are found at the inlet and outlet. Known solutions commonly applied to commercial refrigeration and air conditioning use one or more orifices for the intake or exhaust of gases. By using multiple openings, the gas passage area can be increased without increasing the stiffness and final instability in the valve system. Within this concept a number of openings may be retrofitted to serve applications that efficiently control the refrigeration capacity rather than being obtained with only one opening. In general, known compressor applications using multiple outlets are aimed at commercial refrigeration applications with high mass flow rates, such as the automotive or air conditioning industry, which typically use large diameter pistons. In residential applications, structures with multiple openings are rarely used, mainly because the dead volume increases significantly, further detrimental to the capacity and efficiency in this application. In addition, in housing applications the diameter of the piston is small and therefore requires less space to position the valve system. To facilitate the production process, the inlet and outlet ports usually have a circular cross section and are generally constructed in valve plates made of steel. In most cases and mainly when the hermetic compressor has a small size, in addition to the inlet valve and inlet and outlet geometry, there is a need to separate the already compressed gas from the gas at the suction pressure (this requirement is mainly met by the cylinder cover). Since the outlet port is located eccentrically with respect to the axis of the center of the compression cylinder which is very close to the wall of the cylinder, the inlet port can also be provided in the axial projection of the inner contour of the compression cylinder, so that a certain minimum space relative to the outlet port Will be maintained.

The co-continuity solution disclosed in the applicant's documents US2004 / 0228742 (EP1301711) and US2006 / 0096647 overcomes the deficiencies regarding the positioning of the concentric outlets in the axis of the center of the compression cylinder. However, these solutions still exhibit the inconvenience of low performance caused by load loss in the discharge system, mainly in applications with low condensation pressures, applications of refrigeration with low mass flow rates, and in certain solutions using the refrigeration fluid RβOOa.

Accordingly, an object of the present invention is to provide a hermetic seal which can minimize the load loss and improve the performance of the compressor independently of the type of refrigeration fluid used and used in refrigeration systems designed to operate, for example, in low mass flow home applications. It is to provide a discharge valve device for a compressor.

Another object of the present invention is to reduce the size of the diameter of the piston without damaging the effective gas flow range at the inlet and without damaging the minimum spacing of the inlet to minimize the pressure difference existing in the known conventional structure, It is to provide a device as listed above, which is particularly applicable to a structure that reduces energy loss and load loss during operation.

It is a particular object of the present invention to provide a suction port provided on the inside of the axial protrusion of the inner contour of the compression cylinder and on the outside of the contour of the discharge port so as to maintain a certain minimum distance from the discharge port. US2006 / 022742 (EP1301711) and US2006 / 0096647 It is to provide an apparatus as enumerated above for the construction of an intake system of the type described in.

The above and other objects include a cylinder block forming a compression cylinder; A valve plate closing the end of the compression cylinder and having an inlet and outlet provided in the inner contour of the axial projection of the compression cylinder, the at least one inlet being an axial direction of the outlet being closed by a discharge valve comprising a soft release vane. Occupies an annular sector external to the protrusion, the inlet including a valve plate adapted to be closed by a suction valve comprising a soft suction vane, the soft suction vane having a mounting end attached to the valve plate; Bending middle part; And a discharge valve arrangement for a hermetic compressor for use in a refrigeration system, adapted to provide a sealed end operatively associated with the inlet. According to the present invention, the valve plate has a plurality of outlets distributed in at least one of the regions formed outside and inside the contour of the flexible suction vane, the outlets provided inside the contour of the flexible suction vane are flexible. It is aligned in the axial direction with each of the holes provided in the bending intermediate portion of the suction vane.

According to a particular aspect of the present invention, the bending intermediate portion of the flexible suction vane has a through hole. In order to ensure that the same flow restriction is applied to the central opening during the discharge operation of the compressor, a central outlet is provided which is aligned with the axis of the compression cylinder and the axial protrusion is inside the aperture, and at least the other outlet The directional protrusion is arranged inside the axial protrusion of the compression cylinder. In a modification of the structural aspect of the present invention, the flexural middle portion of the flexible intake can have a single outlet having an axial protrusion provided in the opening.

According to another aspect of the present invention, the flexural intermediate portion of the soft suction vane has a through hole, and any discharge opening whose axial protrusion is inside the contour of the soft suction vane has an axial protrusion provided inside the through hole.

According to another aspect of the invention, the soft suction vanes comprise a plurality of apertures, each having an axial protrusion of each outlet therein.

In this structural modification, the present solution provides at least another outlet outside the contour of the suction vane.

According to another aspect of the invention, a plurality of soft release vanes are provided, each soft release vane providing a respective sealing end for selectively closing at least one outlet and a respective mounting end attached to the valve plate. The mounting end of the soft release vane is formed in a single common piece from which the sealed end of the soft release vane protrudes.

According to another aspect of the invention, the flexible suction vane comprises a plurality of apertures, each having an axial protrusion of each outlet provided in the valve plate therein.

In home applications where the condensation temperature is low and operates with the refrigerant fluid RβOOa, the present invention having a plurality of discharge holes as described herein provides an advantage because the load loss in the discharge system compensates for the adverse effects of use. In addition, a compressor operating with refrigerant fluid RβOOa uses a piston having a larger diameter than that operating with refrigerant fluid R34a to create adequate space to accommodate multiple openings.

The invention is described below with reference to the accompanying drawings, in which:
1 shows a soft suction vane, suction hole and discharge hole constructed in accordance with the prior art, schematically showing a plan view of the valve plate when viewed from the compression cylinder side;
2 shows the inlet and discharge of the invention wherein the axial protrusion of one of the outlets is disposed inside the through hole provided in the soft suction vane and the axial protrusion of the other discharge hole is disposed outside the contour of the soft suction vane. A plan view of the valve plate showing the device of the sphere is schematically shown as shown in FIG. 1;
FIG. 3 shows the flexible suction vane symmetrically with an opening in which the axial protrusion of one of the outlets is provided in the through-hole provided in the soft suction vane and the axial protrusions of the other two outlets are in the opening with the protrusion in the inside of the hole. A top view of a valve plate, which is arranged outside of the contour, wherein the outlet port represents a device of the inlet port and the outlet port of the present invention having the same cross section as schematically shown in FIG. 2;
4 schematically shows a top view of a valve plate showing the device of the inlet and outlet of the invention having outlets with different cross sections, as shown in FIG. 3;
5 schematically shows a second device of the inlet and outlet of the present invention in which the axial protrusion of each outlet is disposed inside each of the apertures provided in the soft suction vane;
6 schematically shows a third device of the inlet and outlet of the present invention in which the axial protrusion of each outlet is disposed outside of the contour of the soft suction vane;
FIG. 7 schematically shows the structural modification of the third device of the inlet and outlet shown in FIG. 6 in which the axial protrusion of each outlet is arranged outside of the contour of the soft inlet vane;
FIG. 8 schematically shows another structural variant of the third device of the inlet and outlet shown in FIG. 6 in which the outlets have different cross sections;
9 schematically shows a perspective view of the valve plate when viewed from the opposite side of the compression cylinder, each showing the structural form of the discharge valve with soft discharge vanes associated with the discharge port;
10 schematically shows a perspective view of the valve plate shown in FIG. 9 when the valve system is removed and viewed from the opposite side of the compression cylinder.

Description of the illustrated embodiment

The present invention is, for example, a hermetic compressor of a refrigerating system applied to a domestic refrigerating system, which has a compression cylinder (2) for accommodating therein a reciprocating piston (2) which sucks and compresses refrigerant gas when driven by an electric motor of a motor compressor assembly. A closed compressor including a motor compressor assembly (not shown) including a cylinder block forming (1) inside a casing (not shown) will be described. In these structures, the compression cylinder 1 and the reciprocating piston 2 are reduced in diameter to provide a suction valve and a discharge valve to limit the space for alignment. The compression cylinder 1 is closed by a valve plate 10 attached to the cylinder block and has an end having an inlet 11 and an outlet 12. A compression chamber (not shown) is formed inside the compression cylinder 1 between the upper end of the reciprocating piston 2 and the valve plate 10, which is provided at each intake valve 20 and discharge valve 30. This forms a compression chamber (not shown) that remains in selective fluid communication with the suction side and discharge side (not shown) of the refrigerating compressor through selective opening and closing of the inlet 11 and outlet. The intake valve 20 and the discharge valve 30 are configured in the form of soft vanes as described above.

According to the conventional structure shown in FIG. 1, the valve plate 10 has a discharge port 12 inside the axial protrusion 40 of the inner contour of the compression cylinder 1 and the axial protrusion 40. Inlet 11 is provided inside and outside of the contour of outlet 12, which has a specified minimum radial spacing calculated to form a wall thickness capable of adequately pressing a sealing joint (not shown). This is to avoid from leaking from the high pressure side to the low pressure side by holding from (12). Although not shown, it should be understood that the inlet 11 and outlet 12 may have respective axial protrusions centered or substantially centered relative to the axial protrusion 40 of the compression cylinder 1.

The inlet 11 is arranged to be outside of the axial protrusion of any outlet 12. In the prior art structure shown in FIG. 1, the outlet 12 is circular and concentric with the inner contour of the compression cylinder 1 and the inlet 11 is the inner contour of the compression cylinder 1 and the outlet 12. At least one of which is in the form of a substantially concentric annular sector. This structure is disclosed in patent EP1301711.

In the structure described, the valve plate 10 fixes the suction valve 20 in the form of a flexible suction vane 21 on the side facing the inside of the compression cylinder 1, which is the valve plate 10. A mounting end 22 attached to the; Bending intermediate portion 23; And a sealing end 24 operatively associated with the inlet 11 and capable of being displaced by elastic deformation between a closed valve position for blocking the inlet 11 and an open valve position for releasing the inlet 11. As shown, the flexible suction vane 21 has at least a sealing end 24 and a bending intermediate portion 23 which are located in the axial projection 40 of the inner contour of the compression cylinder 1. In the prior art structure shown in FIG. 1, the soft suction vane 21 provides a through hole 25 in its bending intermediate portion 23, the center of the compression cylinder 1 being concentric with the axis of the compression cylinder 1. An axial protrusion of the contour of the outlet 12 is located.

The importance of centering the outlet 12 is in the fact that the compressed gas release process takes place while the piston is very close to the top dead center of the mechanism. In this case, by the centralization of the discharge port 12, the pressure difference along the compression cylinder 1 is reduced during the period in which the compressed gas is discharged through the discharge valve 30. The reduction of the pressure difference ultimately leads directly to the reduction of energy loss during the compression process, providing greater energy efficiency to the compressor.

However, in some of the structures described and shown, the central outlet 12 is provided concentrically with respect to the axis of the compression cylinder 1, while the outlet 12 is provided out of alignment with the axis. It is to be understood that this arrangement is not mandatory, as it may be. According to the invention, the valve plate 10 has a plurality of outlets 12 distributed in at least one of the areas formed outside and inside the contour of the soft suction vane 21, Each outlet 12 provided inside the contour is aligned in line with each through hole 25 provided in the bending intermediate portion 23 of the soft suction vane 21 in the axial direction.

The apparatus of the present invention further comprises a release valve 30 formed of a plurality of soft release vanes 31, each release valve operatively associated with at least one outlet 12, the valve plate 10 A respective sealing end 34 which selectively closes each mounting end 32, bending intermediate region 33, and at least one outlet 12 to be attached thereto.

In the first embodiment of the present invention with respect to the discharge valve 30 shown in FIG. 9, the mounting end 32 of the soft release vane 31 is formed on one common piece, from which the respective flexible pieces The bending intermediate portion 33 and the sealing end 34 of the discharge vane 31 protrude. In another structure (not shown), the discharge valve is disposed in the mounting end 32, the bending intermediate region 33, and in a straight line with each other so as to be perpendicular to the axis of the soft release vane 31. It provides a soft release vane (31) with a sealing end (34) for closing it. In another method of practicing the invention, also not shown, each soft release vane 31 may form a release valve independent of the other discharge valve, with each soft release vane 31 having a respective mounting end 32. Is attached to the valve plate 10. In either of these structures, the sealing end 34 of each soft release vane 31 can selectively close one or more outlets 12.

In the method of the present invention in which a single through hole 25 is provided in the bending intermediate portion 23 of the soft suction vane 21, at least a part of the axial protrusion of the discharge port 12 is formed inside the through hole 25. Can be included. In the structural variant of the invention, the axial protrusion of any outlet 12 in which the axial protrusion is inside the contour of the soft suction vane 21 is contained within the through hole 25.

In the structure shown in Fig. 2, the device of the present invention comprises a single outlet 12 having an axial protrusion provided in the interior of the through hole 25, wherein each of the axial protrusions has a soft suction vane ( It further comprises at least another discharge port 12 in an eccentric state on the outside of the contour of the bend 23 of 21. In this structure, the ejection opening 12 in which the axial projection is inside the through hole 25 is provided to be centered and / or aligned in line with the axis of the compression cylinder 1, for example. With regard to the dimensions of the outlet 12, they can be formed to provide the same or similar flow restriction conditions during the discharge operation of the compressor. However, flow restriction conditions along the outlets 12 can be independent for each outlet.

3 and 4, there is shown a single outlet 12 having an axial protrusion provided inside the aperture 25 and two other outlets 12 outside the aperture. Each of the two outlets has respective axial protrusions located externally eccentric with respect to the contour of the flexure 23 of the flexible suction vane 21, the other two outlets being about the axis of the compression cylinder 1. They are specially arranged symmetrically and at right angles to the axis of the flexible suction vane 21. In this structural variant, the other outlet 12 provided in the valve plate 10 will be outside of the contour of the soft suction vane 21. In a method of making this non-mandatory structural choice, the outlets 12 are arranged in the valve plate 10 so that each outlet 12 is the same as that exerted by the soft release vanes 31 during its opening operation. Restrict flow rate.

In the structural selection shown here, the other two outlets 12 are arranged in an alignment that includes a central outlet 12, the alignment being perpendicular to the axis of the soft release vane 31, wherein the two The other outlets 12 are symmetrical about the axis. Specifically, the central outlet 12 and the other two outlets 12 exhibit the same cross-sectional area, but this structure is not necessarily mandatory. While the depicted structure represents an outlet 12 having a circular contour, it is to be understood that other configurations are possible that exhibit elliptical contours or other desirable shapes within the concepts presented herein. Each outlet 12 may be optimized in an independent form relative to other outlets, which optimization is an independent dimension of each outlet 12 that is calculated according to the flow restriction conditions that the outlet 12 must provide. Determined by The discharge port 12 may be arranged in an alignment state perpendicular to or parallel to the axis of the flexible suction vane 21 inside or outside the through hole 25 in the flexible suction vane 21. It does or does not include a central outlet 12 that is concentric with respect to axis 1).

The outlet openings 12 of the present invention may have the same shape and dimensions as each flexible release vane 31 is moved, for example, in order to keep similar flow restriction conditions to a minimum. Possible variations on the distribution of the outlets 12 are made for each project according to the desired result. In structural choice, all outlets 12 exhibit a minimum flow rate limit during the compressor discharge operation, or represent flow rate conditions calculated independently for each outlet 12.

In the structure shown in FIG. 9, the outlet port 12 is selectively closed by a discharge valve 30 comprising three soft release vanes 31, each soft outlet vane having a respective outlet 12. Each sealing end 34 operatively associated with the soft release vane 31 has a mounting end 32 connected to each other in a single piece attached to the valve plate 10. In another form of distribution (not shown), the outlet 12 is concentric and spaced around the center outlet 12 to maintain the same flow restriction conditions applied to the center outlet 12 during the discharge operation of the compressor. Can be distributed in a state. In a structure having a central outlet 12, in order to maintain the same flow restriction conditions during the discharge operation of the compressor, the outlet 12 is characterized by at least one of the characteristics of the cross-sectional area and the distance to the central outlet 12. Indicates a variant.

In the absence of a central outlet 12, the outlet 12 is characterized by at least one of the characteristics of the cross-sectional area and the diameter for the movement of the male portion of the discharge valve 30 in order to maintain the same flow restriction conditions during the discharge operation of the compressor. Indicates a variant. In another method of practicing the invention shown in FIG. 5, the soft suction vanes 21 comprise a plurality of openings 25, each opening having an axial protrusion of each outlet 12 therein. do. In this structure, and as already described with respect to the structure shown in FIGS. 2 to 4, the outlet 12 is provided for example to be centrally arranged with respect to the axis of the compression cylinder 1 and in particular aligned in a straight line. At least the other outlet 21 has its axial protrusion inside the contour of the soft suction vane 21. In the structure shown in FIG. 5, the flexible suction vane 21 has three through holes 25, each of which is aligned with the axial projection of each outlet 12, the through hole 25. Are aligned linearly with each other and at right angles to the axis of the soft suction vanes 21. As already described above, the outlets 12 are dimensioned with respect to each other and with respect to the flexible suction vanes 21 such that each outlet 12 receives the same flow restriction imposed by the soft release vanes 31 during its opening operation. And position, but this alignment is not mandatory.

 In the embodiment shown in FIG. 5, one of the through holes 25 is provided in alignment with the axis of the soft suction vane 21. In this structure shown in FIG. 5, the other outlets 12 all show the same cross-sectional area, but this coincidence is not mandatory as described in the embodiment shown in FIGS. This structure also provides at least another outlet 12 having an axial protrusion outside the contour of the soft intake vane 21, all of which are opened by the soft release vane 31 during opening operation thereof. It should be understood that they may be aligned to receive the same flow restrictions imposed.

In these constructions, the outlet opening 12 comprises a central outlet opening 12 and is arranged in an alignment perpendicular to the axis of the soft release vane 31, with outlets other than the central outlet opening 12 being the axis. And symmetrical with respect to the central outlet 12.

Also in this structure, the discharge valve 30 may be of a type including respective soft discharge vanes 31 for each discharge port 12, and each soft discharge vane 31 may also be a soft discharge vane 31. It may be operatively associated with a plurality of outlets 12 aligned in a straight line with respect to the axis of. In the arrangement shown in FIGS. 6 to 8, the device of the present invention comprises only an outlet 12 having an axial protrusion located outside of the contour of the soft suction vane 21, one of the outlets 12. Is arranged centrally and the other outlets 12 are arranged to undergo the same flow restriction conditions imposed by the soft release vanes 31 during their opening operation. Specifically, the other outlet 12 comprises a central outlet 12 and is arranged in an alignment perpendicular to the axis of the soft release vane 31. The discharge port 12 is symmetrical about the axis. In this structure, the central outlet 12 and the other outlet 12 exhibit the same cross-sectional area. 9 and 10 show the structural form of the valve plate 10 provided in the body portion of the valve plate 10 lowered from the front face of the discharge port as opposed to the discharge port 12 facing towards the compression cylinder 1. The recess is adapted to receive a soft release vane 31 mounted to the valve plate 10.

In the structure using the intake valve as described above, the apparatus of the present invention provides a plurality of outlets in a hermetic compressor of a domestic refrigeration system to prevent gas flow from the interior of the compression cylinder 1 to the plurality of outlets 12. By making it easier, the efficiency of the refrigeration compressor is further improved and the dead volume is reduced. Although many of the outlets 12 in the interior of the through hole 25 are not exactly centered with respect to the axis of the compression cylinder 1, there are a number of outlets 12 for the structure of the intake valve 20 of the type already described herein. Discharge efficiency can be significantly improved if multiple outlets 12 can be provided in different alignments and in different cross-sections with respect to the hermetic refrigerator. Known concepts, in which the piston uses an axial protrusion on the top surface to cooperate with the outlet 12 during the final compression stroke of the piston to reduce the use in the compression chamber, also can be incorporated into the invention only by incorporating into the top surface of the reciprocating piston 2. The same applies, and it should be understood that the protrusions are properly positioned to cooperate with each outlet 12. The physical positioning of the protrusions must, of course, depend on the relative positioning of the outlet opening 12 of the valve plate 10, while the shape of the protrusions and each outlet opening 12 can only represent one of the known patterns. According to the positioning of the projections in the contour of the compression chamber, or vice versa, according to the positioning of the projections in the compression chamber to reduce its use without compromising the discharge flow of compressed refrigerant gas inside the compression chamber. It can represent different form patterns. Providing multiple outlets 12 of reduced diameter compared to the diameter of a single outlet 12 as in the prior art further optimizes the discharge valve 30 compared to the use of a single outlet 12. The use of multiple outlets 12 also allows smaller thicknesses to be used for the discharge valve 30 (because the smaller outlet 12 imposes a small stress on the valve), resulting in a discharge valve ( The degree of freedom for optimizing the stiffness and natural frequency of the soft release vane 31 of 30) is greater. In addition, since the ejection opening 12 is smaller in size than the single ejection opening 12 of the prior art, the force required to open the ejection valve 30 is small to smooth the opening. In addition, there are a number of outlets 12 so that a smaller maximum opening of the outlet valve 30 can be used, which means that the outlet 12 is larger than the diameter of the outlet 12 versus the outlet valve 30. This is because the gas flow rate range increases with the opening height. The larger the number of outlets 12, the smaller the maximum opening of the outlet valve 30 required for good gas flow, since the total gas flow range is proportional to the number of outlets 12 multiplied by their diameter. . Thus, the need for smaller openings for the release valve (as a function of the larger number of outlets 12) is that a smaller force is needed to open the release valve 30 (due to the small diameter of the outlet 12). By incorporating this, the energy seated in the recess provided in the body portion of the valve plate 10 and acting as an end stroke stop (not shown) will be reduced, resulting in advantages such as noise reduction and primarily reliability, because the impact force is reduced. Because it becomes. While only one exemplary embodiment of the invention has been shown herein, it is to be understood that modifications may be made in the form and arrangement of components without departing from the concepts defined in the claims that accompany the specification.

Claims (30)

A cylinder block forming a compression cylinder 1; A valve plate (10) having an inlet port (11) and an outlet port (12) provided in the inner contour of the axial protrusion (40) of the compression cylinder (1) and closing the end of the compression cylinder (1), wherein at least one The inlet 11 occupies an annular sector external to the axial projection of the outlet 12 closed by a release valve 30 comprising a soft release vane 31, the inlet 11 being a soft inlet vane. A valve plate (10) adapted to be closed by a suction valve (20) comprising a (21), said flexible suction vane (21) having a mounting end (22) attached to the valve plate (10); Bending intermediate portion 23; And a discharge valve arrangement for a hermetic compressor for use in a refrigeration system, the sealing end 24 being operatively associated with the inlet 11.
The valve plate 10 has a plurality of outlets 12 distributed in at least one of the regions formed outside and inside the contour of the flexible suction vane 21, the contour of the flexible suction vane 21. The discharge port (12) provided therein is characterized in that it is aligned in the axial direction with each of the through holes (25) provided in the bending intermediate portion (23) of the soft suction vanes (21). 2. The bending intermediate portion 23 of the flexible suction vane 21 is provided with a through hole 25, wherein the axial projection is any discharge opening in the interior of the contour of the flexible suction vane 21. 12) is characterized in that it has an axial protrusion provided in the through hole (25). 3. Device according to claim 2, characterized in that it comprises a central outlet (12) having an axial protrusion inside the through hole (25). 4. Device according to claim 3, characterized in that the central outlet (12) is aligned with the axis of the compression cylinder (1). The device according to any one of claims 2, 3 and 4, characterized in that it comprises a single outlet (12) having an axial protrusion provided in the through hole (25). 6. Device according to claim 5, characterized in that it comprises at least another outlet (12) with an axial protrusion inside the contour of the soft suction vane (21). 3. The device according to claim 2, wherein at least some of the discharge holes (12) are arranged to be subjected to the same flow restriction imposed by the soft release vanes (31) during their opening operation. 6. The soft discharge according to any one of claims 3, 4 and 5, arranged in alignment with an axial protrusion outside the contour of the soft suction vane 21 and having a central outlet 12. And at least two different outlets (12) perpendicular to the axis of the vanes (31), said two outlets (12) being symmetrical about the axis of the compression cylinder (1). The device of claim 1, wherein at least some of the outlets (12) of the plurality of outlets (12) exhibit the same cross-sectional area. 2. Device according to claim 1, characterized in that the outlets (12) of the plurality of outlets (12) exhibit different cross sections. 2. Device according to claim 1, characterized in that the soft suction vanes (21) comprise a plurality of through holes (25), each having a axial protrusion of each outlet (12) therein. 12. The device according to claim 11, comprising a central outlet (12). 13. The device according to claim 12, wherein the central outlet (12) is aligned with the axis of the compression cylinder. 14. An ejection opening (12) according to any one of claims 11, 12 and 13 having an axial protrusion inside the contour of the soft suction vane (21) with respect to the axis of the soft ejection vane (31). Arranged at a right angle, the outlet (12) is characterized in that it is symmetrical about the axis of the compression cylinder (1). 15. The device according to claim 14, wherein at least a portion of the discharge port (12) is arranged to be subjected to the same flow restriction imposed by the soft discharge vanes (31) during its opening operation. 12. An apparatus according to claim 11, wherein at least some of the outlets (12) of the plurality of outlets (12) exhibit the same cross-sectional area. 12. The device according to claim 11, wherein the outlets (12) of the plurality of outlets (12) exhibit different cross sections. 18. The device according to any one of claims 11 to 17, characterized in that it comprises at least another outlet (21) having an axial protrusion outside of the contour of the soft suction vane (21). 19. The device according to claim 18, wherein the other external outlet (12) is arranged to be subject to the same flow restriction applied to the other outlet (12) by the soft release vanes (31) during its opening operation. 18. The device according to any one of claims 11 to 17, characterized in that it comprises at least two different outlets (12) with axial protrusions outside of the contour of the soft suction vanes (21). 21. The device according to claim 20, wherein the two different outlets (12) are arranged such that during their opening operation all outlets (12) are subjected to the same flow restriction imposed by the soft release vanes (31). 22. The two different chambers (12) according to claim 20 or 21, wherein the two different outlets (12) have a central outlet (12) and are arranged in alignment perpendicular to the axis of the soft release vane (31). The outlet (12) is characterized in that it is symmetrical about the axis. 23. The device according to claim 22, wherein at least some of the outlets (12) of the plurality of outlets (12) exhibit the same cross-sectional area. 23. The device according to claim 22, wherein the outlets (12) of the plurality of outlets (12) exhibit different cross sections. 2. Device according to claim 1, characterized in that it comprises only a discharge opening (12) having an axial protrusion disposed outside of the contour of the soft suction vane (21). Device according to claim 25, characterized in that one of the outlets (12) is aligned in a straight line at the center with respect to the axis of the compression cylinder (1). 27. The device according to claim 26, wherein at least a portion of the discharge port (12) is arranged to be subjected to the same flow restriction imposed by the soft release vanes (31) during its opening operation. 28. The outlet of claim 27 wherein at least some of the outlets 12 are arranged in an alignment that includes a central outlet 12 and are perpendicular to the axis of the soft release vane 31, the outlet 12 being the axis. And the device is symmetrical with respect to the device. 29. The device according to claim 28, wherein some of the outlets (12) exhibit the same cross-sectional area. 30. The device according to claim 29, wherein all the outlets (12) have different cross sections.

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