EP3721090B1 - Lamellar discharge valve - Google Patents

Description

The invention relates to an outlet lamellar valve, in particular a lamellar valve for closing and opening an outlet opening in a housing of a compression cylinder of a compressor.

Compressors are used, for example, in the braking systems of buses or trucks. Such compressors have one or more compression cylinders and are attached directly to the engine of the vehicle. Reciprocating compressors which have a duty cycle with suction, compression and discharge of air are often used. When the compressor is in operation, energy is consumed via the vehicle engine on the one hand due to compression work and on the other hand due to mechanical losses, such as friction in the piston rings or throttling losses of a reed valve. Nowadays, however, energy saving is a major challenge.

In the prior art, exhaust reed valves are known which, as in Fig. 1 , Figures 2a and 2b shown, from a lamella 1, which closes and opens outlet openings 4 of a compression cylinder in a housing 9 of the compression cylinder, from a bridge 2, which restricts deformation of the lamella 1 in an open state of the outlet openings 4, and from fastening elements 3. When a piston in the compression cylinder goes down, the outlet reed valve blocks the outlet openings 4 in order to prevent pressurized air that has already been expelled from flowing back into the compression cylinder. When the piston goes up, the lamella 1 is bent away from the outlet opening by the air flow in order to allow air to flow out into an outlet channel. The maximum radius of curvature of the bent-away lamella 1, which is supported on the bridge 2, is in Fig. 2a given with γ. As stated above, part of the energy of the compressed air is used to bend the lamella 1.

A valve plate of the housing 9 of the compression cylinder is shown here, which is attached to a cylinder block. Alternatively, however, a separate valve plate is not absolutely necessary and the function of the separate valve plate can be performed by a section integrated in the housing 9 of the compression cylinder.

In order to reduce the pressure drop across the exhaust reed valves, which is essential for energy consumption, it is necessary to enlarge an exhaust area of the exhaust valve.

This is basically possible by increasing the deformation of the lamella 1 so that the lamella 1 moves further away from the outlet openings 4, i.e. a stroke a ( Fig. 2a ) is enlarged, and thus an outlet space or the outlet area becomes larger. However, given a given installation space (the dimensions of the outlet channel), which cannot be increased, the lamella 1 deforms more strongly and is therefore bent with a smaller radius of curvature. However, this leads to an increase in bending stresses in the lamella 1 and thus to a reduction in the service life of the lamella 1.

The documents DE 1956259 A1 , US 3384298 A and DE 2842611 A1 each disclose a pressure valve or a valve assembly for reciprocating compressors or an outlet valve device for compressors with a lamellar outlet valve having the features according to the preamble of claim 1.

document EP 0571715 A1 discloses a valve assembly having a lamella for closing and opening outlet openings, wherein a bridge is provided with a support surface with a radius of curvature for the lamella which restricts a maximum deformation of the lamella in an open state. The lamella is fastened in its center to the bridge by means of a fastening element.

document JPH04105674U discloses a discharge reed valve for a compressor including a bridge for restricting maximum deformation of the fin with two discharge holes.

The object on which the invention is based is to provide an outlet lamellar valve which, under given dimensional boundary conditions, reduces a pressure drop at the outlet lamellar valve.

The object is achieved by an outlet lamellar valve according to claim 1. Further developments of the invention are the subject of the dependent claims. By providing at least one opening for a fastening element in the lamella, it is possible to increase a length of the lamella in order to increase a maximum distance from the lamella to an outlet opening of the compression cylinder with at least approximately the same radius of curvature of the lamella. The fastening elements can then attach a bridge, which restricts a maximum deformation of the lamella and thus determines its maximum radius of curvature, at given fastening points inside the lamella, so that no additional space is required for fastening outside the lamella.

If the at least one opening is advantageously arranged in an outer region of the lamella, it is possible to have the outlet opening with respect to the lamella on one Position where the maximum deformation of the lamella is greatest in order to make an outlet area as large as possible.

According to the invention, two openings are provided in the lamella. This makes it possible to securely attach the bridge with two fastening elements.

The lamella has an elongated shape, that is to say a shape in which a dimension in a first direction is significantly smaller than a dimension in a second direction perpendicular to the first direction. The openings are arranged in the region of ends in a longitudinal direction, that is to say the direction with the large dimension. This makes it possible to securely fasten the bridge with a large support spacing without the openings in the lamella exposing the outlet openings in a closed position of the lamella.

The bridge has at least one outflow hole, which is arranged in an area that essentially coincides with at least one of the openings of the lamella arranged as intended in the bridge, so that air, in addition to lateral outlet surfaces, through the opening (s) in the lamella can flow out through the outflow hole in the bridge.

The openings are advantageously open towards the ends in the longitudinal direction. There is the possibility of using the openings with an enlarged cross-sectional area for an improved outflow of air through the outflow hole.

The advantageous provision of a through hole in addition to the at least one outflow hole in the bridge makes it possible both to fasten the bridge in the through hole by means of the fastening elements and also to allow the air to flow out through the outflow hole.

If the opening is arranged in a central area of the lamella, it is possible to fasten the lamella in the central area. Thus, the lamella can bend upwards at several points in its edge area, whereby, compared to the fastenings in the edge area, both several outlet openings or outlet openings with a larger overall cross-section can be released and the effort for fastening the bridge is reduced, since this Fastener is only required in one place.

This lamella has an elongated shape so that, when the outlet openings are arranged in the region of the ends in the longitudinal direction, the lever arm for deforming the lamella is large in order to reduce the force for deforming the lamella and thus a pressure drop. An anti-twist device prevents the lamella from twisting, so that the outlet openings are securely closed when the lamella is in a closed state.

The anti-rotation device is provided as an elevation or depression in the lamella and a depression or elevation that is complementary to the elevation or depression in the housing of the compression cylinder. An elevation or depression in the lamella can be easily produced by embossing or a similar manufacturing step.

The invention will now be explained on the basis of exemplary embodiments with reference to the accompanying drawings.

Fig. 1

eine Explosionsdarstellung eines Auslasslamellenventils gemäß dem Stand der Technik;

Fig. 2a

eine seitliche Schnittansicht des Auslasslamellenventils gemäß dem Stand der Technik;

Fig. 2b

eine isometrische Ansicht des Auslasslamellenventils gemäß dem Stand der Technik ohne Darstellung einer Brücke;

Fig. 3a

eine seitliche Schnittansicht eines Auslasslamellenventils;

Fig. 3b

eine isometrische Ansicht des Auslasslamellenventils;

Fig. 4a

eine isometrische Ansicht einer Lamelle und von Befestigungselemente;

Fig. 4b

eine Draufsicht auf eine alternative Lamelle;

Fig. 4c

eine isometrische Schnittansicht des Auslasslamellenventils gemäß der Erfindung;

Fig. 5a

eine Explosionsdarstellung eines Auslasslamellenventils gemäß einem Ausführungsbeispiel, das nicht Teil der Erfindung ist; und

Fig. 5b

eine seitliche Ansicht der Brücke des Auslassventils gemäß dem Ausführungsbeispiel, das nicht Teil der Erfindung ist.

In particular shows

Fig. 1

an exploded view of an exhaust reed valve according to the prior art;

Fig. 2a

a side sectional view of the exhaust reed valve according to the prior art;

Figure 2b

an isometric view of the exhaust reed valve according to the prior art without showing a bridge;

Fig. 3a

a side sectional view of an exhaust reed valve;

Figure 3b

an isometric view of the exhaust reed valve;

Figure 4a

an isometric view of a lamella and fasteners;

Figure 4b

a plan view of an alternative lamella;

Figure 4c

an isometric sectional view of the exhaust reed valve according to the invention;

Figure 5a

an exploded view of an exhaust reed valve according to an embodiment that is not part of the invention; and

Figure 5b

a side view of the bridge of the exhaust valve according to the embodiment which is not part of the invention.

Spatial information such as, above, below, to the side, or the like relate to a description of an outlet reed valve which, as shown in the figures, is arranged above a compression cylinder, and whose lamella moves upwards, as also shown in the figures. However, this information is not restrictive.

Fig. 3a FIG. 11 shows a side sectional view of an exhaust reed valve and FIG Figure 3b Figure 13 shows an isometric view of the exhaust reed valve.

The outlet lamellar valve is provided, outlet openings ( Fig. 1 : Bzz. 4) in one housing ( Fig. 1 : Bzz. 9) to close and open a compression cylinder of a compressor.

The embodiment of the outlet reed valve according to FIG Figures 3a and 3b shows how the prior art according to the Figures 1 , 2a and 2b , also a lamella 1 for closing and opening an outlet opening not shown here ( Fig. 1 : Bzz. 4) on. A single outlet opening can be provided or, alternatively, a plurality of outlet openings, wherein a total cross-sectional area of the outlet openings should be selected as large as possible in order to minimize a pressure loss when the air is expelled.

The outlet reed valve also has a bridge 2 in order to restrict deformation of the lamella 1. The lamella 1 is released by a stream of air through the outlet openings ( Fig. 1 : Bzz. 4) bent upwards until the outlet openings ( Fig. 1 : Bzz. 4) rests on a support surface 5 facing the lamella 1. The bridge 2 has in one area a support surface 5 with a predetermined radius of curvature γ which is essentially identical to that in FIG Fig. 2a The radius of curvature shown is γ, so that, on the one hand, the largest possible outlet area is realized, but, on the other hand, an increase in bending stresses does not reduce a service life.

Furthermore, the bridge 2 has a depression (not shown here) through which the lamella 1 is guided laterally in order to restrict the lamella 1 from shifting laterally. The bridge 2 also has through holes 8 for fastening elements 3. The fastening elements 3 here each consist of bolts and nuts, but can also be designed in a different form, for example as rivets.

As in Figure 3b shown, the lamella 1, in contrast to the lamella 1 in the prior art ( Fig. 1 , Figure 2b ), Openings 6 through which the fastening elements 3 can penetrate the lamella 1 in order to attach the bridge 2 to the housing ( Fig. 1 : Bzz. 9) of the compression cylinder. This enables the stroke a ( Fig. 2a ) to enlarge to a stroke a '.

Furthermore, it is alternatively also possible for only one opening 6 to be provided, in which case the fastening elements 3 only penetrate through this one opening 6. Alternatively, there is also the possibility that more than two openings 6 are provided for the fastening elements 3.

Figure 4a shows an isometric view of the lamella 1 and the fastening elements 3. The openings 6 are not here, as in FIG Figure 3b embodiment shown, formed as through holes matched to a dimension of the fastening element 3, but have dimensions described below.

Figure 4b shows a plan view of an alternative lamella 1. The openings 6 in this lamella 1 are open towards the ends in the longitudinal direction.

In Figure 4c , an isometric sectional view of the outlet lamellar valve according to the invention, the bridge 2 has through outflow holes 7 with predetermined Dimensions on. The outflow holes 7 are each provided in an area which essentially coincides with the openings 6 of the lamella 1 arranged as intended in the bridge 2. The dimensions of the openings 6 are selected such that they essentially correspond to the predetermined dimensions of the associated outflow holes 7. The bridge 2 has the outflow holes 7 in addition to the through holes 8 for the fastening elements 3.

Figure 5a Figure 3 is an exploded view of the exhaust reed valve according to an embodiment not forming part of the invention. In contrast to the first embodiment, the lamella 1 does not have the opening 6 in an outer area of the lamella 1, but the opening 6 through which the fastening element 3 penetrates the lamella 1 is arranged in a central area.

Here, too, the lamella 1 is provided for closing and opening the outlet openings 4. The bridge 2 is also provided for limiting the maximum deformation of the lamella 1 in an open state of the outlet openings 4. For this purpose, the bridge 2 also has the support surface 5 facing the lamella 1 here. Since the opening 6 for the fastening element 3 is arranged in the central area of the lamella 1, the bridge 2 and also the lamella 1 are fastened here in their respective central area. As in Figure 5b , a side view of the bridge of the exhaust valve according to the embodiment of FIG Figure 5a , is shown, here too the radius of curvature γ essentially corresponds to that in Fig. 2a and 3a Radii of curvature γ shown, so that here, too, a service life of the lamella 1 is not reduced by an increase in the bending stresses.

As in Figure 5a shown, a rotation lock is provided between the lamella 1 and the housing 9 of the compression cylinder. The anti-rotation device consists of three recesses 10 which are made in the housing 9 of the compression cylinder. In the lamella 1, embossings 11 complementary to the recesses 10 are provided, which thus protrude downward and can engage in the recesses 10 in order to ensure a position of the lamella 1 in relation to the housing 9. Alternatively, elevations can also be provided in the housing 9, the lamella 1 then having impressions complementary to the elevations.

In operation, the lamella 1 rests against the outlet opening (s) 4 during an intake stroke of the compressor by adopting its original shape and is sucked onto the housing 9 of the compression cylinder by a negative pressure in the compression cylinder in order to close the outlet opening (s). 4 to close. During an exhaust stroke, the lamella 1 is bent away from the outlet opening (s) 4 by the air flowing out due to the pressure in the compression cylinder, so that the air can flow out. The lamella 1 is bent until it rests against the support surface 5 of the bridge 2, a maximum radius of curvature of the lamella 1 being defined. Due to the air flowing out, the lamella 1 lifts from the housing 9 in order to minimize wear on its edges. The air flows out laterally through outflow surfaces.

With the exhaust reed valve according to the invention, it is possible to reduce the stroke a ( Fig. 2a ) of the lamella 1 with an approximately equal radius of curvature of the lamella 1 on the stroke a '( Fig. 3a ) to reduce a pressure drop across the exhaust reed valve.

If the outflow hole 7 or the outflow holes 7 and enlarged openings 6 are provided in the lamella 1, air can also flow out of the outlet openings 4, whereby a more undisturbed flow is usually possible here than through the lateral outflow surfaces, due to the installation space.

In the embodiment of Figure 5a the air can flow out of the outlet openings 4 in an area that runs approximately around the outlet opening 4, so that the pressure drop is further reduced.

REFERENCE LIST

1

Lamella

2

bridge

3

Fastener

4th

Outlet opening

5

Support surface

6th

opening

7th

Outlet hole

8th

Through hole

9

casing

10

deepening

11

Imprint

Claims (3)

1. A lamellar discharge valve for a discharge opening (4) in a housing (9) of a compression cylinder of a compressor, comprising

   a lamella (1) for closing and opening the discharge opening (4),

   a bridge (2) for limiting a maximum deformation of the lamella (1) when the discharge opening (4), and

   at least one fastening element (3) for fastening the bridge (2) to the housing (9) of the compression cylinder,

   in one region the bridge (2) comprising a support surface (5) that faces the lamella (1) and has a predefined radius of curvature (γ), and

   there being provided in the lamella (1) at least one opening (6) that is configured to allow the fastening element (3) to pass through the lamella (1) in order to fasten the bridge (2) to the housing (9) of the compression cylinder,

   two openings (60) being provided in the lamella (1),

   the lamella (1) having an elongated shape and the openings (6) being arranged in the region of the longitudinal ends,

   characterised in that

   the bridge (2) has at least one outflow hole (7) that is provided substantially in a region that corresponds with the at least one opening (6) of the lamella (1) that is arranged as prescribed in the bridge (2).
2. A lamellar discharge valve according to claim 1,
   the openings (6) being open toward the longitudinal ends.
3. A lamellar discharge valve according to claim 1 or 2,
   the bridge (2) comprising at least one through-hole (8) for the fastening element (3) in addition to the at least one outflow hole (7).

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