KR101890739B1 - Apparatus for forming rotation module of mechanical seal - Google Patents

Abstract

The present invention relates to a housing molding device for a mechanical seal rotor module. With the present invention, an insertion protrusion can be easily and uniformly formed in an assembly structure for a rotor module coupled to a stator module for a mechanical seal and a housing constituting the rotor module. The housing molding device is provided to mold a housing constituting a rotor module for a mechanical seal, including a table; a first fixing member mounted on the table; a ring-shaped ring die having a concave groove on the outer peripheral surface and detachably mounted on the front of the first fixing member; and a punch member mounted to be movable upwards and downwards on the table. The housing is inserted into and mounted on the outer peripheral surface of the ring die. In a state where the housing is mounted on the outer peripheral surface of the ring die, the punch member is lowered for press molding of the insertion protrusion corresponding to the concave groove in the housing.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a housing molding device for a mechanical seal rotor module,

The present invention relates to a housing molding apparatus for a mechanical seal rotor module, and more particularly to an assembly structure of a rotor module coupled to a stator module of a mechanical seal, and a method of easily and uniformly forming an insertion projection in a housing constituting such a rotor module And more particularly, to a housing molding apparatus for a mechanical seal rotor module.

The mechanical seal is a surface contact type sealing device for sealing a motor shaft to be coupled with a pump or a turbine of a generator. Specifically, a mechanical seal is formed by a stator which forms two sliding surfaces perpendicular to the motor shaft, Sealing is performed by the oil film, and the rotor is rotated together with the motor shaft so that the sealing with the stator can be continuously maintained by the tension of the spring or the pressure of the fluid.

Such a mechanical seal is an absolutely necessary device for preventing leakage of fluid to the motor, and lubrication of the sliding surface is made by the fluid film formed by itself.

For example, in the case of a mechanical seal used in a slurry pump, when a rotating shaft to which a propeller is connected is rotated, a rotor connected to the rotating shaft rotates together with a minute flow of fluid into a contact portion between the rotor and the stator, do.

As the speed reducer accelerates and decelerates, the rotor vibrates back and forth. At this time, the rotor is elastically supported by the spring so that the sealed state can be maintained.

Thus, the mechanical seal is prevented from being visibly leaked, and the wear of the shaft does not occur, but instead all wear occurs only on the seal face.

In addition, there is an advantage that the sealing can be continuously performed by automatically compensating for the worn portion by the tension of the mounted spring.

Open No. 10-2012-0010394 discloses a technique for such a mechanical seal.

Particularly, in the above prior art, there is a structure in which a groove is formed in a seal face constituting a rotor module of a mechanical seal and a protrusion is formed in the housing to prevent the housing and the seal face from rotating independently of each other by inserting the protrusion into the groove. Respectively.

However, in the conventional mechanical seal of the conventional mechanical seal, the structure for coupling the housing and the seal face so as not to be separated from each other is unclear or complicated, and a simple structure is required to prevent the housing and the seal face from being separated after they are assembled.

In order to allow the seal face and the housing to transmit the rotational force without being relatively rotated, the position of the protrusion formed on the housing is important for engagement with the groove formed in the seal face.

Accordingly, there is a need for a molding apparatus that allows the protrusions formed in the housing to be formed more easily and accurately.

Published Patent No. 10-2012-0010394

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a rotor module of a mechanical seal which is easy to assemble due to a simple structure and can not be arbitrarily separated from each other, And it is an object of the present invention to provide a housing molding device for a mechanical seal rotor module in which formed protrusions (insertion protrusions) can be easily formed and formed at precise positions to improve the productivity and reliability of products.

In order to achieve the above object, a rotor module of a mechanical seal according to the present invention is a rotor module of a mechanical seal coupled to a stator module of a mechanical seal fixed to a main body of a fluid machine, A tangential seal face; A housing in which the other end of the seal face is inserted in one end and a support tab is formed in the other end; A spring disposed inside the housing in a compressed state between the seal face and the support jaw; A snap ring for coupling the seal face and the housing in a compressed state of the spring; And a rotation restricting portion for restricting relative rotation between the seal face and the housing, wherein a seating groove is seated inside the one end of the housing for receiving the snap ring, and the other end of the seal face is engaged with the snap ring, A locking protrusion protruding outward to prevent the seal face from being disassembled in a direction opposite to the spring, the rotation stopper including: an insertion groove formed on an outer circumferential surface of the seal face; And an insertion protrusion which is recessed in the insertion groove direction from the housing and inserted into the insertion groove.

According to another aspect of the present invention, there is provided an apparatus for molding a housing constituting a rotor module of a mechanical seal, comprising: a table; A first fixing member mounted on the table; A ring die having a ring shape and detachably mounted in front of the first fixing member, the ring die having a concave groove formed on an outer peripheral surface thereof; And a punch member movably mounted in an upper portion of the table, wherein the housing is inserted into an outer circumferential surface of the ring die, and in a state in which the housing is mounted on an outer circumferential surface of the ring die, And the member is lowered to press-mold the insertion protrusion corresponding to the concave groove in the housing.

Wherein a plurality of the concave grooves are spaced apart from each other on an outer circumferential surface of the ring die, and the first fixing member rotates the ring die to change a plurality of concave groove positions, The housing mounted on the housing is also rotated.

A support cover which is tightly coupled to the housing in a direction opposite to the first fixing member; And a second fixing member mounted on an upper portion of the table in front of the first fixing member and adapted to tightly couple the support cover to the housing by the second fixing member, And is tightly coupled to the housing to prevent the housing from being separated and separated from the ring die.

The support cover includes: a cover portion that is in surface contact with one surface of the housing; And a contact protrusion protruded from the cover portion and inserted into the housing to closely contact the inner circumferential surface of the housing.

The second fixing member includes: a pressing projection for pushing and pressing the support cover; And a slider for moving the pressing protrusion back and forth in the direction of the support cover.

And a lower support disposed between a lower portion of the ring die and an upper surface of the table and supporting the ring die when the punch member is lowered.

According to the housing molding apparatus of the mechanical seal rotor module of the present invention as described above, the following effects can be obtained.

It is possible to easily assemble and fasten the components constituting the rotor module of the mechanical seal through the fastening structure of the snap ring to prevent the individual components from being separated arbitrarily.

With the molding apparatus of the present invention, the insertion protrusions can be easily formed in the housing constituting the rotor module, and the size, position and angle of the insertion protrusions can be made uniform and uniform, And reliability can be improved.

1 is a perspective view of a rotor module of a mechanical seal according to an embodiment of the present invention,
2 is an exploded perspective view of a rotor module of a mechanical seal according to an embodiment of the present invention,
Fig. 3 is a cross-sectional structure taken along the line AA in Fig. 1,
4 is a perspective view of a housing molding apparatus for a mechanical seal rotor module according to an embodiment of the present invention,
Fig. 5 is a front view of the molding apparatus shown in Fig. 4,
Fig. 6 is an operational view showing a process of preparing the housing of the mechanical seal rotor module by the molding apparatus shown in Fig. 5; Fig.
Fig. 7 is an operational view showing the process of molding the housing in Fig.

FIG. 1 is a perspective view of a rotor module of a mechanical seal according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of a rotor module of a mechanical seal according to an embodiment of the present invention, Fig.

The present invention relates to a rotor module of a mechanical seal coupled to a stator module of a mechanical seal fixedly mounted on a main body of a fluid machine. The rotor module related to the present invention will be described below, And therefore, a detailed description thereof will be omitted.

1 to 3, the rotor module 100 of the mechanical seal of the present invention includes a seal face 110, a housing 120, a spring 130, a snap ring 140, And a stopper 150.

The seal face 110 has a hollow pillar shape and has one end abutted against the stator module of the mechanical seal.

The seal face 110 may be a single piece or may be a combination of several parts.

The housing 120 has a hollow pillar shape with both open ends, and a part of the seal face 110 is inserted and disposed inside the housing 120.

The other end of the seal face 110 is inserted into one end of the housing 120 and a support protrusion 121 is formed inside the other end of the housing 120.

The spring 130 is disposed in a compressed state between the other end of the seal face 110 and the support tab 121 from the inside of the housing 120.

Accordingly, the spring 130 applies a pushing force to the seal face 110 in a direction opposite to the support step 121.

The snap ring 140 couples the seal face 110 and the housing 120 in a state where the spring 130 is compressed.

To this end, a seating groove 122 in which the snap ring 140 is seated is formed at one end of the housing 120.

The other end of the seal face 110 is engaged with the snap ring 140 to prevent the seal face 110 from being disassembled in a direction opposite to the spring 130, .

Therefore, when the snap ring 140 is compressed and seated in the seating groove 122 while the other end of the seal face 110 is inserted into the housing 120, The seal face 110 of the seal face 110 is engaged with the snap ring 140 and the seal face 110 is inserted in the opposite direction of the spring 130 And can be prevented from being separated from the housing 120.

The rotation stopper 150 prevents the seal face 110 and the housing 120 from rotating relative to each other while allowing linear movement of the seal face 110 and the housing 120 independently of each other.

The rotation stopper 150 includes an insertion groove 151 formed in an outer circumferential surface of the seal face 110 and an insertion groove 151 formed in the insertion hole 151 in the housing 120 in the direction of the insertion groove 151, And an insertion protrusion 152 to be inserted.

At this time, it is preferable that the insertion groove 151 and the insertion protrusions 152 are formed in plural numbers so that relative rotation of the seal face 110 and the housing 120 is prevented.

The insertion groove 151 is opened to the other unidirectional side of the seal face 110 where the spring 130 is disposed so that the seal face 110 and the housing 120 are prevented from moving relative to each other .

The components constituting the mechanical seal rotor module 100 not shown in the other drawings are the same as the components used in the known mechanical seal, so a detailed description thereof will be omitted.

In the mechanical seal rotor module 100 of the present invention, the molding device for forming the insertion protrusions 152 in the housing 120 is structured as shown in FIGS. 4 to 7, do.

FIG. 4 is a perspective view of a housing molding apparatus for a mechanical seal rotor module according to an embodiment of the present invention, FIG. 5 is a front view of the molding apparatus shown in FIG. 4, FIG. 7 is an exploded view of the process of forming the housing of the seal rotor module.

The housing molding device of the mechanical seal rotor module of the present invention is an apparatus for molding the housing 120 constituting the rotor module 100 of the mechanical seal described above and includes a table 210 and a first fixing member 220 A ring die 230, a support cover 240, a second fixing member 250, a punch member 260, and the like.

The first fixing member 220 and the second fixing member 250 are mounted on the table 210.

The first fixing member 220 is mounted on the upper portion of the table 210.

The first fixing member 220 is rotatable about an axis disposed in a horizontal direction by an external force.

The ring die 230 is ring-shaped and is detachably mounted in front of the first fixing member 220.

A plurality of concave grooves 231 are formed on the outer peripheral surface of the ring die 230 so as to be spaced apart from each other.

The concave groove 231 is the same as the shape and position of the insertion groove 151 formed in the seal face 110.

The previously manufactured housing 120 is inserted and mounted on the outer peripheral surface of the ring die 230.

The housing 120 has a cylindrical shape with open ends at both ends as described above.

The first fixing member 220 can change the positions of the plurality of concave grooves 231 by rotating the ring die 230 mounted on the front side.

Therefore, the housing 120 mounted on the ring die 230 also rotates when the ring die 230 is rotated by the first fixing member 220.

The punch member 260 is mounted on the table 210 so as to be movable up and down.

The punch member 260 is lowered in a state where the housing 120 is mounted on the outer circumferential surface of the ring die 230 and the insertion protrusion 152 corresponding to the concave groove 231 is formed on the outer circumferential surface of the housing 120, .

The support cover 240 is tightly coupled to the housing 120 in a direction opposite to the first fixing member 220.

The support cover 240 includes a cover portion 241 which is in surface contact with one surface of the housing 120 and a cover portion 241 protruding from the cover portion 241 and inserted into the housing 120, And a contact protruding portion 242 which is in close contact with the inner circumferential surface of the protruding portion 242.

When the support cover 240 is attached to the housing 120, the ring die 230 is inserted into one end of the housing 120 and the contact protrusion 242 of the support cover 240 is inserted into the other end of the housing 120. do.

The second fixing member 250 is mounted on the upper portion of the table 210 at the front of the first fixing member 220 and supports the support cover 240 inserted into the housing 120, (120).

The second fixing member 250 tightly couples the support cover 240 to the other end of the housing 120 to prevent the housing 120 from being separated and separated from the ring die 230 have.

That is, when the punch member 260 is lowered and applied with a force in a state where the housing 120 is mounted on the ring die 230, the housing 120 is pressed by the ring die 230, . ≪ / RTI >

However, when the support cover 240 is mounted on the housing 120 and the second fixing member 250 closely contacts the support cover 240 to the housing 120 as in the present invention, It is possible to prevent the housing 120 from being detached and separated from the ring die 230 even if a force is applied to the housing 120 due to the lowering of the member 260.

The second fixing member 250 for tightly coupling the support cover 240 to the housing 120 includes the pressing protrusion 251 and the slider 252.

The pressing protrusions 251 are arranged in a horizontal direction to push the support cover 240 in the direction of the housing 120.

The slider 252 moves the pressing protrusion 251 back and forth in the direction of the support cover 240 by an external force.

It is preferable that the present invention further includes a lower support 270 disposed between the lower portion of the ring die 230 and the upper surface of the table 210 to support the lower portion of the ring die 230 Do.

The lower support table 270 is disposed between the lower portion of the ring die 230 and the upper surface of the table 210 so that the ring die 230 is not struck downward when the punch member 260 is lowered .

Even if the punch member 260 applies a downward force to the housing 120 and the ring die 230 by supporting the lower portion of the ring die 230 by supporting the lower support 270 as described above, The housing 120 and the ring die 230 may be stuck in the downward direction to prevent the insertion protrusion 152 from being formed at an incorrect position.

The lower support table 270 is vertically movable so that the lower support table 270 is lowered when the ring die 230 rotates to allow the ring die 230 to rotate smoothly, After the ring die 230 is rotated, the lower support 270 rises to support the ring die 230 again.

Referring to the operation of the molding apparatus, the housing 120 is inserted into the ring die 230 as shown in FIG. 6 (a).

6 (b), the support cover 240 is attached to the other end of the housing 120, and the second fixing member 250 is used as shown in FIG. 6 (c) And the support cover 240 is tightly fixed to the other end of the housing 120.

After the one end and the other end of the housing 120 are fixed as described above, the lower support table 270 is raised to support the lower portion of the ring die 230 as shown in FIG. 6 (d).

The punch member 260 is lowered to press the insertion protrusion 152 corresponding to the concave groove 231 on the outer circumferential surface of the housing 120 as shown in FIG.

The lower support table 270 supports the lower portion of the ring die 230 so that the punch member 260 can be pushed by the housing 120 and the ring die 230 even if the punch member 260 presses the housing 120 and the ring die 230. [ The die 230 can be prevented from striking.

After the insertion protrusion 152 is press-formed, the punch member 260 is lifted as shown in FIG. 7 (b).

Then, the ring dies 230 and the housing 120 are rotated using the first fixing member 220 as shown in FIGS. 7 (c) and 7 (d).

At this time, in order to rotate the ring die 230, first, the height of the lower support table 270 is lowered, and the ring die 230 and the housing 120 are rotated.

After the ring die 230 is rotated, the lower support table 270 is raised again so that the lower support table 270 can support the lower portion of the ring die 230.

Then, the punch member 260 is lowered again, and new insertion protrusions 152 are press-formed on the outer circumferential surface of the housing 120.

Accordingly, an insertion protrusion 152 corresponding to the insertion groove 151 formed in the seal face 110 can be formed on the outer circumferential surface of the housing 120.

The insertion protrusions 152 can be easily formed on the outer circumferential surface of the housing 120 and the size, position and angle of the insertion protrusions 152 formed on the plurality of the housings 120 So that the productivity and reliability of the product can be improved.

The housing molding apparatus of the mechanical seal rotor module of the present invention is not limited to the above-described embodiments, but can be variously modified and practiced within the scope of the technical idea of the present invention.

100: Rotor module,
110: seal face, 115: engagement jaw,
120: housing, 121: supporting jaw, 122:
130: spring,
140: snap ring,
150: rotation stopper, 151: insertion groove, 152: insertion protrusion,
210: table,
220: a first fixing member,
230: ring die, 231: concave groove,
240: support cover, 241: cover, 242:
250: second fixing member, 251: pressing projection, 252: slider,
260: punch member,
270: lower support,

Claims (7)

delete delete An apparatus for forming a housing constituting a rotor module of a mechanical seal,
The rotor module of the mechanical seal includes:
1. A rotor module of a mechanical seal coupled to a stator module of a mechanical seal fixedly mounted on a main body of a fluid machine, comprising: a seal face having one end abutting against a stator module of a mechanical seal; A housing in which the other end of the seal face is inserted in one end and a support tab is formed in the other end; A spring disposed inside the housing in a compressed state between the seal face and the support jaw; A snap ring for coupling the seal face and the housing in a compressed state of the spring; And a rotation restricting portion for restricting relative rotation between the seal face and the housing, wherein a seating groove is seated inside the one end of the housing for receiving the snap ring, and the other end of the seal face is engaged with the snap ring, A locking protrusion protruding outward to prevent the seal face from being disassembled in a direction opposite to the spring, the rotation stopper including: an insertion groove formed on an outer circumferential surface of the seal face; And an insertion protrusion which is recessed in the insertion groove direction from the housing and inserted into the insertion groove,
The housing molding device of the mechanical seal rotor module,
A table; A first fixing member mounted on the table; A ring die having a ring shape and detachably mounted in front of the first fixing member, the ring die having a concave groove formed on an outer peripheral surface thereof; And a punch member movably mounted in an upper portion of the table,
The housing is inserted and mounted on the outer peripheral surface of the ring die,
The punch member is lowered in a state that the housing is mounted on the outer circumferential surface of the ring die to press-mold the insertion protrusion corresponding to the concave groove in the housing,
Wherein a plurality of the concave grooves are formed on an outer circumferential surface of the ring die,
Wherein the first fixing member rotates the ring die to change a plurality of the concave groove positions,
Wherein the housing mounted on the ring die is also rotated when the ring die is rotated. The method of claim 3,
A support cover which is tightly coupled to the housing in a direction opposite to the first fixing member;
And a second fixing member mounted on an upper portion of the table at a front side of the first fixing member and tightly coupling the support cover to the housing,
And the support cover is tightly coupled to the housing by the second fixing member to prevent the housing from being separated and separated from the ring die. The method of claim 4,
The support cover
A cover portion which is in surface contact with one surface of the housing;
And a contact protrusion protruded from the cover portion and inserted into the housing to closely contact the inner circumferential surface of the housing. The method of claim 4,
Wherein the second fixing member comprises:
A pressing projection for pushing and pressing the support cover;
And a slider configured to move the pressing protrusion back and forth in the direction of the support cover. The method of claim 3,
And a lower support disposed between a lower portion of the ring die and an upper surface of the table and supporting the ring die when the punch member is lowered,
Wherein the lower support has a vertical height that is variable. ≪ RTI ID = 0.0 > 11. < / RTI >

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