KR20130006110U - Disk coupling - Google Patents

Abstract

The present invention relates to a disk coupling for easily connecting drive shafts and driven shafts having different diameters and absorbing vibration and shock generated between the drive shaft and driven shafts. The disc coupling may include a first shaft insertion hole penetrating a center of two bottom surfaces, at least one first bolt hole formed parallel to the first shaft insertion hole, and a first press-fit pin formed by indenting one of the two bottom surfaces. A cylindrical first coupler having an insertion hole, a disk-shaped first elastic plate disposed adjacent to a bottom surface of the first coupler having a first pressing pin insertion hole, and interposed between the first coupler and the first elastic plate. At least one first bolt through which the head is inserted into the first bolt hole, and the screw part passes through the first elastic plate, and the first elastic plate passes through the first elastic plate and one end is inserted into the first press-fit pin insertion hole. And a first press-fit pin fixed to the first coupler, wherein the first bolt hole is a first section in which the head of the first bolt is inserted, and a second section having an inner diameter smaller than the outer diameter of the head and extending in the first section. Is done.

Description

Disk coupling

The present invention relates to a disc coupling, and more particularly, to a disc coupling that easily connects drive shafts and driven shafts having different diameters and absorbs vibrations and shocks generated between the drive shafts and driven shafts.

In general, a disk coupling is a shaft joint member that transmits power by connecting the shaft to the shaft. The disk coupling is used to reduce vibration, shock, and noise generated during rotation, and a shock absorbing member capable of alleviating shock or vibration is generally inserted between two shafts.

On the other hand, the drive shaft and the driven shaft must be coupled exactly on the same axis to smoothly transmit the rotational force. However, in the industrial field, the driving shaft and the driven shaft are often not exactly positioned on the same axis, and a problem arises in that the driving shaft is damaged unless a flexible shaft coupling member is used in the middle.

To solve this problem, as in Utility Model Registration No. 0249906, a technology has been developed in which a spiral cutting groove is formed in the body of the coupling so that the entire coupling acts as a kind of coil.

However, the coupling of Utility Model Registration No. 0249906 is manufactured by integrally processing one member, and the diameter of the coupling hole to which the drive shaft and the driven shaft are coupled is predetermined. Therefore, when the diameter of the drive shaft and the driven shaft is different, the entire coupling must be replaced, there are a lot of cases in accordance with the combination of the drive shaft and the driven shaft diameter, there was a problem that a number of types of coupling must be prepared in advance.

Korea Utility Model Registration No. 0249906

It is an object of the present invention to provide a disk coupling which easily connects drive shafts and driven shafts having different diameters and absorbs vibrations and shocks generated between the drive shafts and driven shafts.

The technical problems of the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

Disc coupling according to an embodiment of the present invention for achieving the technical problem, a first shaft insertion hole penetrating the center of the two bottom surface, and at least one first bolt formed in parallel with the first shaft insertion hole A disk disposed adjacent to a bottom surface of the first coupler having a cylindrical shape having a hole, a first press pin insertion hole formed by indenting one of the two bottom surfaces, and the first coupler having the first press pin insertion hole formed therein; At least one first bolt interposed between the first elastic plate having a shape, the first coupler and the first elastic plate, a head portion inserted into the first bolt hole, and a screw portion passing through the first elastic plate; And a first pressing pin penetrating the first elastic plate and having one end inserted into the first pressing pin insertion hole to fix the first elastic plate to the first coupler, wherein the first bolt hole is the first bolt hole. Remind of bolt The first section is inserted into the head, and the second section extending to the first section having an inner diameter smaller than the outer diameter of the head.

According to the present invention, two coupling half members are formed by a press-fit method, respectively, and are coupled to each other, so that only a small number of coupling half members can effectively cope with connecting shafts having various diameters.

In addition, it can effectively absorb vibrations and shocks generated during the rotation of the disc coupling at high speed, and prevents the bolts from coming off completely even if some of the bolts are loosened, thereby preventing accidents that may occur. can do.

1 is a perspective view of a disk coupling according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the disk coupling of FIG. 1. FIG.
3 is a cutaway perspective view of the disk coupling of FIG. 1.
4 is a perspective view illustrating a state in which a shaft is coupled to the first coupler of FIG. 2.
FIG. 5 is a front view of the disk coupling of FIG. 1 with the axes of different diameters coupled; FIG.
FIG. 6 is a front view of the disc coupling of FIG. 1 in which axes with shifted central axes are engaged. FIG.
7 to 11 are perspective views for explaining a manufacturing process of the disk coupling according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. It should be understood, however, that the present invention is not limited to the embodiments disclosed herein but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, To the person having the invention, and this invention is only defined by the scope of the claims. In addition, like reference numbers refer to like elements throughout the specification.

Hereinafter, a disk coupling according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3.

1 is a perspective view of a disk coupling according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the disk coupling of FIG. 1, and FIG. 3 is a cutaway perspective view of the disk coupling of FIG. 1.

Disc coupling 1 according to an embodiment of the present invention is a coupling element that can easily connect two shafts having different diameters, and smoothly transmit power even if the two shafts are shifted from each other. The disc coupling 1 largely comprises two coupling half members 10, 20 and a connecting disc 30.

The coupling half members 10 and 20 are elements coupled to either the drive shaft or the driven shaft, and the coupler 110 and 210, the buffer plates 130 and 230, the bolts 120 and 220, and the press-fit pins 10 and 240. ). Coupling half members 10, 20 are coupled to each axis and connected by connecting disks 30 to transmit power.

The coupling half members 10 and 20 have a first coupling half member 10 coupled to the first shaft S1 and a second coupling half member 20 coupled to the second shaft S2. Since the first coupling half member 10 and the second coupling half member 20 are substantially the same except for inner diameters of the first shaft insertion hole 113 and the second shaft insertion hole 213, the present specification In the following, only the first coupling half member 10 will be described.

The first coupler 110 is generally formed in a cylindrical shape and includes a first shaft insertion hole 113 penetrating the center thereof. The first shaft insertion hole 113 is formed through the centers of two bottom surfaces of the cylindrical first coupler 110, and may be formed to be the same as or slightly larger than the outer diameter of the first shaft S1.

The first coupler 110 includes a fixing part 112 constituting a part of the first shaft insertion hole 113 and an elastic part 111 constituting the remainder of the first shaft insertion hole 113. The fixing part 112 is a part that is coupled with the first elastic plate 130, and the elastic part 111 is elastically coupled with the fixing part 112 to serve to compress and fix the first shaft S1.

The fixing part 112 and the elastic part 111 may be integrally formed. For example, when the incision 116 is formed on the cylindrical metal member to form the elastic part 111 and the fixing part 112, the elastic part 111 is connected to the fixing part 112 by a small connection part. It can be combined while maintaining elasticity. Therefore, when a constant external force is applied, the distance between the elastic part 111 and the fixing part 112 can be adjusted. The gap between the elastic part 111 and the fixing part 112 may be adjusted using an adjusting screw (see 117 of FIG. 4).

The elastic portion 111 and the fixing portion 112 respectively form part of the first shaft insertion hole 113, so that the first shaft S1 is inserted into the first shaft insertion hole 113 and the adjustment screw 117 When tightening, the inner diameter of the first shaft insertion hole 113 is reduced, so that the first shaft S1 may be fixed to the first coupler 110. The cutout 116 may be a groove passing through the center of the bottom of the cylinder and a groove cut along the outer circumferential surface of the cylinder. That is, the two grooves meet each other, so that only a predetermined region (connecting portion) of the elastic portion 111 is connected to the fixing portion 112, thereby enabling elastic coupling.

On the other hand, the first coupler 110 is formed with at least one first bolt hole 114 formed in parallel with the first shaft insertion hole 113, and the first pressing pin insertion hole 115 formed by the bottom surface is indented have. The first bolt hole 114 is a space in which the head 121 of the first bolt 120 coupled with the connecting disk 30 is accommodated. The first bolt hole 114 has a first section (see P1 of FIG. 8) into which the head 121 of the first bolt 120 is inserted, and a second section extending from the first section P1 (FIG. 8, see P2).

The first section P1 is a space into which the head 121 of the first bolt 120 is inserted, and the second section P2 is to expose the head 121 of the first bolt 120 to the outside. It becomes a section connecting the first section (P1) and the outside so that. Therefore, the second section P2 is formed to have an inner diameter smaller than the outer diameter of the head 121 of the first bolt 120.

The first section P1 is formed on the surface connected to the first elastic plate 130, and the second section P2 is formed on the opposite side. The second section P2 is a space where a tool for tightening the first bolt 120 accommodated in the first section P1 enters and exits. That is, in order to connect the first coupling half member 10 to the connecting disk 30, the first bolt 120 must be coupled to the connecting disk 30, so that the tool is inserted into the second section P2. The first bolt 120 is tightened.

The first bolt hole 114 may be formed of the first section P1 and the second section P2, and may prevent the first bolt 120 from being completely released. That is, since the first bolt 120 accommodated in the first section P1 cannot escape to the outside through the second section P2, even if the first bolt 120 is partially removed from the connecting disk 30, the first bolt 120 is completely detached. Can be prevented. Therefore, it is possible to prevent an accident in which the first shaft S1 and the second shaft S2 are separated from each other while the machine is in operation.

In addition, by making the second section P2 smaller than the diameter of the first section P1, the first coupler 110 can rotate more smoothly about the first axis S1. That is, when the diameter of the first bolt hole 114 is increased, mass deviation may occur in the first coupler 110, and vibration may occur when the first coupler 110 rotates. However, by minimizing the diameter of the second section P2, the mass deviation of the first coupler 110 may be reduced. In addition, when the first coupler 110 rotates due to the formation of the second section P2, air resistance may be reduced to minimize noise, and the appearance may be simplified to increase the aesthetics.

On the other hand, the first elastic plate 130 is coupled to the first coupler 110 by the first press-fit pin 140. The first elastic plate 130 is coupled to the first coupler 110 and the connecting disk 30 in the shape of a circular disk, thereby acting as a buffer between the first coupler 110 and the connecting disk 30. The first elastic plate 130 acts as a kind of leaf spring so that the first shaft S1 and the second shaft S2 can rotate smoothly even if they are shifted from each other.

The first elastic plate 130 may be fixed to the first coupler 110 using the plurality of first press pins 140. The threaded portion 122 of the first bolt 120 penetrates through the first elastic plate 130 and is coupled to the connecting disk 30.

* The first press-fit pin 140 is formed in the form of a bolt that is not formed with a thread, the press-fit in the first press pin insertion groove 115 formed in the first coupler 110 through the first elastic plate 130 (壓 入) is fixed. At this time, the washer 123 is inserted between the first elastic plate 130 and the first coupler 110 and fixed with the first press-fit pin 140 to thereby fix the first elastic plate 130 and the first coupler 110. The interval between them can be kept constant.

By combining the first coupler 110 and the first elastic plate 130 with the first press-fit pin 140, not only workability is improved, but also can be firmly fixed compared to the use of bolts. Since the shaft joint member is vibrated by a rotating shaft that rotates all the time, a bolt may be unwound and detached in the case of bolt fixing. However, the coupling between the first coupler 110 and the first elastic plate 130 can be firmly coupled to reduce the use of the bolt by using the first press-fit pin 140. In addition, when using the first press-fit pin 140, it is not necessary to use Loctite (bond) to prevent the bolt loosening. It also has the advantage of reducing the number of washers used in the bolt. Meanwhile, the head of the first press pin 140 is inserted into the hole 31 formed in the connecting disk 30.

In addition, even if the first coupling half member 10, the connecting disk 30, and the second coupling half member 20 are fixed by the first bolt 120 and the second bolt 220, the first bolt 120 may be fixed. ) And the second bolt 220 are received in the first section P1 of the first bolt hole 114 and the second bolt hole 214, respectively, so that the first bolt 120 and the second bolt 220 vibrate. Can be prevented from being separated by.

4 is a perspective view illustrating a state in which a shaft is coupled to the first coupler of FIG. 2.

As described above, the first coupler 110 is formed of the fixing portion 112 and the elastic portion 111, the inner diameter of the first shaft insertion hole 113 is changed as the elastic portion 111 moves. Coupling the first shaft (S1) to the first shaft insertion hole 113, and tightening the adjusting screw 117, while reducing the interval of the cutout 116 between the fixing portion 112 and the elastic portion 111, The first shaft S1 is fixed.

FIG. 5 is a front view of the disk coupling of FIG. 1 with the axes of different diameters coupled; FIG.

The disc coupling 1 shown in FIG. 5 shows a shaft coupling between a first shaft S1 and a second shaft S2 having different diameters, and the first shaft S1 having a relatively small diameter has a first axis. The second shaft S2 coupled to the coupling half member 10 and having a relatively large diameter is coupled to the second coupling half member 20 so that the first coupling half member 10 and the second coupling half can be coupled to each other. The member 20 is fixed via the connecting disk 30.

Disc coupling 1 according to an embodiment of the present invention is manufactured in the first coupling half member 10 and the second coupling half member 20 to fit the shaft having a different diameter, and then connected in the field The disk 30 can be combined with each other.

FIG. 6 is a front view of the disc coupling of FIG. 1 in which axes with shifted central axes are engaged. FIG.

When the central axes of the first axis S1 and the second axis S2 do not coincide with each other, vibration may occur, and the disc coupling 1 is subjected to bending stress. In this case, as shown in FIG. 6, the disc coupling 1 is bent to smoothly connect the first axis S1 and the second axis S2.

The first axis S1 and the second axis S2 may be rotated while being refracted within a predetermined range. When a temporary vibration or shock is input, the first axis S1 and the second axis S2 are restored again, and the first axis S1 and the second axis S2 are restored. ) Can be rotated while being aligned on the same axis.

Hereinafter, the manufacturing process of the disc coupling according to an embodiment of the present invention will be described in detail with reference to FIGS. 7 to 11.

7 to 11 are perspective views for explaining a manufacturing process of the disk coupling according to an embodiment of the present invention.

First, referring to FIG. 7, a cylindrical member 100 is prepared. The cylindrical member 100 may be a metal member capable of maintaining sufficient rigidity when the shaft is coupled, and may be a synthetic resin such as plastic having a certain elasticity.

Subsequently, referring to FIG. 8, a first shaft insertion hole 113 is formed to penetrate two bottom surfaces of the cylindrical member 100. The first shaft insertion hole 113 penetrates through the rotation center of the cylindrical member 100. When combined with the shaft, smooth rotation is possible.

In addition, the first bolt hole 114 is formed in parallel with the first shaft insertion hole 113. The first bolt hole 114 may be formed at a symmetrical position with the first shaft insertion hole 113 at the center thereof, thereby minimizing vibration when the disc coupling 1 rotates.

The first bolt hole 114 includes a first section P1 and a second section P2 to first form a hole having a relatively small diameter to form a second section P2, and to form a second section P2. The first section P1 may be formed by increasing the diameter of some sections of P2).

In addition, a first press-fit pin insertion hole 115 is formed on a bottom surface of the bottom surface of the cylindrical member 100 where the first section P1 is exposed. The first press-fit pin insertion hole 115 has a form of an indentation hole formed such that one end of the first press-fit pin 140 may be accommodated.

Subsequently, referring to FIG. 9, the elastic plate 130 penetrates the first press pin 140 and then press-inserts into the first press pin insertion hole 115 to form the first elastic plate 130 in a cylindrical shape 100. ) At this time, the first bolt 120 is inserted and coupled between the cylindrical member 100 and the first elastic plate 130. The first bolt 120 is inserted such that the head 121 is inserted into the cylindrical member 100 and the threaded portion 122 is exposed through the first elastic plate 130.

In addition, a washer 123 is inserted into the first press-fit pin 140 between the cylindrical member 100 and the first elastic plate 130 to form the cylindrical member 100 and the first elastic plate 130. Keep the gap between.

Subsequently, referring to FIG. 10, a cutout 116 is formed in the cylindrical member 100 to complete the first coupling half member 10. The cutout 116 may be formed in a vertical direction to penetrate the first shaft insertion hole 113 so that the first shaft insertion hole 113 is divided into the fixing part 112 and the elastic part 111. However, one end of the fixing part 112 and the elastic part 111 is not completely cut off so that the elastic part 111 and the fixing part 112 are not completely separated by the cutting part 116.

Finally, referring to FIG. 11, the connecting disk 30 is inserted between the first coupling half member 10 and the second coupling half member 20, and the first bolt 120 and the second bolt ( The disk coupling 1 is completed by fixing the elastic plates 130 and 230 and the connecting disk 30 using the 220.

The manufacturing method of the disc coupling 1 described with reference to FIGS. 7 to 11 is not limited to the continuous sequence of FIGS. 7 to 11. For example, before the step of connecting the first elastic plate 130 to the cylindrical member 100 of FIG. 9, the step of forming the cutout 116 of FIG. 10 may be performed first. . Therefore, the present invention is not limited to the above-described manufacturing steps, and may include the steps for manufacturing each component of the disc coupling 1 according to an embodiment of the present invention. There will be.

While the embodiments of the present invention have been described herein with reference to the accompanying drawings, those skilled in the art will appreciate that the present invention can be practiced in other specific forms without departing from the spirit or essential characteristics thereof You will understand. It is to be understood, therefore, that the embodiments described above are not exhaustive in all respects.

1: disc coupling 10: first coupling half member
20: second coupling half member 30: connecting disk
110: first coupler 111: first elastic portion
112: first fixing portion 113: first shaft insertion hole
114: first bolt hole 115: first press-fit pin insertion hole
116: incision 120: first bolt
121: head portion 122: screw portion
123: washer 130: second connecting plate
140: second press-fit pin 210: second coupler
211: second elastic portion 212: second fixing portion
213: second shaft insertion hole 214: bolt hole
215: second press-fit pin insertion hole 220: bolt
230: second connecting plate 240: second press-fit pin

Claims (5)

A first shaft insertion hole penetrating the center of the two bottom surfaces, at least one first bolt hole formed parallel to the first shaft insertion hole, and a first press-fit pin insertion hole formed by indenting any one of the two bottom surfaces; A cylindrical first coupler formed;
A disk-shaped first elastic plate disposed adjacent to a bottom surface of the first coupler where the first press-fit pin insertion hole is formed;
At least one first bolt interposed between the first coupler and the first elastic plate, the head portion being inserted into the first bolt hole, and the screw portion passing through the first elastic plate; And
A first press pin penetrating the first elastic plate and having one end inserted into the first press-fit pin insertion hole to fix the first elastic plate to the first coupler,
The first bolt hole includes a first section in which the head of the first bolt is inserted, and a second section extending in the first section and having an inner diameter smaller than the outer diameter of the head. The method of claim 1,
The first coupler may include a fixing part that forms part of the first shaft insertion hole, an elastic part that forms the remainder of the first shaft insertion hole, and an adjustment screw that adjusts a gap between the fixing part and the elastic part. And a disc coupling, one end of which is elastically coupled to the fixing part. 3. The method of claim 2,
The fixing portion and the elastic portion is integrally formed, the disc coupling is formed between the fixing portion and the elastic portion. The method of claim 1,
A second shaft insertion hole penetrating a center of two bottom surfaces, at least one second bolt hole formed in parallel with the second shaft insertion hole, and a second press-fit pin insertion hole formed by indenting any one of the two bottom surfaces; A formed second coupler having a cylindrical shape;
A disk-shaped second elastic plate disposed adjacent to a bottom surface of the second coupler having the second press-fit pin insertion hole formed therein;
At least one second bolt interposed between the second coupler and the second elastic plate and having a head portion inserted into the second bolt hole and a screw portion passing through the second elastic plate;
A second press-fit pin penetrating the second elastic plate and having one end inserted into the second press-fit pin insertion hole to fix the second elastic plate to the second coupler; And
And a connecting disk interposed between the first elastic plate and the second elastic plate, wherein the connecting disk is coupled to the first elastic plate and the second elastic plate with the first bolt and the second bolt, respectively. Disk coupling. 5. The method of claim 4,
The connecting disk is a disk coupling in which a hole is inserted into the head of the first press-fit pin and the second press-fit pin.

Images