BR112020010273B1 - LAMELAR DISCHARGE VALVE - Google Patents

Abstract

A lamellar discharge spring is provided for a discharge opening (4) in a housing (9) of a compression cylinder of a compressor. The lamellar discharge valve has a blade (1) for closing and opening the discharge opening (4), a bridge (2) for restricting deformations of the blade (1) in an open state of the discharge opening (4), and at least one fixing element (3) for fixing the bridge (2) in the housing (9) of the compression cylinder. The bridge (2) has, in a region, a support face (5) facing the blade (1) with a predetermined radius of curvature (¿), and at least one opening (6) is provided in the blade (1) , which is configured to let the fixing element (3) penetrate the blade (1) to fix the bridge (2) in the housing (8) of the compression cylinder.

Description

[001] The invention relates to a lamellar discharge valve, especially a lamellar valve for closing and opening a discharge opening in a housing of a compression cylinder of a compressor.

[002] Compressors are used, for example, in bus or truck brake systems. Such compressors have one or more compression cylinders and are installed directly on the vehicle's engine. Alternating compressors are frequently used, which have a work cycle with suction, compression and air expulsion. During compressor operation, on the one hand, due to compression work and, on the other hand, due to mechanical losses, such as friction of the piston rings or throttling losses of a lamellar valve, energy through the vehicle's engine. Currently, however, energy saving is a main challenge.

[003] In the state of the art, lamellar discharge valves are known which, as shown in figures 1, 2a, 2b, consist of a blade 1, which closes and opens openings 4 of a compression cylinder in a housing 9 of the pressure cylinder. compression, a bridge 2, which restrains the deformation of the blade 1 in an open state of the discharge openings 4, and fastening elements 3. When the plunger goes down in a compression cylinder, the discharge valve blocks the discharge openings. discharge 4 to prevent air that has already been expelled, under pressure, from returning to the compression cylinder. When the plunger goes up, the blade 1 is curved away from the discharge opening through the air current, to let air pass into the channel. The maximum radius of curvature of the blade 1 curved away, which rests on the bridge 2, is indicated with Y in figure 2a. As indicated above, part of the compressed air energy is used to bend blade 1.

[004] From the housing 9 of the compression cylinder, a valve plate is represented here, which is arranged in a cylinder block. Alternatively, however, a separate valve plate is not necessarily required and the function of the separate valve plate can be performed by a section integrated into the housing 9 of the compression cylinder.

[005] To reduce the pressure drop in lamellar discharge valves, which is essential for energy consumption, it is necessary to enlarge the discharge area of the discharge ratio.

[006] This is basically possible through an increase in the deformation of blade 1, so that blade 1 is further away from the discharge openings 4, that is, a course a (figure 2a) is enlarged, and with this a space discharge area or discharge area becomes larger. In this case, however, with a predetermined construction space (the dimensions of the discharge channel), which cannot be enlarged, blade 1 deforms more and is curved with a smaller radius of curvature. However, this leads to an increase in bending stresses in blade 1 and, therefore, a reduction in the useful life of blade 1.

[007] The objective of the invention is to provide a lamellar discharge valve which, under compatibility conditions, reduces a pressure drop in the lamellar discharge valve.

[008] The objective is achieved through a lamellar discharge valve according to claim 1. Developments of the invention are the subject of the dependent claims.

[009] By providing at least one opening for a fastening element in the blade, it is possible to extend a length of the blade, to extend a maximum distance from the blade to a compression cylinder discharge opening in a radius of curvature of the blade. at least approximately equal. The fixing elements can fix a bridge that restricts the maximum deformation of the blade and, therefore, determines its maximum radius of curvature at certain fixing points inside the blade, so that there is no need for additional space for fixing outside the blade.

[0010] When said at least one opening is preferably arranged in an external region of the blade, it is possible to position the discharge opening, in relation to the blade, at a point where the maximum deformation of the blade is the greatest, to configure an area discharge as large as possible.

[0011] Preferably, two openings are provided in the blade. This means that the bridge can be securely fixed with two fastening elements.

[0012] The blade preferably has an elongated shape, that is, a shape in which a dimension is substantially smaller in a first direction relative to a dimension in a second direction perpendicular to the first direction. The openings are arranged in the end region in a longitudinal direction, that is, the direction with the largest dimension. This way it is possible to securely fix the bridge with a greater support distance, without the openings in the blade releasing discharge openings in a closed position of the blade.

[0013] When the bridge preferably has at least one drain hole, which is arranged in a region that coincides with at least one of the openings of the blade arranged in the bridge in accordance with the requirements, air can flow through the drain hole into the bridge through the opening(s) in the lamia, in addition to the side discharge areas.

[0014] Advantageously, the openings are open towards the ends in the longitudinal direction. In this case there is the possibility of using openings with a larger cross-sectional area for improved air flow through the drain hole.

[0015] Through the advantageous provision of a through hole in addition to said at least one drain hole in the brush, it is possible to fix both the bridge by means of the fixing elements in the through hole and, additionally, to allow air to flow through the hole. of drainage.

[0016] When the opening is advantageously arranged in a central region of the blade, there is the possibility of fixing the blade in a central region. Thus the blade can curve upwards at several points in its edge region, whereby, in comparison with attachments in the edge region, either several discharge openings or discharge openings with a larger total cross-section can be released as The cost of fixing the bridge is reduced, since the fixing element is only needed at one point.

[0017] Advantageously this blade has an elongated shape, so that, when arranging the discharge openings in the end region in the longitudinal direction, the lever arm for deforming the blade is larger, to reduce the deformation force of the blade and, therefore, reduce a pressure drop. In this case, a twist-proof fastening prevents the blade from twisting, so that the discharge openings are securely closed in a closed state of the blade.

[0018] Advantageously, the attachment to the torsion bow is provided as an elevation or depression in the blade and a depression or elevation in the housing of the compression cylinder complementary to the elevation or depression. An elevation or depression in the blade is simply produced by means of a punch or similar cut.

[0019] The invention is now clarified as an aid to embodiment examples with reference to the attached drawings, where:

[0020] Figure 1 shows an exploded representation of a lamellar discharge valve according to the state of the art;

[0021] Figure 2a shows a side sectional view of the lamellar discharge valve according to the state of the art;

[0022] Figure 2b shows an isometric view of the lamellar discharge valve according to the prior art without representation of a bridge;

[0023] Figure 3a shows a side sectional representation of a lamellar discharge valve according to a first embodiment of the invention;

[0024] Figure 3b shows an isometric view of the lamellar discharge valve according to the first embodiment of the invention;

[0025] Figure 4a shows an isometric view of a blade and fixing elements of a first modified embodiment of the invention;

[0026] Figure 4b shows a top view of an alternative blade of the first modified embodiment;

[0027] Figure 4c shows an isometric sectional view of the first modified embodiment of the invention;

[0028] Figure 5a shows an exploded representation of a lamellar discharge valve according to a second embodiment of the invention; It is

[0029] Figure 5b shows a side view of the discharge valve bridge according to a second embodiment with indication of the radius of curvature.

[0030] Data referring to space as above, below, sideways, or the like refer to a description of a lamellar discharge valve which, as represented in the figures, is disposed above a compression cylinder, and whose blade moves towards above, as also shown in the figures. These data, however, are not restrictive.

[0031] Figure 3a shows a side sectional view of a lamellar discharge valve according to a first embodiment of the invention and figure 3b shows an isometric view of the lamellar discharge valve according to the first embodiment of the invention. invention. The lamellar discharge valve is intended to close and open discharge openings (figure 1, reference number 4) in a housing (figure 1, reference number 9) of a compression cylinder of a compressor.

[0032] The embodiment of the lamellar discharge valve according to figures 3a and 3b presents, like the state of the art according to figures 1, 2a, and 2b, also a blade 1 for closing and opening an opening drain not shown (figure 1, reference number 4). A single discharge opening or alternatively several discharge openings may be provided, with the total cross-sectional area of the discharge openings being chosen as large as possible to minimize a loss of pressure when air is expelled.

[0033] The lamellar discharge valve also has a bridge 2, to restrict deformation of the blade 1. The blade 1 is curved upwards through an air stream that passes through the discharge openings arranged above the blade 1 (figure 1, reference number 4), until it touches a support face 5 facing the blade 1 in a state of maximum opening of the discharge openings (figure 1, reference number 4). The bridge 2 has, in one region, a support face 5 with a predetermined radius of curvature Y, which is substantially identical to the radius of curvature shown in figure 2a, so that, on the one hand, a discharge area is realized. as large as possible, but, on the other hand, a service life is not reduced through an increase in bending stresses.

[0034] Furthermore, the bridge 2 has a depression not shown here, through which the blade 1 is guided laterally, to restrict a lateral displacement of the blade 1. The bridge 2 also has through holes 8 for fixing elements 3.

[0035] The fastening elements 3 here consist of respective pins and nuts, but they can also be configured in another way, for example, as rivets.

[0036] As shown in figure 3b, the blade 1, unlike the blade 1 in the prior art (figure 1, reference number 2b), has openings 6 through which the fastening elements 3 can pass through the blade 1, to fix the bridge 2 in the housing (figure 1, reference number 9) of the compression cylinder. It is thus possible to extend the stroke a (figure 2a) to a stroke a’ with an approximately equal radius of curvature Y of the blade.

[0037] Furthermore, alternatively it is possible that only one opening 6 is provided, and then the fixing elements 3 penetrate only through this opening 6. Alternatively, there is also the possibility that more than two openings 6 are provided for the fixing elements. fixing 3.

[0038] Figure 4a shows an isometric view of the blade 1 and the fixing elements 3 of a first modified embodiment of the invention. The openings 6 are not formed here as through holes adjusted to the size of the fastening elements 3, as in the embodiment shown in figure 3b, but rather have dimensions described below.

[0039] Figure 4b shows a top view of an alternative blade 1 of the first modified embodiment of the invention. The openings 6 in this blade 1 are end-to-end in the longitudinal direction.

[0040] In figure 4c, from an isometric sectional view of the first modified embodiment of the invention, the bridge 2 presents continuous discharge holes 7 with predetermined dimensions. The discharge holes 7 are provided in a respective region that substantially coincides with the openings 6 of the blade 1 arranged on the bridge 2 in accordance with the requirements. The dimensions of the openings 6 are chosen such that they substantially correspond to the predetermined dimensions of the associated discharge holes 7. The bridge 2 has discharge holes 7 in addition to the through holes 8 for the fastening elements 3.

[0041] Figure 5a is an exploded representation of the lamellar discharge valve according to a second embodiment of the invention. Unlike the first embodiment, the blade 1 presents the opening 6 not in an external region of the blade 1, but rather the opening 6, through which the fixing element 3 penetrates the blade 1, is arranged in a central region.

[0042] Here also the blade 1 is provided for closing and opening the discharge openings 4. The bridge 2 is also provided for restricting the maximum deformation of the blade 1 in an open state of the discharge openings 4. For this purpose the bridge 2 has Also here, the supporting face 5 faces the blade 1. As the opening 6 for the fixing element 3 is arranged in the central region of the blade 1, the bridge 2 and also the blade 1 are fixed in their respective central region. As shown in figure 5b, from a side view of the discharge valve bridge according to the second embodiment, here also the radius of curvature Y corresponds substantially to the radii of curvature Y shown in figures 2a and 3a, so that Here too, a service life of the blade 1 is not reduced by increasing the bending stresses.

[0043] As shown in figure 5a, a torsion-proof fixation is provided between the blade 1 and the housing 9 of the compression cylinder. The torsion-proof fastening consists of three depressions 10, which are made in the housing 9 of the compression cylinder. In the blade 1, complementary lows 11 are provided for the depressions 10, which are protruding downwards and can engage in the depressions 10, to fix a position of the blade 1 in relation to the housing 9. Alternatively, elevations may also be provided in the housing 9. the blade has recesses complementary to the elevations.

[0044] In the example, the blade 1 touches the discharge opening(s) 4 through the use of its original shape during a compressor suction cycle and, through an underpressure in the compression cylinder, is sucked into the housing 9 of the compression cylinder, to close the discharge opening(s) 4. During an expulsion cycle the blade 1 is curved away from the discharge opening(s) 4 through the air exiting in virtue of the pressure in the compression cylinder, so that air can flow out. The blade 1 is curved until it touches the support face 5 of the bridge 2, with a maximum radius of curvature of the blade 1 being fixed. The blade 1 moves away from the housing 9, due to the air escaping, to minimize a wear on its edges. Air flows sideways through discharge faces.

[0045] Through the lamellar discharge valve according to the invention it is possible to enlarge the stroke a (figure 2a) of the blade 1 with a radius of curvature of the blade 1 approximately equal to a stroke a' (figure 3a), to reduce a pressure drop in the lamellar discharge valve.

[0046] In an optimal provision of the discharge hole 7 or the discharge holes 7 and enlarged openings 6 in the blade 1, here the air can additionally exit from the discharge openings 4, and here, conditioned by the construction space, a smoother exit is normally possible than through the side discharge faces.

[0047] In the second embodiment of the invention, air can exit the discharge openings 4 in a circumferential region approximately around the discharge opening 4, so that the pressure drop is reduced again.

[0048] All of the features represented in the description, the following claims and the drawing may be essential to the invention either individually or in any combination. LIST OF REFERENCE NUMBERS 1 blade 2 bridge 3 fastening element 4 discharge opening 5 support face 6 opening 7 discharge hole 8 through hole 9 housing 10 depression 11 recess

Claims (4)

1 . Lamellar discharge valve for a discharge opening (4) in a housing (9) of a compression cylinder of a compressor, comprising: - a blade (1) for closing and opening the discharge opening (4), - a bridge (2) for restricting a maximum deformation of the blade (1) in an open state of the discharge opening (4), and - at least one fastening element (3) for fixing the bridge (2) in the housing (9) of the compression cylinder, with the bridge (2) having, in one region, a support face (5) facing the blade (1), which has a predetermined radius of curvature (Y), and is provided for at least an opening (6) in the blade (1), which is configured to let the fixing element (3) penetrate the blade (1), to fix the bridge (2) in the housing (9) of the compression cylinder, two openings are provided for on the blade, the blade (1) has an elongated shape and the openings (6) are arranged in the end region in a longitudinal direction, characterized by the fact that the bridge (2) comprises at least one discharge hole (7 ) which is provided substantially in a region coinciding with said at least one opening (6) of the blade (1) which is arranged as intended in the bridge (2). 2. Lamellar discharge valve, according to claim 1, characterized by the fact that said at least one opening (6) is arranged in an external region of the blade (1). 3. Lamellar discharge valve according to claim 1 or 2, characterized in that the openings (6) are open towards the ends in the longitudinal direction. 4. Lamellar discharge valve, according to any one of claims 1 to 3, characterized by the fact that the bridge (2) has, in addition to said at least one discharge hole (7), a through hole (8) for the fastening element (3).