EP1180214B1 - Axial piston refrigerant compressor - Google Patents

Description

The invention relates to an axial piston refrigerant compressor with at least one piston-cylinder unit, whose cylinders are closed by a valve plate which has at least one pressure valve with a Has outlet opening, with a projection of the piston protrudes into the outlet opening when the piston is in the Located near its top dead center.

DE 195 15 217 A1 discloses a compressor of this type known in which the piston has an asymmetrical projection has that with the outlet opening of the pressure valve interacts. The outlet opening is at the asymmetrical Projection of the piston adjusted.

An axial piston compressor is from patent application DK 898/92 known with a conical piston projection, the one with a conical outlet opening of the pressure valve interacts.

An axial piston compressor is known from US Pat. No. 5,149,254 a depression in the part of the piston face known which is from the outlet opening of the pressure valve extends to the center of the piston face. In the recess a piston projection can be provided which cooperates with the outlet opening.

In these known compressors, the piston projection should the outlet opening at top dead center if possible completely fill in to their "harmful space" avoid, i.e. to also eject the gas contained therein and thereby the efficiency of the compressor to increase.

This is the actual (free) cross-sectional area the outlet opening decreases when the piston approaches its upper point so that the flow resistance rises in the outlet opening. The flow conditions in the outlet opening and around the valve closure element around can cause the pressurized gas Recirculation zones in part of the outlet opening forms. The piston boss can solve the problem enlarge that the distance between the projection and Outlet opening up to a flow restriction has decreased before the protrusion the outlet opening has reached. So the free cross-sectional area of the Exhaust opening must be narrowed considerably before that Pressure valve opens.

The invention has for its object an axial piston refrigerant compressor of the type mentioned at the beginning specify which has an even higher efficiency.

According to the invention this object is achieved in that the outlet opening, the piston projection, the inside the valve plate and the end face of the piston one Flow channel with at least most of it its circumference continuous course of its axial cutting edges limit that the free cross-sectional area of the Flow channel through the smallest cross-sectional area the outlet opening is determined until the Piston reaches a position during its pressure stroke has at least the height of the outlet opening below top dead center lies that during the rest Piston pressure stroke the relative decrease in free Cross-sectional area of the flow channel less than that relative decrease in the volume of the pressure chamber is and that at least 45% of the volume of the outlet opening in the top dead center of the piston filled by the projection are.

In this solution there is a flow channel with minimal flow resistance, less pressure loss in the outlet opening and smaller "harmful space". The maximum outflow speed of the gas is smaller. At the same time, noise reduction is achieved. Overall, the efficiency is higher of the compressor.

It is preferably ensured that the cross-sectional area the outlet opening to the outside of the valve plate decreases that the cross-sectional area of the projection decreases towards its free end and that the Cross-sectional areas of the outlet opening and the projection change in the axial direction so that the free cross-sectional area of the flow channel during the piston movement changes relatively less than that Volume remaining in the cylinder. This ensures that the flow resistance of the flow channel remains at a low level during the flow or mass flow decreases during the piston pressure stroke.

During the pressure stroke of the piston, the flow resistance can of the flow channel through the smallest cross-sectional area the outlet opening to be determined until the free end of the piston projection with the inside of the Valve plate is aligned. This ensures optimal gas flow ensured while the mass flow through the outlet opening is the largest.

In particular, during the pressure stroke of the piston Flow resistance of the flow channel through the smallest cross-sectional area of the outlet opening determined be up to 50% of the height of the piston projection into the outlet opening have penetrated. This makes an optimal one Gas leak reached until the piston speed is significantly reduced and the gas flow decreased Has.

An advantageous embodiment is that a Axial section through the outlet opening of the valve plate and the piston projection has curved cutting edges. Here, the cutting edge of the outlet opening steeper than that of the ledge.

In particular, the compressor according to the invention can do so be designed so that the transitions between the valve plate surface and the exhaust port and transition between the piston face and the projection are continuous, the transition between the outlet opening and valve seat and the transition between projection and piston face are rounded. Thereby can the gas drain during the emptying of the cylinder done almost without vortex formation, the flow resistance is reduced.

The outlet opening can be asymmetrical. This is an advantage if the outlet opening is opposite the center of the cylinder is offset.

Alternatively, the outlet opening can be symmetrical his. This is an advantage if the outlet opening is near the center of the cylinder.

The piston projection can also be asymmetrical his. This allows the lead to be asymmetrical Outlet opening can be adjusted.

If the piston projection is symmetrical, it can be adapted to a symmetrical outlet opening become.

It is also possible to have a symmetrical piston projection with an asymmetrical valve opening, and vice versa, to combine.

Fig. 1

einen vergrößerten Axialschnitt durch einen Teil einer Kolben-Zylinder-Einheit eines bekannten Axialkolben-Kältemittelverdichters im Bereich eines Druckventils,

Fig. 2

einen der Fig. 1 entsprechenden Axialschnitt eines weiteren bekannten Axialkolben-Kältemittelverdichters mit einem stirnseitigen Vorsprung des Kolbens,

Fig. 3

einen der Fig. 1 entsprechenden Axialschnitt einer Kolben-Zylinder-Einheit eines ersten Ausführungsbeispiels eines erfindungsgemäßen Kältemittelverdichters,

Fig. 4

einen Axialschnitt durch eine KolbenZylinder-Einheit eines gegenüber dem Ausführungsbeispiel nach Fig. 3 etwas abgewandelten Ausführungsbeispiels eines erfindungsgemäßen Kältemittelverdichters,

Fig. 5

ebenfalls einen den vorhergehenden Figuren entsprechenden Axialschnitt eines Teils einer Kolben-Zylinder-Einheit eines dritten Ausführungsbeispiels eines erfindungsgemäßen Kältemittelverdichters,

Fig. 6

ebenfalls einen den vorhergehenden Figuren entsprechenden Axialschnitt eines Teils einer Kolben-Zylinder-Einheit eines vierten Ausführungsbeispiels eines erfindungsgemäßen Kältemittelverdichters.

Fig. 7

einen der Fig. 4 entsprechenden Axialschnitt einer Kolben-Zylinder-Einheit zur Verdeutlichung der Bestimmung der freien Querschnittsfläche des Durchflusskanals.

Fig. 8

einen der Fig. 3 entsprechenden Axialschnitt einer Kolben-Zylinder-Einheit mit zwei unterschiedlichen Kolbenpositionen.

The invention is described below with reference to the accompanying drawings of preferred embodiments. Show it:

Fig. 1

2 shows an enlarged axial section through part of a piston-cylinder unit of a known axial piston refrigerant compressor in the region of a pressure valve,

Fig. 2

1 shows an axial section corresponding to FIG. 1 of another known axial piston refrigerant compressor with an end projection of the piston,

Fig. 3

1 corresponding axial section of a piston-cylinder unit of a first embodiment of a refrigerant compressor according to the invention,

Fig. 4

3 shows an axial section through a piston-cylinder unit of an embodiment of a refrigerant compressor according to the invention, somewhat modified compared to the embodiment according to FIG. 3,

Fig. 5

likewise an axial section corresponding to the previous figures of part of a piston-cylinder unit of a third exemplary embodiment of a refrigerant compressor according to the invention,

Fig. 6

likewise an axial section corresponding to the previous figures of part of a piston-cylinder unit of a fourth exemplary embodiment of a refrigerant compressor according to the invention.

Fig. 7

one of the Fig. 4 corresponding axial section of a piston-cylinder unit to illustrate the determination of the free cross-sectional area of the flow channel.

Fig. 8

3 corresponding axial section of a piston-cylinder unit with two different piston positions.

In the known refrigerant compressor according to FIG. 1 a piston 1 is guided in a cylinder, not shown, which is closed by a valve plate 2. The valve plate 2 is shown schematically with a Pressure valve 3 provided that a circular cylindrical Outlet opening 4 in the valve plate 2 with a trained on the outside of the valve plate 2 Valve seat 5 and a valve closure element 6 in the form has a plate. The valve closure element 6 is under the internal pressure of the cylinder against the force a spring, not shown, lifted off the valve seat 5, to open the pressure valve 3, or is on the valve plate 2 clamped leaf spring educated.

During the pressure stroke of the piston 1, i.e. if he is approaching its top dead center is between the inside 7 of the valve plate 2 and the end face 8 of the Piston 1 the flow at the circumference of the outlet opening 4th restricted, i.e. the free cross-sectional area of a Flow channel to the outlet opening 4 is reduced and thereby the flow velocity during the pressure stroke with the pressure valve 3 open, so that recirculation zones are formed in the outlet opening, which increase the flow resistance and thereby the Reduce compressor efficiency and at the same time increase the noise level when the compressor is operating. The volume of the outlet opening 4 acts as "more harmful Space ", which further increases the efficiency of the compressor reduced.

The known refrigerant compressor according to FIG. 2 differs differs from that of FIG. 1 only in that the End face 8 of the piston 1 with an approximately frustoconical shape Projection 9 is provided, the outlet opening 4 partially completed. The projection 9 can however, restrict the flow before the Projection 9 enters the outlet opening 4 and before the pressure valve 3 is open. If the pressure valve 3 is open is the flow rate of the gas, while being pushed out of the cylinder by the piston 1 is greatest, so that a reduction in Cross-sectional area of the flow channel the efficiency of the compressor significantly reduced.

Also in the embodiment of the invention 3 is the end face 8 of the piston 1 is provided with a projection 10 which the outlet opening 11 of the pressure valve 3 at top dead center of the piston 1 partially fills in as it does the continuous boundary line of the piston 1 is shown is. The dashed lines represent the piston 10 in different lower positions.

In contrast to the known compressor according to FIG. 2 the cross-sectional area or the diameter changes the outlet opening 11 over its entire height H, i.e. the Cross-sectional area or its diameter increases from the inside outwards steadily and non-linearly. It is also the transition from the inside 7 of the valve plate 2 rounded to the outlet opening 11.

The projection 10 of the piston 1 has one over its total height steady and non-linear to its free Cross-sectional area decreasing towards the end. The same also applies to the cross-sectional diameter of the projection 10. The decrease rate of the cross-sectional area the projection 10 is somewhat larger, however than that of the outlet opening 11. At the same time the Transition between the flat end face 8 of the piston 10 and the circumferential surface of the projection 10 continuously or rounded.

Between the projection 10 and the outlet opening 11 a flow channel 12 is formed, the axial cutting edges are continuously curved in each axial section plane and the free cross-sectional area of the position of the piston 1 depends, i.e. decreases during its pressure stroke. In addition, the cross-sectional area of the flow channel changes 12 not suddenly, but steadily over the length of the flow channel.

While the piston 1 from the lower in Fig. 3, Position shown in dashed lines at top dead center moved there, i.e. during its pressure stroke, it reaches the middle position shown in dashed lines. In this Position is the cross-sectional area of the flow channel reduced. However, while the piston 1 approaching top dead center, its speed and speed hence the mass or volume flow of the ejected Gases off. Therefore, the cross-sectional area of the Flow channel 12 without increasing the pressure loss be reduced. At top dead center of piston 1, represented by the solid line is the cross-sectional area of the flow channel 12 to a minimum reduced, but at the same time the gas flow (mass or Volume flow). Since the projection 10 the Now almost completely fills outlet opening 11, the "harmful space" is reduced to a minimum, because almost the entire amount of gas from the cylinder is below the valve closure element 6 pressed outwards becomes. However, a free one remains, though very narrow flow channel, so that even in and after top dead center with pressure valve 3 gas open emerge through the outlet opening 11 to the pressure outlet can.

By reducing the pressure drop during the Emptying the cylinder and reducing it at the same time the "harmful space" becomes the efficiency of the compressor increased.

4 differs 3 only in that the transition 13th between the valve seat 5 and the outlet opening 11 and the transition 14 between the end face of the projection 10 and its circumferential surface is continuously rounded are.

The steady transitions 13, 14 and the steady transitions between the inside 7 of the valve plate 2 and the outlet opening 11 and between the end face 8 of the piston 1 and the peripheral surface of the projection 10 cause less eddies to appear in the gas flow, so that the recirculation zones and the flow noise be reduced.

5 is the outlet opening 15 of the pressure valve 3 asymmetrical. Also the Projection 16 of the piston 1 is correspondingly asymmetrical. That is, the steepness of the flanks of the outlet opening 15 and the projection 16 are opposite to each other or facing away from each other, left and right in the axial sectional view, different. Because of these mutually adapted asymmetries of the outlet opening and the protrusion 16 also flows the gas asymmetrical from the cylinder 17. The outlet opening 15 and the projection 16 are so far eccentric arranged to the central axis of the cylinder that they are close lie on the wall of the cylinder 17. Otherwise corresponds this embodiment the embodiment according to Fig. 4.

In the embodiment shown in Fig. 6 are the outlet opening 18 and the projection 19 also asymmetrical so that their axial cut contours largely correspond to each other, and both even closer than in the embodiment according to Fig. 5 arranged on the wall of the cylinder 17. There in in this case the gas during the pressure stroke with the open Pressure valve 3 mainly from the left in Fig. 6, approximately central area of the end face 8 to the outlet opening 18 flows towards the near the Inside of the cylinder 17 facing surfaces the outlet opening 18 and the projection 19 with Edges 20 and 21 be provided, which are in partially cylindrical Pass areas 22 and 23, respectively. The arrangement of the outlet opening 18 in the immediate vicinity of the inside of the Cylinder 17 enables both the outlet opening 18th as well as the suction opening, not shown in the Form valve plate 2 with a larger diameter.

In all of the exemplary embodiments, the projection 10, 16, 19 at least about 45% of the volume of the outlet opening Fill in 11, 15, 18.

7 illustrates the determination of the free cross-sectional area of the flow channel for a given Position of the piston 1 using the example of that shown in Fig.4 rotationally symmetrical shape of outlet opening 11 and piston projection 12. Below the free cross-sectional area is generally that for the outflowing gas Available and by the "clear width" of the Flow channel determined the smallest geometric cross-sectional area to understand.

The free cross-sectional area can be calculated for different Gradients of the axial cut edges of the outlet opening 11 and piston projection 12 are determined. Here, on the axial cut edges of the outlet opening 11 over the entire height of the valve plate 2 a Set of points 24. Likewise, on the axial cut edges of the projection 12 several points 25 set.

By connecting one of the points 24 on the inside of the outlet opening to a point 25 of the piston projection, a distance a and an associated diameter d are obtained, the diameter d corresponding to the length of the connecting line between the centers of two associated horizontally opposite distances a. According to the formula d eff = 2 a · d this results in an effective diameter d _{eff of} the flow channel for a distance a. Geometrically, d _eff can be thought of as the diameter of a circular opening that has the same cross-sectional area as the annular gap between the inside of the outlet opening and the piston projection.
The point 24 on the axial cut edge of the outlet opening 11 is now connected in a corresponding manner to all points 25 of the projection, and values for d _{eff are} determined. The smallest value found corresponds to the effective diameter of the flow channel for this point 24 in question.

The free cross-sectional area A of the flow channel 12 for a given piston position is determined from the overall smallest value d _{eff min of} the effective diameter after values have been determined for each point 24 along the inside of the outlet opening in accordance with the described procedure. In the case of a rotationally symmetrical shape of the outlet opening and projection, A = d 2 / eff min · π / 4 results.

The respective volume V of the pressure chamber includes this free volume in the cylinder and the volume of the dead space to the upper end surface of the valve plate 2.

8 shows the change in the pressure chamber volume and the free cross section of the passage 12 for two positions of the piston 1. In a first position, which is indicated by the dashed line, this results in a volume V1 and a free cross-sectional area A1 of the flow channel 12. In the further course During the lifting process, the piston approaches its upper one Dead center, and you get a new lower volume V2 and a new free cross-sectional area A2, which is now in a region of the outlet opening near the Underside of the valve plate. Such a position the piston is indicated by the solid line.

The relationship V ₂ / V ₁ < A ₂ / A ₁ applies, since the volume V of the pressure chamber decreases relatively faster than the free cross-sectional area A of the passage 12, whereby an increase in the flow resistance and flow noise are avoided.

Claims (6)

1. Axial piston refrigerant compressor comprising at least one piston-cylinder unit, whose cylinder (17) is closed by a valve plate (2) that has at least one discharge valve (3) with an outlet opening (11; 15; 18), a projection (10; 16; 19) of the piston (1) extending into the outlet opening (11; 15; 18), when the piston (1) is near its upper dead centre, characterised in that the outlet opening (11; 15; 18), the piston projection (10; 16; 19), the inside (7) of the valve plate (2) and the front face (8) of the piston (1) delimit a flow channel (12) having a continuous extension of its axial section edges, at least over the major part of its circumference, that the free cross-sectional area of the flow channel (12) is determined by the smallest cross-sectional area of the outlet opening (11; 15; 18), at least until the piston (1), during its pressure stroke, has reached a position, which lies below the upper dead centre by at least the height (H) of the outlet opening (11; 15; 18), that during the further pressure stroke of the piston (1) the relative decrease of the free cross-sectional area of the flow channel is smaller than the relative decrease of the volume of the pressure chamber in the cylinder (17) and that, in the upper dead centre position of the piston (1), at least 45% of the volume of the outlet opening (11; 15;18) is occupied by the projection.
2. Axial piston refrigerant compressor according to claim 1, characterised in that the cross-sectional area of the outlet opening (11; 15; 18) decreases in the direction of the outside of the valve plate (2), that the cross-sectional area of the projection (10; 16; 19) decreases towards its free end and that the cross-sectional areas of the outlet opening (11; 15; 18) and the projection (10; 16; 19) change in the axial direction in such a way that during the piston movement towards the upper dead centre the free cross-sectional area of the flow channel (12) changes less than the volume remaining in the pressure chamber of the cylinder (17).
3. Axial piston refrigerant compressor according to claim 1 or 2, characterised in that during the pressure stroke of the piston (1), the flow resistance of the flow channel is determined by the smallest cross-sectional area of the outlet opening (11; 15; 18), until the free end of the piston projection (10; 16; 19) is aligned with the inside (7) of the valve plate (2).
4. Axial piston refrigerant compressor according to one of the claims 1 to 3, characterised in that during the pressure stroke of the piston (1), the flow resistance of the flow channel (12) is determined by the smallest cross-sectional area of the outlet opening (11; 15; 18), until 50% of the height of the piston projection (10; 16; 19) has penetrated into the outlet opening (11; 15; 18).
5. Axial piston refrigerant compressor according to one of the claims 1 to 4, characterised in that an axial section through the outlet opening (11; 15) of the valve plate (2) and the piston projection (10; 16) has curved section edges.
6. Axial piston refrigerant compressor according to one of the claims 1 to 5, characterised in that the junction surfaces (13; 14) between the valve plate surface and the outlet opening (11; 15; 18), and the junction surface between the piston front end (8) and the projection (10; 16) are continuous, the junction surface (13) between the outlet opening (11; 15; 18) and the valve seat (5) and the junction surface between the projection (10; 16; 19) and the piston front end (8) being rounded.

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