DENTING DEVICE FOR IMPROVING SURFACE ROUGHNESS OF VALVE PLATE AND VALVE PLATE HAVING DENT PATTERN

Abstract

A denting device for forming a predetermined pattern on a surface near a discharge hole and an intake hole of a valve plate for a compressor includes: a seating jig to which the valve plate is fixed; a processing pin in which a pressing part for pressing the valve plate is formed at a distal end thereof; and a moving unit which is disposed on an upper portion of the seating jig, horizontally moves the processing pin at a constant speed while allowing the processing pin to vertically reciprocate at a constant speed, so as to form the pattern on the valve plate.

Claims

1. A denting device for improving surface roughness and forming a predetermined dent pattern on a surface near a discharge hole and an intake hole of a valve plate for a compressor, the denting device comprising: a seating jig to which a valve plate is fixed; a moving unit disposed above the seating jig, wherein the moving unit is configured to move toward and far away from the seating jig to adjust a distance between the moving unit and the valve plate, a processing pin disposed in the moving unit and having a pressing part formed at a distal end thereof, wherein the processing pin is configured to horizontally move in parallel to the valve plate and vertically move toward and far away from the valve plate in such a way that the presssing part forms a dent near a discharge hole and an intake hole of the valve plate.

2. The denting device of claim 1, further comprising: a height adjusting support to which the moving unit is movably attached.

3. The denting device of claim 1, wherein the pressing part has a conic shape, a diameter of which is decreased downwardly.

4. The denting device of claim 1, wherein a slope angle (a) of the pressing part is one of 60 degrees, 90 degrees, and 120 degrees.

5. The denting device of claim 1, wherein the pressing part has a polygonal including a hexagonal cross-section.

6. A valve plate for a compressor and having a discharge hole and an intake hole, the valve plate comprising: a plurality of dents formed in a surface near the discharge hole and the intake hole, wherein the plurality of dents are arranged along a plurality of circular lines around the discharge hole and the intake hole, the plurality of circular lines are spaced apart from each other, a space between two neighboring circular lines become gradually larger toward an outer side of the discharge hole and the intake hole, and dents arranged along each of the plurality of circular lines are spaced apart from each other.

7. The valve plate of claim 6, wherein the plurality of dents comprises: a first section formed along an outer periphery of the discharge hole and the intake hole; a second section formed on an outer side of the first section; and a third section formed on an outer side of the second section.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which:

[0028] FIG. 1 is a perspective view illustrating a denting device according to an embodiment of the present invention;

[0029] FIG. 2 is an enlarged perspective view illustrating a distal end of a processing pin of a denting device according to an embodiment of the present invention;

[0030] FIG. 3 is an enlarged perspective view illustrating a distal end of a processing pin of a denting device according to another embodiment of the present invention;

[0031] FIG. 4 illustrates a planar structure of a denting device according to yet another embodiment of the present invention;

[0032] FIG. 5 is a plan view illustrating a pattern formed using a denting device according to an embodiment of the present invention;

[0033] FIG. 6 is a plan view illustrating a pattern formed using a denting device according to another embodiment of the present invention; and

[0034] FIG. 7 illustrates a sectional structure of a pattern formed using a denting device according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS

[0035] FIG. 1 is a perspective view illustrating a denting device according to an embodiment of the present invention; FIG. 2 is an enlarged perspective view illustrating a distal end of a processing pin of a denting device according to an embodiment of the present invention; FIG. 3 is an enlarged perspective view illustrating a distal end of a processing pin of a denting device according to another embodiment of the present invention; FIG. 4 illustrates a planar structure of a denting device according to yet another embodiment of the present invention; FIG. 5 is a plan view illustrating a pattern formed using a denting device according to an embodiment of the present invention; FIG. 6 is a plan view illustrating a pattern formed using a denting device according to another embodiment of the present invention; and FIG. 7 illustrates a sectional structure of a pattern formed using a denting device according to an embodiment of the present invention.

[0036] As illustrated in FIGS. 1 and 2, a denting device according to an embodiment of the present invention includes a seating jig 100, a processing pin 200, a moving unit 300, and a height adjusting support 400.

[0037] The seating jig 100 fixes a valve plate 10 which is an object to be punched and is formed in the shape of a flat plate which is parallel to the moving unit 300 which will be described below.

[0038] Here, the valve plate 10 is used for a compressor, etc., and has an intake hole 11 formed therein to be connected to an intake chamber of a cylinder and a discharge hole 11 formed therein to be connected to a discharge chamber.

[0039] A fixing protrusion 110 which is inserted into the discharge hole 11 and the intake hole 11 when the valve plate 10 is seated is formed on the upper surface of the seating jig 100.

[0040] The fixing protrusion 110 is formed at an interval identical to a distance between the discharge hole 11 and the intake hole 11, guides a location where the valve plate 10 is fixed, and prevents an arbitrarily horizontal movement after fixing.

[0041] In some cases, the seating jig 100 may have a pressing means to prevent the valve plate 10 fixed on the upper surface from being left, and a tilting means capable of adjusting a slope to process a product having a sloped surface, and a vibration prevention means for absorbing vibration to reduce noise generated during processing.

[0042] Meanwhile, the processing pin 200 has the shape of pin elongated in the vertical direction and has a pressing part 210 formed on the lower end thereof to press the valve plate 10 while moving around the discharge hole 11 and the intake hole 11 of the valve plate so as to a circular dent 12.

[0043] As illustrated in FIG. 2, the pressing part 210 has a conic shape in which the diameter of a tip end decreases toward the lower portion, the tip end being rounded.

[0044] Further, as illustrated in FIG. 2, the slope angle (a) of the side surface of the pressing part 210 is 90 degrees.

[0045] Of course, in some cases, the slope angle (a) of the pressing part 210 may be 60 degrees or 120 degrees. When the slope angle (a) is 60 degrees, the diameter of the dent 12 is small and the depth of the dent 12 is deep. When the slope angle (a) is 90 degrees, the diameter of the dent 12 is large and the depth of the dent is shallow.

[0046] Such a pressing part 210 forms the concave circular dent 12 on the valve plate 10 while downwardly moving by the moving unit 300, which will be described below, and forms a pattern 20 formed by the plurality of dents 12 while horizontally moving by the moving unit 300.

[0047] Here, the pattern 20 is filled with oil, and the oil increases the surface roughness of the valve plate 10 to decrease noise and vibration generated during friction of the valve plate 10 using the surface tension of the oil.

[0048] Meanwhile, in some cases, as illustrated in FIG. 3, the pressing part 210 may have the shape of a hexagonal pyramid.

[0049] In detail, the sectional surface of the pressing part 210 is a hexagon and is decreased toward the lower portion, wherein an end thereof is rounded.

[0050] Such a pressing part 210 having the shape of a hexagonal pyramid forms a hexagonal concave dent 12 when pressing the valve plate 10.

[0051] Here, when the shape of the dent 12 is a hexagon, the pattern 20 formed on the valve plate 10, which will be described below, can have the dents 12 as many as possible within the same area while minimizing a surplus space between the dent 12 and the dent 12.

[0052] In this way, since the pressing part 210 has the shape of a hexagon, the dents 12 are formed within the same area as many as possible, so that oil is applied to the entire area while an amount of oil filled in the dents 12 is minimized, thereby maximizing space utilization, improving the stability of the pattern 20, and minimizing the surface tension during friction with a lead.

[0053] Of course, the shape of the pressing part 210 may be a triangle, a quadrangle, a pentagon, etc. in addition to the circle or the hexagon.

[0054] Meanwhile, the moving unit 300 is disposed on the upper portion of the seating jig 100, and moves the processing pin 200 in the horizontal direction at a constant speed while the processing pin 200 reciprocates in the vertical direction at a constant speed, thereby forming a pattern 20 on the valve plate 10.

[0055] That is, the moving unit 300 allows the processing pin 200 to reciprocate in the vertical direction about 10 times per 1 second and move the processing pin 200 in the horizontal direction along a part around the discharge hole 11 and the intake hole 11 by 10 to 80 mm at each second so as to form the plurality of circular concave dents 12 near the discharge hole 11 and the intake hole 11 at a constant interval, thereby forming a pattern 20, which is like a general marking machine.

[0056] Here, the moving unit 300 is operated by a program of driving an XY axis stage step motor to move the processing pint 200 and solely processing a pattern by a CNC.

[0057] Further, the moving unit 300 can, when moving upward/downward, adjust air pressure to adjust the depth of the dent 12.

[0058] Meanwhile, the moving unit 300 can freely adjust the height by the height adjusting support 400.

[0059] The height adjusting support 400 is to adjust an interval between the seating jig 100 and the moving unit 300, is formed by a guide part 410 elongated vertically and an elevating part 420 mounted to be vertically movable along the guide part 410, and vertically moves while the moving unit 300 is mounted to the elevating part 420.

[0060] In this way, in the denting device having the aforementioned configuration according to an embodiment of the present invention, the processing pin 200 is easily mounted to and separated from the moving unit 300. Further, in the case of the conventional mold, when the mold is damaged, a problem that it is difficult to exchange the mold is improved, thereby making the maintenance easier, and the moving speed, the moving direction, the pressure, etc. can be adjusted without replacing the processing pin 200, or various dents 12 and patterns 20 can be formed by changing the shape of a processing part of the processing pin 200.

[0061] Meanwhile, in some cases, the denting device according to the present invention can be configured by an index-type automation system.

[0062] In detail, as illustrated in FIG. 4, in the index-type automation system, the seating jig 100 is formed in a circular shape and turns around on its axis, and a plurality of fixing protrusions 110 are formed on the upper surface of the seating jig 100 along the circumference to fixedly arrange 7 valve plates 10 at a constant interval.

[0063] That is, 7 sets of the fixing protrusions 110 are provided.

[0064] Further, 5 sets are provided and are arranged in the fixing protrusions side by side, respectively, each set including the moving unit 300, the processing pin 200, and the height adjusting support 400.

[0065] The moving unit 300, which constitutes 5 sets, forms the pattern 20 near one of the plurality of intake holes 11 or the plurality of discharge holes 11 formed on the valve plate 10.

[0066] That is, when 3 intake holes 11 and 2 discharge holes 11 are formed on the valve plate 10, one of the moving units 300 forms the pattern 20 near one of the intake holes 11, and another moving unit 300 neighboring it forms the pattern 20 at another intake hole 11 or another discharge hole 11 neighboring the intake hole 11.

[0067] Here, the seating jig 100 is rotated at an interval of about 51 degrees, one valve plate 10 has the pattern 20 formed near the intake hole 11 and the discharge hole 11 while passing through 5 sets of the moving units 300, and in 2 sets of the fixing protrusions 110, an operator withdraws the valve plate 10 and mounts the valve plate 10 again.

[0068] Of course, the withdrawing and the mounting of the valve plate 10 may be performed not manually but automatically using a hydraulic system, and may be performed by a system automatized in a conveyor form.

[0069] In this way, a plurality of fixing protrusions 110 are formed such that a plurality of valve plates 10 are mounted on the upper surface of the seating jig 100, and the pattern 20 is formed by the plurality of moving units 300 and the processing pin 200 while the seating jig 100 is rotated, so that the processing device is automatized, thereby performing a work a little more efficiently and thus improving a productivity.

[0070] Meanwhile, the pattern 20 formed by the processing pin 200 is formed by a plurality of lines L in which a plurality of dents 12 are formed along an outer periphery of the discharge hole 11 and the intake hole 11 while being spaced apart from each other at a predetermined interval. The lines L are arranged to be spaced apart from each other in a direction in which the lines L become farther from the discharge hole 11 or the intake hole 11, and an interval between the lines L is increased as they become farther from the discharge hole 11 and the intake hole 11.

[0071] In more detail, as illustrated in FIG. 5, the pattern 20 is formed by a first section 21, a second section 22, and a third section 23.

[0072] The first section 21 is formed along an outer periphery of the discharge hole 11 or the intake hole 11 and does not have the lines L formed therein.

[0073] That is, the first section 21, the surface of which is not processed from the outer periphery of the discharge hole 11 or the intake hole 11 in a direction in which the lines L become farther therefrom, is formed in a ring shape.

[0074] The width of the first section 21 is formed to be about 0.5 mm.

[0075] The second section 22 corresponds to an interval which is formed on an outer side of the first section 21 and has the plurality of lines L formed therein, and has a ring-shaped pattern 20 obtained by processing a plurality of dents 12 at a predetermined interval along the outer periphery of the first section 21.

[0076] Further, the width of the second section 22 is formed to be about 1.0 mm.

[0077] The second section 22 is an interval which is rubbed with the lead part of the compressor cylinder, and oil is applied thereto, thereby reducing the surface tension while the surface thereof becomes uneven by the shape of the pattern 20 and thus minimizing noise and vibration.

[0078] The third section 23 is an interval which is formed on an outer side of the second section 22 and has the plurality of lines L and in which an interval between the lines L and an interval between the dents 12 are larger than those of the second section 22.

[0079] The second section 23 is not rubbed with the lead parts, is used as an interval in which oil is filled, and has the width of about 2.1 mm.

[0080] Here, it is preferred that an interval between the lines L of the second section 22 is 0.1-0.2 mm and an interval between the lines L of the third section 23 is 0.2-0.5 mm.

[0081] Meanwhile, in some cases, the pattern 20 may be formed by only the second section 22 and the third section 23.

[0082] In this case, as illustrated in FIG. 6, the second section 22 has about 0 to 5 lines L arranged therein outwardly from the outer periphery of the discharge hole 11 or the intake hole 11, and the third section 23 has about 15 lines L arranged therein.

[0083] Of course, the number of lines L can be adjusted from 20 to 50.

[0084] In this way, the interval between the lines L is increased as they become farther from the discharge hole 11 and the intake hole 11, thereby reducing the surface tension of the second section 22 in which friction is directly generated, and thus minimizing noise and vibration and increasing a content of oil on the third section 23.

[0085] Further, as illustrated in FIG. 7, in the dents 12 constituting the line L, only a processed part thereof is formed to be concave and an unprocessed surface thereof is flat, so that the dents 12 can be not easily worn when being rubbed with the lead parts and can maintain a constant height.

[0086] Further, a protrusion 13 protruding by a reaction generated during processing is formed in the periphery of the dents 12, thereby preventing the height from being lowered due to the wear of the existing surface, and increasing the surface roughness to reduce generation of the surface tension.

[0087] Meanwhile, in a denting method for forming the pattern 20, the moving unit 300 is manipulated to perform processing while the processing pine 20 horizontally moves along the outer periphery of the discharge hole 11 and the intake hole 11 and vertically reciprocates at a constant speed.

[0088] Here, the moving units 300 have the same vertical moving speed and the processing pine 200 has an increased horizontal moving speed as they become farther from the discharge hole 11 and the intake hole 11.

[0089] That is, the moving units 300 allow the processing pin 200 to vertically reciprocate 10 times per about 1 second while the processing pin 200 horizontally moves 10-30 mm per about 1 second in the second section 2 and horizontally moves 30-80 mm per about 1 second in the third section 23.

[0090] In this way, the denting method according to an embodiment of the present invention can form various patterns 20 by speeds without replacing equipment such as the processing pin 200, thereby improving the productivity and the efficiency.

[0091] The denting device, the denting method using the same, the pattern thereof according to an embodiment of the present invention, which have the above configurations, use the moving units 300 to form the plurality of dents 12 by the processing pin 200, thereby forming the pattern 20. Further, only the surface of the valve plate 10 is processed, so that the surface is not sharpened and has a smooth curve, thereby preventing the pattern 20 from easily worn during friction with the lead parts, and the protrusion 13 is formed near the dents 12, thereby preventing the height from becoming lower than the existing surface.

[0092] In particular, the processing part has a hexagonal shape and thus the dents 12 can be formed on a constant area as many as possible so as to maximize an oil pocket function and minimize the surface tension, thereby further reducing noise and vibration.

[0093] Further, a program of the moving units 300 is manipulated, thereby forming the pattern 20 having various shapes, the processing pin 200 can be easily replaced, making the maintenance easier, and the shape of the processing part is changed so as to form the dents 12 having various shapes, thereby improving usability.

[0094] The present invention is not limited thereto and can be implemented in various modified forms by those skilled in the art without departing from the technical spirit and scope of the following claims. Accordingly, the modification should be interpreted to be within the scope of the present invention.