KR20120001442U - Rotary joint - Google Patents

Abstract

The object of the present invention is to provide a high pressure, high flow of fluid and effectively prevent leakage of fluid due to high loads, and to provide a rotary joint that is easy to replace when the housing or the airtight member is damaged.
Rotary joint of the present invention for realizing this, the shaft is made of a cylindrical shape therein a plurality of flow holes in which the fluid is moved; An insertion hole into which the shaft is rotatably inserted is formed therein, and the housing is formed of a combination of a plurality of housing dividers divided into axial and radial directions, and a housing having a plurality of distribution holes communicating with the distribution holes of the shaft. ; Rotation support portions supporting both sides of the shaft such that the shaft is rotatable inside the housing; And an airtight holding member interposed on a contact surface between the shaft and the housing and a contact surface between the housing divider to prevent leakage of the fluid.

Description

Rotary joint {ROTARY JOINT}

The present invention relates to a rotary joint having a plurality of rotary fluid supply passages, and more particularly to a rotary joint that can effectively prevent the leakage of fluid by dispersing a high load when supplying a high pressure, high flow fluid.

In general, a rotary joint is a rotary tube joint device used to supply or discharge fluid from a pipe of a fixed housing to a rotating part of various mechanical devices. For example, steam, hot water, and hot oil for heating a rotating drum, a cylinder, etc. When supplying a heat medium such as water and a refrigerant body such as water, ammonia and freon for cooling, supplying a working medium such as compressed air or hydraulic oil to a rotating device such as a clutch or a brake that operates as a fluid, or a semiconductor It is used for supplying a fluid such as nitrogen gas or a chemical liquid to a nozzle of a cleaning and deposition apparatus for manufacturing.

The rotary joint used for this purpose includes a cylindrical shaft, a housing into which the shaft is rotatably inserted therein, and a rotation support portion rotatably supporting the shaft. A distribution hole, which is a fluid supply line, is formed, and the fluid supplied from the outside is moved to one side of the shaft along the distribution hole formed inside the housing and the shaft, and is configured to be supplied to the rotating parts of various machinery.

The distribution hole is formed with a number corresponding to the type of fluid to be supplied, and when the number of fluids is plural, sealing is provided on the contact surface between the shaft and the housing to prevent the fluid from leaking to the outside while preventing mixing between the supplied fluid. And airtight members such as O-rings are installed.

However, when the fluid supplied through the shaft is a high pressure, high flow rate, a high load load acts in a direction perpendicular to the direction of the central axis of the shaft.

However, the conventional rotary joint has a problem in that the housing has an integral structure, so that the length of the rotary joint corresponding to the number of fluids to be supplied cannot be changed, and a portion of the housing is damaged since a heavy load is applied to the entire housing. Even if there was a problem that the entire housing must be replaced.

In addition, as the housing is integrally constructed, the load acting on the housing cannot be distributed, and the surface load of high load acts on the airtight holding member, so durability is degraded due to frequent breakdown, and the entire shaft and the housing are replaced to replace the broken airtight member. Since all must be separated, there was a problem that the operation is not easy and takes a lot of time.

In addition, the conventional rotary joint has a problem that the durability of the hermetic holding member is weak due to excessive amount of wear of the hermetic holding member during friction between the shaft made of the metal material and the hermetic holding member made of the elastic material.

The present invention is devised to solve the above problems, it is effective to prevent the leakage of fluid by dispersing high load at the time of supply of high pressure, high flow rate fluid, easy replacement work in case of damage to the housing or airtight member The purpose is to provide a rotary joint.

In addition, the present invention is to provide a rotary joint that can improve the durability by minimizing the amount of wear of the airtight holding member provided on the contact surface between the shaft and the housing.

It is also an object of the present invention to provide a rotary joint capable of changing the structure of the housing in response to the increase and decrease of the fluid to be supplied.

Rotary joint of the present invention for realizing the object as described above, the shaft is made of a cylindrical shape therein a shaft formed with a plurality of flow holes for moving the fluid; An insertion hole into which the shaft is rotatably inserted is formed therein, and the housing is formed of a combination of a plurality of housing dividers divided into axial and radial directions, and a housing having a plurality of distribution holes communicating with a distribution hole of the shaft therein. ; Rotation support portions supporting both sides of the shaft such that the shaft is rotatable inside the housing; And an airtight holding member interposed on a contact surface between the shaft and the housing and a contact surface between the housing divider to prevent leakage of the fluid.

The hermetic holding member is characterized in that one or more pairs are provided on both sides of the distribution hole formed through the shaft and the housing.

The joint surface between the plurality of housing dividers is formed so that the stepped to match the central axis to each other to prevent the occurrence of play in the radial direction is coupled to each other.

The outer circumferential surface of the shaft is characterized in that the wear-resistant material is coated.

Both sides of the liquid distribution hole of the distribution hole is characterized in that the liquid discharge hole is further formed to collect the fluid leaking along the contact surface of the shaft and the housing.

According to the rotary joint according to the present invention, the housing is divided into a plurality of housing dividers are configured to be combined with each other to distribute the high load acting on the housing to minimize the damage of the housing and the airtight member, even in case of damage Since only the housing divider and the airtight member installed therein need to be replaced, the replacement work is easy and economical in terms of time and cost.

In addition, according to the present invention, as the wear-resistant material is coated on the outer circumferential surface of the shaft, the wear amount of the hermetic holding member in rotational contact with the shaft can be reduced, thereby improving durability of the hermetic holding member, thereby extending the replacement life.

In addition, according to the present invention, the housing divider can be additionally assembled in response to an increase in the number of supply fluids, so that the housing can be configured, thereby reducing the manufacturing cost as compared with the case of integrally replacing the housing.

1 is a cross-sectional configuration of a rotary joint according to an embodiment of the present invention,
2 is a left side view of FIG. 1;
3 is a right side view of FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional configuration diagram of a rotary joint according to an embodiment of the present invention, FIG. 2 is a left side view of FIG. 1, and FIG. 3 is a right side view of FIG. 1.

Rotary joint according to an embodiment of the present invention, the shaft 100 is formed in a cylindrical shape therein a plurality of flow holes (110, 120) in which the fluid moves in the axial direction, the shaft 100 to be relatively rotatable An insertion hole 201 to be inserted is formed therein, and is made of a combination of housing split bodies 210, 220, and 230 formed in plurality, and housings 200 having a plurality of distribution holes 412, 422, 432, 442 communicating with the distribution holes 110, 120. ), The rotation support parts 310 and 320 supporting both sides of the shaft 100 so that the shaft 100 is rotatable inside the housing 200, and a joint surface between the shaft 100 and the housing 200, and the housing. The airtight holding members 501 to 512 are interposed between the partitions 210, 220, and 230 to prevent leakage of the fluid.

The shaft 100 is composed of a large diameter portion 101 having a substantially cylindrical shape, and a small diameter portion 102 formed at a diameter smaller than the large diameter portion 101 on the right side of the large diameter portion 101, and the large diameter portion 101. The left side of the flange portion 130 having a larger diameter than the large diameter portion 101 is coupled.

As shown in FIG. 2, a plurality of fastening holes 131 to 136 are formed in the flange portion 130 along the circumferential direction, and fastening members such as bolts, which are not shown, form the fastening holes 131 to 136. Coupled to a rotating mechanism (not shown) through which fluid is supplied, the shaft 100 is configured to rotate with the rotating mechanism.

A plurality of gas distribution holes (110, 110a, 110b, 110c, 110d) and the liquid distribution holes (120, 120a) are formed in the shaft 100 along the axial direction, and each of the distribution holes (110, 110a, 110b, The 110c, 110d, 120, and 120a extend to the end side of the large diameter portion 101, and are disposed at predetermined intervals on the same circumference around the central axis of the shaft 100.

Each of the distribution holes 110, 110a, 110b, 110c, 110d, 120, and 120a may be in circumference of the shaft 100 to communicate with the distribution holes 412, 422, 432, 442 formed in the housing 200 when the shaft 100 rotates. It is bent toward the outer side of the direction.

The outer circumferential surface of the shaft 100, specifically, the wear-resistant material is coated on the outer circumferential surface of the shaft 100 of the portion that is in rotational contact with the inner circumferential surface of the insertion hole 201 formed in the housing 200, for example, ceramic The layer may consist of a melt sprayed coating. In addition, the surface of the abrasion-resistant coated shaft 100 is surface treated through ultra-precision grinding to meet the surface roughness required for airtightness.

When the surface of the shaft 100 is coated with a wear resistant material and subjected to ultra-precision grinding, the amount of wear of the airtight holding members 501 to 508 provided on the contact surface between the shaft 100 and the housing 200 may be reduced. Can be.

The shaft 100 is provided with rotation support parts 310 and 320 on the outer circumferential surfaces of the large diameter part 101 and the small diameter part 102 to support the shaft 100 so as to be rotatable inside the housing 200.

The rotation support parts 310 and 320 are preferably configured as bearings for vertical heavy loads capable of withstanding heavy loads acting in a direction perpendicular to the central axis of the shaft 100.

The housing 200 is formed of a combination of a plurality of housing split bodies (210, 220, 230) formed in the axial direction and the radial direction, the gas distribution holes (110, 110a, 110b, 110c, 110d) formed in the shaft 100 therein And gas inflow ports 410, 420, 430, gas distribution holes 412, 422, 432, liquid inlet ports 440, and liquid distribution holes 442 communicating with the liquid distribution holes 120, 120a, respectively.

In the present embodiment, the housing 200 is divided into a first housing divider 210, a second housing divider 220, and a third housing divider 230, and is configured to be combined with each other.

The first housing divider 210 is disposed around the large diameter portion 101 of the shaft 100, and the second housing divider 220 and the third housing divider 230 are disposed on the shaft 100. It is disposed around the neck 102. The first housing divider 210 and the second housing divider 220 are disposed to be in contact with each other in an axial direction, and the third housing divider 230 is inserted into the second housing divider 220. One side surface and the outer peripheral surface of the third housing partition body 230 in the axial direction is joined to one side surface and the inner peripheral surface of the second housing partition body 220 in the axial direction.

The joint surfaces of the first housing divider 210 and the second housing divider 220 are formed so that the stepped portions 211 and 221 are fitted to each other to coincide with a central axis to prevent the occurrence of radial play.

In addition, a fastening portion 240 is formed on an outer circumferential surface of the second housing splitter 220, and the fastening portion 240 has a plurality of fastening holes 241 to 246 along the circumferential direction as shown in FIG. Is formed, a fastening member such as a bolt (not shown) is coupled to and fixed to the frame (not shown) fixed through the fastening holes 241 to 246.

In the present embodiment, the fastening part 240 formed on the second housing split body 220 is coupled to a fixed frame, and the first housing split body 210 and the third housing split body 230 are rotation supporting parts 310 and 320. It is supported by the configuration to limit the axial movement, but the configuration for fixing the housing 200 is not limited to this fastening structure between the first housing partition body 210 and the second housing partition body 220, and the second A fastening structure between the housing divider 220 and the third housing divider 230 may be further provided.

The first housing splitter 210 has a plurality of gas inlet ports 410, 420, 430 and gas distribution holes 412, 422, 432 communicating with each of them corresponding to the gas distribution holes 110, 110a, 110b, 110d of the shaft 100. It is formed at the position. The gas inflow ports 410, 420, 430 and the gas distribution holes 412, 422, 432 may be formed to have different diameters corresponding to the inflow amount of the gas, and may be configured such that different gases are introduced.

The contact surface between the first housing divider 210 and the large diameter portion 101 of the shaft 100 is interposed between the gas distribution holes 412, 422, 432 on both sides of the gas distribution holes 412, 422, 503, 504 and passes through the gas distribution holes 412, 422, 432. The gas is prevented from leaking through the gap between the contact surface of the first housing splitter 210 and the shaft 100.

The hermetic holding members 501, 502, 503 and 504 support the self-weight of the first housing split body 210 and the vertical load acting upon supply of a high pressure and high flow rate of gas, in addition to preventing leakage of gas. The hermetic holding members 501, 502, 503, 504 are formed in a ring shape around the axis of rotation of the shaft 100, and may be configured as quadrangle rings.

The liquid inlet port 440 and the liquid flow hole 442 communicating therewith correspond to the liquid flow holes 120 and 120a of the shaft 100 in the second housing split body 220 and the third housing split body 230. It is formed in the position to become. Both sides of the liquid flow hole 442, the contact surface of the second housing divider 220 and the shaft 100, and the contact surface of the third housing divider 230 and the shaft 100 for airtight to prevent liquid leakage Holding members 505 and 506 are interposed.

The airtight holding members 505 and 506 support the self-weight of the second housing divider 220 and the third housing divider 230 as well as the vertical load acting upon supply of high pressure and high flow rate of liquid. do. The hermetic holding members 505 and 506 are formed in a ring shape centering on the rotation axis of the shaft 100, and may be configured as, for example, high pressure rotating seals.

The contact surface between the second housing divider 220 and the third housing divider 230 is provided with airtight members 509, 510, 511 and 512 for preventing the leakage of liquid, and the airtight members 509, 510, 511 and 512 are O-rings (O-). Ring).

In addition, liquid discharge holes 452 and 462 and liquid discharge ports 450 and 460 connected thereto are formed at both sides of the liquid inflow port 440 and the liquid flow hole 442.

The liquid discharge holes 452 and 462 and the liquid discharge ports 450 and 460 of the second housing split body 220 and the shaft 100 are damaged when the airtight holding members 505 and 506 interposed on both sides of the liquid flow hole 442 are damaged. When the liquid leaks from the contact surface and the contact surface between the third housing divider 230 and the shaft 100, the leaked liquid is collected to make it easy to check whether the liquid leaks from the outside, and the leaked liquid. Prevents leakage to the outside immediately.

In this case, the liquid discharged through the liquid discharge ports 450 and 460 may be configured to be re-introduced back into the liquid inlet port 440.

In addition, airtight holding members 507 and 508 are disposed on both sides of the liquid discharge holes 452 and 462 on the contact surfaces of the second housing divider 220 and the shaft 100, and the contact surfaces of the third housing divider 230 and the shaft 100, respectively. Is further interposed to block the leakage of the liquid discharged through the liquid discharge holes (452,462).

In the present exemplary embodiment, three gas distribution holes 412, 422, 432 and one liquid distribution hole 442 are described as an example. However, when the type of fluid to be supplied is increased, the housing partition is additionally connected and installed. And a shaft having a shape corresponding to the changed shape housing is possible. In this case, there is an advantage that the manufacturing cost of the housing 200 can be reduced by configuring the housing 200 by adding or replacing a part of the housing divider as compared with replacing the entire housing 200.

As described above, in the present invention, the housing 200 is composed of a plurality of divided housing dividers 210, 220, and 230, and the first housing divider 210 and the second housing divider 220 are arranged in an axial direction. Reduce the vertical load acting on the rotary support 310 and the airtight holding members (501, 502, 503, 504) provided inside the first housing split body 210, the second housing split body 220 and the third housing split body 230 ) Is arranged in a radial direction to reduce the vertical load acting on the rotary support 320 and the airtight member (505,506,507,508) to minimize the damage of the airtight member (501,502,503,504,505,506,507,508).

In addition, the combination of the housing divider (210, 220, 230) and the central axis of the natural match with each other can prevent the leakage of fluid due to the occurrence of the gap in the non-uniformity of the central axis, the contact surface and the housing between the shaft 100 and the housing 200 It is possible to effectively prevent the leakage of the fluid in the contact surface between the partitions (210, 220, 230).

In addition, when the liquid is supplied through the liquid distribution hole 442, the liquid discharge holes 452 and 462 provided on both sides of the liquid distribution hole 442 and the liquid discharge ports 450 and 460 facilitate the leakage of the liquid from the outside. It is possible to confirm quickly, and to respond quickly in case of leakage of liquid.

100: shaft 101: large diameter part
102: small diameter portion 110: gas distribution hole
120: liquid distribution hole 130: flange portion
131 ~ 136: fastener 200: housing
201: hole 210: the first housing partition
211,221 step 220: second housing split body
230: third housing split body 240: fastening part
241 ~ 246: Fastener 310,320: Rotating support
410,420,430: Gas inlet port 412,422,432: Gas distribution hole
440: liquid inlet port 442: liquid distribution hole
450,460: Liquid discharge port 452,462: Liquid discharge hole
501 ~ 512: confidentiality member

Claims (5)

A shaft formed in a cylindrical shape and having a plurality of distribution holes through which fluid flows;
An insertion hole into which the shaft is rotatably inserted is formed therein, and the housing is formed of a combination of a plurality of housing dividers divided into axial and radial directions, and a housing having a plurality of distribution holes communicating with the distribution holes of the shaft. ;
Rotation support portions supporting both sides of the shaft such that the shaft is rotatable inside the housing; And
An airtight holding member interposed on a contact surface between the shaft and the housing and a contact surface between the housing divider to prevent leakage of the fluid;
Rotary joint comprising a. The method of claim 1,
The airtight holding member is a rotary joint, characterized in that provided with one or more pairs on both sides of the distribution hole formed through the shaft and the housing. The method of claim 1,
The joint surface between the plurality of housing dividers are formed so that the stepped to match the central axis to each other to prevent the occurrence of play in the radial direction is coupled to each other. The method of claim 1,
A rotary joint, characterized in that the wear-resistant material is coated on the outer peripheral surface of the shaft. The method of claim 1,
And a liquid discharge hole for collecting fluid leaking along the contact surface of the shaft and the housing on both sides of the liquid distribution hole of the distribution hole.

Images