KR20130000764U - structure for joining magnetic gear to shaft - Google Patents

Abstract

The present invention relates to a shaft coupling structure of a magnetic gear, and more particularly, a shaft is conveyored when a magnetic gear is fixed on a shaft such as a drive shaft or a rotating shaft of a conveyor apparatus or some components such as a magnet of a magnetic gear are replaced. A shaft coupling structure of a magnetic gear that makes it possible to axially fix or detach the magnetic gear or some component of the magnetic gear directly without detaching from the device, ie with the shaft mounted on the conveyor device.

Description

Structure for joining magnetic gear to shaft

The present invention relates to a shaft coupling structure of a magnetic gear, and more particularly, a shaft is conveyored when a magnetic gear is fixed on a shaft such as a drive shaft or a rotating shaft of a conveyor apparatus or some components such as a magnet of a magnetic gear are replaced. A shaft coupling structure of a magnetic gear that makes it possible to axially fix or detach the magnetic gear or some component of the magnetic gear directly without detaching from the device, ie with the shaft mounted on the conveyor device.

In general, LCD manufacturing equipment, semiconductor cleaning equipment, pharmaceutical equipment, food manufacturing equipment, PCB transfer equipment, etc., which require high cleaning in preparation for contamination by metal particles, dust, noise, pathogens, etc. The device for delivering the is used.

As a representative example of an apparatus for transmitting power in a non-contact manner using such a magnet, an apparatus for driving a roller in a conveyor apparatus may be mentioned.

The conveyor apparatus includes a magnet opposite to each other on a driving shaft and a rotating shaft, and rotates the driving shaft with a driving source such as a motor, thereby forming a magnetic gear for rotating the rotating shaft by interacting with a magnet provided on the driving shaft and a magnet provided on the rotating shaft. Then, the roller for conveying the object to be transferred is rotated by the rotation of the magnetic gear.

As described above, a method of fixedly coupling a magnet or a roller on a rotating drive shaft or a shaft of a rotating shaft has been proposed in the related art.

Among them, the present inventor has presented Korean Registered Room No. 20-0388034 (2005.06.17; hereinafter referred to as 'prior art 1'). Referring to FIG. 4, the prior art 1 will be described. In the shaft fixing magnet bush (1) for fixing the magnet ring (12) on (30); As a cylindrical shape made of synthetic resin, a magnet fixing part 11 is formed to which the magnet ring 12 is inserted and fixed to one outer circumference, and an outer thread part 14 is formed on the other outer circumference, and the outer thread part 14 A bush body (10) having a fixed length groove (16) formed by cutting at least one point in the inner longitudinal direction from the front end thereof; The inner screw portion 22 is screwed to the outer screw portion 14 of the bush body 10, the inner diameter of the screw thread 23 of the inner screw portion 22 is larger than the outer diameter of the drive shaft or the rotating shaft 30, A shaft fixing nut 20 smaller than the outer diameter of the screw bone 15 of the outer threaded portion 14; .

Prior art 1 of the above characteristics, when screwing the inner threaded portion 22 of the shaft fixing nut 20 to the outer threaded portion 14 of the bush body 10 on the drive shaft or the rotating shaft 30, the bush body 10 The outer screw portion 14, which is separated by an appropriate amount from the tip by the fixing cabinet groove 16 of the crankshaft, is slightly tensioned inward, and the bush body 10 is more firmly fixed to the drive shaft or the rotating shaft 30, thereby to convey the conveyor device. The magnet ring 12 can be easily fastened and fixed without additional extension on the drive shaft or the rotation shaft 30, and the position of the magnet bushing that is screwed according to the size of the object to be conveyed is easily configured.

In addition, as shown in FIG. 5, Japanese Patent Laid-Open No. 2004-262626 (2004.09.24; hereinafter referred to as “prior art 2”) is integrally installed with the support base 16 and the support base 16 on which the transfer object is disposed. Cylindrical roller body 12 is inserted into the rotating shaft 11 and having a fixed portion 17 and the fixed portion 17 of the roller body 12 outside the outer peripheral surface of the fixed portion 17 In the configuration comprising a fixing body 13 to be elastically pressed from the side to abut on the shaft 11, the fixing portion 17 has a tapered shape of a portion of the outer peripheral surface and the male screw is formed on the tapered portion (17a) In addition, the notch 21 is formed by cutting at least one point in the inner longitudinal direction from the tip of the fixing part 17.

In the prior art 2, when the female screw of the fixing body 13 is fastened to the fixing portion 17 of the roller body 12 on the shaft 11, the tip portion is formed by the notch 21 of the roller body 12. The fixed part 17 separated by an appropriate amount is easily deformed in the direction of the shaft 11 and the roller body 12 is firmly fixed to the shaft 11, so that the object to be conveyed is efficiently conveyed between the cleaning devices. In this case, it is possible to easily realize the cleaning equipment for suitably washing the object to be conveyed.

The prior arts 1 and 2 are all screwed in the manner that the components are fixed to the shaft after the components are fitted to the shaft, there is an advantage that the position of the component is easy to move by this screwing, screwing method Inevitably, any one component must be made of one body as a whole because the components that are to be made of one body are not effective in terms of airtightness or durability when they are formed by assembly or the like. In fact, the magnet ring 12 of the prior art 1, the bushing body 10 and the shaft fixing nut 20, the roller body 12 and the fixing body 13 of the prior art 2 are all formed in a cylindrical shape. Since the operation of replacing one of the components formed in the cylindrical shape cannot be carried out directly on the shaft because the component is formed in the cylindrical shape, the entire device configured on one side of the shaft must be dismantled so that one end of the shaft is exposed. The component must then be pulled out through the exposed end of the shaft. In this process, not only the corresponding components but also all other components must be separated from the shaft, so that the replacement work takes too much time, and there is a problem that the productivity is greatly reduced.

Republic of Korea Registration Room No. 20-0388034 (2005.06.17.) JP P2004-262626 A 2004.09.24.

The present invention has been made in view of the above-mentioned problems in the prior art, but the most effective method is to provide a shaft coupling structure of the magnetic gear that can be more economical and simple and yet durable. In particular, it is possible to freely move the position if necessary, and also to remove the shaft from the conveyor when fixing the magnetic gear on a shaft such as a drive shaft or a rotating shaft of the conveyor apparatus or replacing some components such as the magnet of the magnetic gear. That is, the object is to provide a shaft coupling structure of the magnetic gear which is capable of axially fixing or detaching the magnetic gear or some components of the magnetic gear directly with the shaft installed in the conveyor apparatus. In addition, it is another object to provide a shaft coupling structure of the magnetic gear that can ensure the durability of the hinge portion of the shaft fixing body that rotates by the hinge portion.

The shaft coupling structure of the present invention magnetic gear for achieving the above object is a bisected cylindrical magnet installed in the longitudinal direction on a shaft such as a drive shaft or a rotating shaft of the conveyor, and one side rotates by the hinge portion and the other side is separated It is possible to be fixed by a fixing means is characterized in that the base is made of a shaft fixing for fixing the magnet to the shaft.

In addition, the hinge portion of the shaft fixing body is characterized in that the metal sheet is installed to ensure the durability of the rotation operation.

In addition, the coupling surface of the shaft fixing body and the magnet is made of 'c' shape, characterized in that the magnet is inserted into the recess of the 'c' type.

In addition, the anti-rotation body for preventing the rotation of the shaft fixing body with respect to the shaft is characterized in that it further comprises.

The present invention, as described above, does not separate the shaft from the conveyor device when the shaft of the magnetic gear is fixed on the shaft, such as the drive shaft or the rotating shaft of the conveyor device, or replace the magnetic components of the magnetic gear, that is, the shaft is a conveyor It is possible to axially fix or detach the magnetic gear or some components of the magnetic gear directly in the installation.

In addition, there is an advantage that the position shift of the magnetic gear is free as needed.

In addition, the metal plate is inserted into the hinge portion of the shaft fixing body that is rotated by the hinge portion has the advantage that the hinge portion can be prevented from being damaged even during the frequent rotation of the hinge portion.

1 is an exploded perspective view showing a shaft coupling structure of the magnetic gear according to an embodiment of the present invention.
Figure 2 is an exploded perspective view showing a shaft coupling structure of the magnetic gear according to another embodiment of the present invention.
3 is a perspective view of the present combination of FIG.
Figure 4 is a cross-sectional view showing a state that the shaft fixing nut of the prior art 1 is screwed to the bush body.
Figure 5 is an exploded cross-sectional view of the roller body and the fixture of the prior art 2.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, even if the configuration is essential to practice the present invention is described in detail in the known art, or omit the detailed description for obvious matters. In addition, the names and reference numerals given in the present invention are independent of the names and reference numerals given in the above prior arts.

As shown in Figures 1 to 3, the magnetic gear of the present invention is a longitudinally divided cylindrical magnet 10, which is installed on a shaft 1, such as a drive shaft or a rotating shaft of the conveyor, and the magnet 10 It consists of a shaft fixing body 20 for fixing the shaft to the shaft (1).

The magnet 10 has a cylindrical shape divided in the longitudinal direction, that is, the same direction as the axial direction of the shaft 1, and the divided cylindrical shape is formed as a pair of the first magnet 11 and the second magnet 12, respectively. do.

Steps 14 are formed at both ends of the first magnet 11 and the second magnet 12, respectively, and the insertion protrusions 13 protruding from the step 14 are inserted into the shaft fixing body 20. do.

The shaft fixing body 20 forms an insertion groove 23 to insert the insertion protrusions 13 formed on both sides of the first magnet 11 and the second magnet 12 to form the first magnet 11 and the second magnet. The magnet 12 is installed in a pair on both sides of the first magnet 11 and the second magnet 12 so as to be fixed to the shaft (1). That is, the magnet 10 is installed in pairs at both ends of the magnet 10 so as to be fixed to the shaft 1.

The pair of shaft fixing bodies 20 are cylindrical, bisected in the same direction as the axial direction of the shaft 1, so that the first shaft fixing bodies 21 correspond to the first magnets 11 and the second magnets 12. And a second shaft fixing body 22, one side of the first shaft fixing body 21 and the second shaft fixing body 22 in the axial direction and the horizontal direction of the shaft 1 by the hinge portion 24 The through hole 25 is rotatably connected and communicated with each other on the other side of the first shaft fixing body 21 and the second shaft fixing body 22.

In addition, the shaft fixing body 20, that is, the first shaft fixing body 21 and the second shaft fixing body 22 protrude in the direction of the magnet 10 along the outer circumference of the insertion groove 23, and the tip thereof is the magnet. The fixing part 26 is in close contact with the stepped portion 14 of the 10 to fix the magnet 10 to the shaft fixing body 20, and is formed in the direction of the magnet 10 along the inner circumference of the insertion groove 23. A close contact portion 27 which protrudes and whose inner circumferential surface is in close contact with the shaft 1 is preferably formed.

In addition, the hinge portion 24 may be provided integrally with one side end portion of the first shaft fixing body 21 and the second shaft fixing body 22 extending as shown in FIG. 1, and as shown in FIG. 2. It may be composed of a fixing groove 24b formed at one end of each of the shaft fixing body 21 and the second shaft fixing body 22, and a metal thin plate 24a inserted into the fixing groove 24b and rotating. In the latter case, the metal thin plate 24a is preferably made of a material of the STS standard which is a stainless steel standard of the Korean Industrial Standard, and the fixing groove 24b of the first shaft fixing body 21 and the second shaft fixing body 22 is used. Insert injection molding to prevent the hinge portion 24 from being damaged by frequent rotational movement of the hinge portion (24).

In addition, the through hole 25 is inserted into the insertion groove 23 of the magnet 10 into the insertion groove 23 of the shaft fixing body 20 is coupled, and then coupled to the shaft fixing body 20 and the magnet ( 10 is used when the shaft is fixed to the shaft 1, and the fixing means 30 is fixedly coupled to the through hole 25, whereby the shaft fixing body 20 and the magnet 10 are coupled to the shaft 1. It is fixed to the installation. That is, through the through holes 25 and 25 formed to correspond to the first shaft fixing body 21 and the second shaft fixing body 22, bolts and nuts, which are fixing means 30, are preferably coupled to the holes 25 and 25. As a result, the pair of first shaft fasteners 21 and the second shaft fasteners 22 are fixed to the shaft 1 and at the same time between the pair of first shaft fasteners 21 and the second shaft fasteners 22. The magnet 10 coupled to the shaft is also fixed to the shaft (1).

After the shaft fixing body 20 is fixed to the shaft 1, the rotation preventing body 28 may be further provided to prevent the shaft fixing body 20 from rotating about the shaft 1 again. . The anti-rotation body 40 penetrates toward the axis of the shaft 1 on the first shaft fixing body 21 and the second shaft fixing body 22 of the shaft fixing body 20, and has a thread formed on the through surface thereof. (28a) and a stop screw (28b) for screwing into the through hole (28a), and when the stop screw (28b) is screwed through the through hole (28a), the close contact portion (27) is a shaft Closer and tighter coupling to (1) can prevent the shaft fixing body 20 from rotating about the shaft (1). In the present invention has been illustrated that only one rotation preventing body 28 is formed, one or more may be installed as needed.

As described above, in the present invention, the cylindrical magnet 10 as a whole is bisected into the first magnet 11 and the second magnet 12 in the longitudinal direction, and correspondingly, the magnet 10 is connected to the shaft 1. The shaft fixing body 20 for fixing the shaft is also composed of a biaxial cylindrical first shaft fixing body 21 and a second shaft fixing body 22, the bilateral side of the shaft (1) by the hinge portion 24 And through-holes 25 and 25 correspondingly rotatably connected in the horizontal direction and horizontally, and penetrating the first shaft fixing body 21 and the second shaft fixing body 22, respectively, on the other side divided into the two holes. The magnet 10 coupled between the pair of shaft fasteners 20 while simultaneously fixing the pair of shaft fasteners 20 to the shaft 1 through the fixing means 30 that are bolts and nuts. By the configuration to be fixed to the shaft (1), the positional movement of the shaft fixing body 20 and the magnet 10 is free, if necessary, When replacing some components such as the net 10 or the shaft fixing body 20, the magnet 10 or the shaft fixing body is not directly removed from the conveyor apparatus, i.e., the shaft 1 is installed in the conveyor apparatus. It is possible to replace some components such as (10) can shorten the replacement work time, thereby increasing the productivity. In addition, by insert-molding the metal sheet 24a into the hinge portion 24 of the shaft fixing body 20, the hinge portion 24 is not damaged even during frequent rotational movement of the hinge portion 24 due to frequent replacement operations. It can maintain the durability.

1: shaft 10: magnet
11: first magnet 12: second magnet
13: insertion protrusion 14: step
20: shaft fixation 21: first shaft fixation
22: second shaft fixing body 23: insertion groove
24: hinge portion 24a: metal sheet
24b: fixing groove 25: through hole
26: fixed part 27: close part
28: anti-rotation body 28a: through hole
28b: set screw 30: fixing means

Claims (4)

In the magnetic gear which is axially fixed on the shaft (1), such as a drive shaft or a rotating shaft of a conveyor;
A pair of magnets (10) installed on the shaft (1) and having insertion protrusions (13) protruding from the cylindrical tip end portions (14) divided in the longitudinal direction;
Insertion grooves 23 are formed to insert the insertion protrusions 13 of the magnet 10 so as to be coupled to both ends of the magnet 10 in the longitudinal direction, respectively, and nutrient in the same direction as the axial direction of the shaft 1. One side of the cylindrical shape is rotatably connected by the hinge portion 24, the other side forms a through-hole 25 in communication with each other to secure the shaft 10 to the shaft (1) by the fixing means 30 A shaft coupling structure of the magnetic gear, characterized in that consisting of;
The method of claim 1,
The shaft coupling structure of the magnetic gear, characterized in that the hinge portion 24 of the shaft fixing body 20 is inserted into the metal plate (24a) is inserted in order to prevent the hinge portion 24 from being damaged by frequent rotational operation.
The method of claim 1,
The shaft fixing body 20 protrudes along the outer circumference of the insertion groove 23 so that its front end surface is in close contact with the step 14 of the magnet 10 to fix the magnet 10. And a shaft coupling of the magnetic gear, characterized in that it protrudes toward the magnet 10 along the inner circumference of the insertion groove 23 so that the inner circumferential surface thereof is in close contact with the shaft 1. rescue.
The method of claim 1,
An anti-rotation body 28 is further included to prevent the shaft fixing body 20 from rotating relative to the shaft 1, and the anti-rotation body 40 is disposed on the shaft fixing body 20. A shaft coupling structure of a magnetic gear, characterized in that it comprises a through hole (28a) penetrating toward the axis of the screw thread on the through surface and a stop screw (28b) screwed to the through hole (28a).

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