JP2006029400A - Hub for oldham's coupling, oldham's coupling and hub processing equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To process side faces 11, 13 of a projecting part 12 of a hub 10 with high accuracy. <P>SOLUTION: In this hub 10 for an Oldham's coupling, provided with the linear projecting part 12 connected with linear recessed parts 22, 24 formed on a flat plate slider 20, the hub 10 for the Oldham's coupling is formed of a sintered alloy, and both sides faces 11, 13 of the projecting part 12 are processed by being pressed in a state of being held from both sides. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an Oldham coupling hub, Oldham coupling, and hub processing apparatus, and more particularly, to an Oldham coupling hub, Oldham coupling, and hub processing apparatus capable of accurately transmitting a force in the rotational direction.

  Conventionally, Oldham couplings are used to connect shafts of rotating bodies provided in industrial devices such as soldering devices, automobiles, and pumps. The Oldham coupling includes a flat slider in which linear concave portions are formed on both surfaces, and a pair of hubs in which convex portions corresponding to the concave portions of the slider are formed. An Oldham coupling is assembled by positioning a slider between each hub and joining each convex part and each concave part.

  The outline of the hub manufacturing process is roughly divided into the following two processes. In other words, it is divided into a process of forming a convex shape with a sintered alloy or the like, and then a process of processing the coupling surface so that the convex part of the hub can be coupled to the concave part of the slider with a required press fit. Separated. In this processing step, a skilled worker manually cuts both side surfaces of the convex portion with a file or the like so as to be flat.

  However, as described above, when the convex portion is processed manually using a file, the processing accuracy of the side surface of the convex portion is limited, although it is a skilled worker. For this reason, the surface accuracy was not good, and backlash sometimes occurred in the Oldham coupling. Therefore, the yield of Oldham coupling was not high. In particular, if the surface accuracy is not good, the coupling surface between the hub and the slider becomes small, so the friction coefficient between the hub and the slider is large, and there is a disadvantage that they are difficult to slip.

  Furthermore, the processing of the convex portions by manual work has a limit in improving the productivity of the Oldham coupling, and therefore it is difficult to reduce the cost of the Oldham coupling. The low yield of Oldham coupling also spurred difficulties in reducing Oldham coupling costs.

  Further, the Oldham coupling mainly wears the slider when used. For this reason, there is a demand from purchasers of Oldham couplings to purchase only the slider again. However, the slider is generally molded. Molded products vary in product depending on the molding environment. In particular, the product variation is largely due to lots, and also due to molding time. Thus, if only a slider is resold, the slider may not necessarily couple well to a hub that has already been sold. Therefore, at present, the Oldham coupling which is a finished product is sold, and it is difficult to sell the hub and the slider which are parts individually.

  However, the processing of the concave portion of the slider can be performed more easily than the processing of the convex portion of the hub. Therefore, if the side surface of the convex portion of the hub can be processed with high accuracy, it is possible to easily create a slider that is properly coupled to the hub and resell it. In this way, even if the slider wears out, the purchaser purchases the slider sold as a part and replaces it with the one that has been used so far, and the coupling surface between the hub and the slider is large. The reproduction of the Oldham coupling can be realized.

  This invention makes it a subject to process the side surface of the convex part of a hub accurately.

  In order to solve the above-mentioned problems, the Oldham coupling hub of the present invention is formed of a sintered alloy, and sandwiches both side surfaces of the linear protrusion formed on the Oldham coupling hub from both sides. So that it is processed by pressing. Specifically, in order to create the Oldham coupling hub, the processing includes a pair of press portions corresponding to each side surface of the convex portion, a slide mechanism that slides at least one of the press portions, and a press portion. This is performed using the hub processing apparatus of the present invention having a defining portion that defines the slide position. The Oldham coupling of the present invention includes the Oldham coupling hub.

  When the side surface of the convex portion of the hub is processed using the hub processing apparatus of the present invention, the side surface of the convex portion can be adjusted faster and more accurately than when the side surface of the convex portion is cut with a file. Therefore, the surface accuracy of the hub and the slider can be improved. In addition, the productivity of the Oldham coupling can be improved. Furthermore, only hubs or sliders can be sold.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an exploded perspective view of an Oldham coupling 30 according to an embodiment of the present invention. FIG. 1 shows an exploded state of, for example, a cylindrical Oldham coupling 30 that includes a pair of hubs 10 and a flat slider 20 positioned between the hubs 10.

  In the hub 10, a pair of linear protrusions 12 are formed on the first surface of the hub body 14. A through hole 16 is formed from the first surface to the second surface of the hub main body 14 along an axis into which a shaft or the like is inserted. A screw receiver 15 through which a screw (not shown) for connecting the shaft or the like and the hub body 14 is passed is formed on the side surface of the hub 10.

  First, the hub 10 uses a powder of a metal such as stainless steel, iron, copper alloy, or brass to produce a molded product that is an intermediate product using a sintered alloy. Subsequently, at least the surface of the molded product is impregnated with resin. By impregnating the resin, the friction coefficient (slip resistance) of the contact surface between the hub 10 and the slider 20 is reduced, and the ease of sliding between the hub 10 and the slider 20 is ensured. Both side surfaces 11 and 13 of the convex part 12 are processed by pressing so as to be sandwiched from both sides as will be described later. As a result, the side surfaces 11 and 13 have no surface roughness, and the parallelism between them is ensured.

  In the slider 20, linear concave portions 22 and 24 connected to the hub 10 through the convex portions 12 are formed on the first and second surfaces of the slider body 26. The recesses 22 and 24 are formed in directions orthogonal to each other. A through hole 28 corresponding to the through hole 16 is formed from the first surface to the second surface of the slider body 26.

  The slider 20 is made of a resin such as super engineering plastic or plastic. The resin contains a reinforcing agent such as glass or carbon. Thereby, the strength of the slider 20 is secured.

  Since the Oldham coupling 30 includes the hub 10 in which the parallelism between the side surfaces 11 and 13 is ensured and the slider 20 in which the strength is ensured, the Oldham coupling 30 is strong against torque. Furthermore, since the slider 20 has strength, the wear due to use is less than that using a resin as a material, and backlash does not easily occur even when used for a long time.

  FIG. 2 is a schematic configuration diagram of a press portion of the processing device 40 for the convex portion 12 of the hub 10 of the Oldham coupling 30 shown in FIG. 1. The processing device 40 includes a pair of press portions 42 and 44 corresponding to the side surfaces 11 and 13 of the convex portion 12. When the hub 10 is processed, the convex portion 12 is positioned between the press portions 42 and 44. At this time, both side surfaces 11 and 13 are positioned in a manner facing the press portions 42 and 44, respectively.

  The press parts 42 and 44 are attached to the laying tables 41 and 43, respectively. The press parts 42 and 44 are configured to be detachable from the placement tables 41 and 43. For this reason, if a plurality of press portions having different lengths in the short direction are prepared, the length between the side surfaces 11 and 13 of the convex portion 12, that is, the width of the upper surface of the convex portion 12 can be freely changed. Is possible.

  The same effect can be achieved by making the defining portions 48 and 49 described below movable, and can also be achieved by controlling the amount of air injected into the air cylinder below. .

  In this embodiment, the press part 42 is a fixed type, and the press part 44 is a movable type. The press part 42 is being fixed to the processing apparatus 40 main body using the bolt in eight places, for example. The press part 44 is configured to be slidable while being positioned by the guide parts 50 and 51. The press part 44 is slid integrally with a slide part 47 connected on the opposite side to the press part 42.

  The slide part 47 is slid by being powered by an air cylinder, hydraulic cylinder, electric cylinder or the like (not shown). It should be noted that both the press portions 42 and 44 are configured to be slidable, the press portion 42 side is also provided with a slide portion connected to an air cylinder or the like, and pressing is performed simultaneously from both sides of the side surfaces 11 and 13. Good.

  The maximum slide position of the press unit 44 is defined by defining units 48 and 49 that project in the direction perpendicular to the sliding direction. When the power to the slide portion 47 is stopped, the press portion 44 is returned to the position before the slide by the contraction of the pair of spring portions 45 and 46 that are extended at the time of pressing.

  The reason why the side surfaces 11 and 13 can be processed by pressing is that the hub 10 is formed of a sintered alloy. That is, for example, if the hub is formed by using aluminum as a material, the shape of the portion other than the side surface (for example, the through hole 16) is also deformed when the press working is performed. Such a thing may not form the body as an Oldham coupling, but if it is a sintered alloy, since the shape of the through-hole 16 etc. will not deform | transform, it is because the said inconvenience does not arise. is there.

  The force applied to the slide part 47 at the time of pressing may be smaller than when the metal is deformed. Moreover, if the processing apparatus 40 is used, the processing time of the hub 10 will be a short time.

  Note that the processing device 40 may be as small as possible. If it carries out like this, it will become possible to make small the stress distortion concerning the processing apparatus 40 at the time of press work, and the width | variety of the upper surface of the convex part 12 can be prescribed | regulated accurately.

  Actually, when the side surfaces 11 and 13 of the convex portion 12 processed by the processing device 40 shown in FIG. 2 are compared with the side surfaces of the convex portion processed using a file, the convex portion 12 of the hub 10 of the present embodiment is compared. It was found that the side surfaces 11 and 13 had a smaller surface roughness and smoother over the entire side surfaces 11 and 13 than those processed with a file. Also, the manufacturing time for Oldham couplings has been shortened.

  The Oldham coupling of the present invention can be used for industrial devices such as soldering devices, devices such as automobiles, pumps, turbochargers, and boilers that include a rotating body having a shaft. The Oldham coupling of the present invention can also be used for precision positioning parts such as a feed screw driving part, measuring equipment, OA equipment, and semiconductor manufacturing equipment of an NC machine tool.

It is a disassembled perspective view of the coupling of embodiment of this invention. It is a typical block diagram of the press part of the processing apparatus of the convex part of the hub of Oldham coupling shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Hub 11, 13 Side surface 12 Convex part 14 Hub main body 15 Screw receiving 16 Through-hole 20 Slider 22, 24 Recessed part 26 Slider main body 28 Through-hole 30 Oldham coupling 40 Processing apparatus 41, 43 Placement table 42, 44 Press part 45, 46 Spring part 47 Slide part 48, 49 Regulation part 50, 51 Guide part

Claims (7)

In the Oldham coupling hub in which the linear convex portion coupled to the linear concave portion formed on the flat slider is formed,
The Oldham coupling hub is formed of a sintered alloy,
An Oldham coupling hub, wherein both side surfaces of the convex portion are processed by pressing so as to be sandwiched from both sides. 2. The Oldham coupling hub according to claim 1, wherein the Oldham coupling hub is made of stainless steel, iron, copper alloy, or brass. The Oldham coupling hub according to claim 1 or 2, further impregnated with a resin. An Oldham coupling comprising: a pair of Oldham coupling hubs according to any one of claims 1 to 3; and the slider positioned between the Oldham coupling hubs. The Oldham coupling according to claim 4, wherein the slider is made of a resin including super engineering plastic and plastic. The Oldham coupling according to claim 5, wherein the resin is a resin containing a reinforcing agent including glass and carbon. A hub processing apparatus for processing the Oldham coupling hub according to any one of claims 1 to 3,
A pair of press portions corresponding to each side surface of the convex portion;
A slide mechanism for sliding at least one of the press parts;
A defining part for defining the slide position of the press part;
A hub processing apparatus comprising:

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