KR20130120769A - The manufacturing method of sperical valve and sperical valve thereof - Google Patents

Abstract

The present invention relates to a manufacturing method of a spherical valve and a spherical valve manufactured thereby. According to the present invention, a spherical valve having a spherical surface of the produced spherical valve with a constant curvature like in a concentric sphere is able to be manufactured by pre-molding a spherical valve by using a first mold, and coating the surface of the pre-molded spherical valve with plastic melt by using a second mold in manufacturing a spherical valve. A spherical valve without surface wrinkles, curvature and dents due to the difference in contraction is able to be manufactured. A metal ring member embedded inside the spherical valve is not exposed to the outside of the spherical valve due to the coated plastic melt. Accordingly, the present invention is able to be applicable to a spherical valve requiring accuracy, to drastically increase the reliability upon opening/closing of the conduit line, and to facilitate mass production.

Description

Spherical valve manufacturing method and its products {THE MANUFACTURING METHOD OF SPERICAL VALVE AND SPERICAL VALVE THEREOF}

The present invention relates to a spherical valve manufacturing method and a product which is installed in a path through which a fluid flows in a pump (hereinafter referred to as a "fluid pipe"), and more particularly, to a spherical valve (upper part having a center hole having a center hole, Is a spherical valve having a hemispherical shape, which is referred to as a “spherical valve”, and a method for manufacturing a spherical valve for producing a hemispherical spherical valve having a uniform radius of curvature without being crushed or recessed It is about a product.

In general, a spherical valve or ball valve (ball valve) is coupled to the flow path to control the opening and closing of the pipe, mainly made of synthetic resin material, specific gravity range of 1.1 to 1.2 is useful, manufactured by injection molding using a mold do.

As shown in FIGS. 1 and 2A and 2B, the spherical valve assembly 100 is provided with a spherical valve assembly 100 such that the spherical valve 10 is vertically positioned in the pipe path of the flow path tube 1. When the valve 10 descends due to its own weight, the flow path of the flow path tube 1 is closed, and when the spherical valve 10 floats upward due to buoyancy or pressure of the fluid, the flow path pipe 1 is closed. Since the conduit is opened, the spherical valve 10 can perform the opening and closing function of the conduit normally only higher than the specific gravity of the water.

In FIG. 1 and FIG. 2A, reference numeral 20 denotes a spherical valve housing, 21 denotes a sealing member spirally coupled to outer diameters of both ends of the spherical valve housing 20, and 22 denotes between the sealing member 21 and the spherical valve housing 20. Is assembled to the connection member for connecting the flow path tube 1 and the inside of the spherical valve housing 20, 23 is a sealing member (22) for sealing one side of the spherical valve housing 20 to be watertight. 21 is a retainer for pressurizing the edge portion of the sealing seat 24 which is stretched by the fastening pressure of 21, and 10 is moved up and down along the guide 20b provided in the spherical valve housing 20 of the sealing seat 24. It is a spherical valve for closing the conduit by opening and closing the inner diameter 24a.

The sealing member 21 described above has an inner diameter 22a for receiving the outer diameter of the connecting member 22 and a flange 22b having a diameter larger than the inner diameter 22a, as shown in FIG. 2A. Helix is coupled to the outer diameter of the housing 20.

In addition, the coupling member 22 is squeezed to the spherical valve housing 20 by a helical coupling of the sealing member 21 so as to be watertightly coupled to the spherical valve housing 20, and the connecting pipe 1 and the spherical valve housing 20. Connect

The retainer 23 and the sealing seat 24 are centered through the inner diameter 20b of the spherical valve housing 20. The retainer 23 is made of a synthetic resin material, and the sealing sheet 24 is made of rubber. Made of material.

The inner diameter of the sealing seat 24 is configured to be smaller than the spherical surface 10a of the spherical valve 10 so that the spherical surface 10a of the spherical valve 10 comes into close contact with the inner diameter 24a of the sealing seat 24 or the sealing sheet 24 is closed. When the spherical surface (10a) is spaced apart from the inner diameter (24a) of the ()) the conduit of the spherical valve housing 20 is opened.

As shown in FIG. 2B, the spherical valve 10 is slidably coupled to an outer circumferential surface of the spherical valve 10 to a guide 20b provided to be spaced at an angle to the inner diameter of the spherical valve housing 20.

The present invention relates to the spherical valve manufacturing method of the above-described spherical valve assembly 100 will be described in more detail with respect to the manufacturing method of the spherical valve 10.

As a conventional spherical valve manufacturing method, as shown in Figure 3a, the upper mold 40 is provided with a cavity 41 having a shape corresponding to the spherical valve 10, and guides the plastic melt into the cavity 41. The runner 42a, the branch runner 42b connected to the runner 42a, and the gate 42c are connected to each other, and the lower mold 50 has a center hole in the inner diameter of the spherical valve 10 (see FIG. 4). The center pin 51 for forming (10b, FIG. 2A) is provided.

A metal ring member 11 (see FIG. 2A) for adjusting the specific gravity of the spherical valve 10 (so that the specific gravity of the spherical valve is in the range of 1.1 to 1.5) is arranged around the center pin 51. As shown, the upper and lower molds 40 and 50 are coalesced through the guide posts 43 and the post holes 53, and the plastic melt is injected at a high pressure into the cavity 41 through the gate 42c. After that, when the plastic melt filled in the cavity 41 is solidified, the upper / lower molds 40 and 50 are separated and manufactured by demolding the spherical valve 10 (see FIG. 4) solidified in the cavity 41. In FIG. 3A and FIG. 3B, reference numeral 60 denotes an injection machine for injecting a plastic melt into the cavity 41.

On the other hand, the center pin 51 provided on the lower mold 50 is disposed on the circumferential surface of the metal ring member 11 and then the upper and lower molds 40 and 50 are coalesced into the plastic 41 into the cavity 41. Injecting the metal ring member 11 is embedded in the spherical valve 10 formed as shown in FIG.

However, as shown in FIG. 4, since the spherical valve 10 formed by the mold has a non-uniform thickness for each part of the cavity 41, when the plastic melt is solidified, the difference between the shrinkage rate and the shrinkage rate of each area of the cavity, Insufficient filling of gas or plastic melt causes wrinkles, bends or depressions in the outer circumferential surface or surface of the spherical valve 10 due to hollows in the molding, in particular, the curvature of the spherical surface 10a is not constant. Is generated.

The main reason that the shrinkage failure of the spherical valve 10 is mainly caused by the difference in cooling rate due to the thickness difference in the cavity 41, that is, by the chill action of the metal ring member 11 placed in the cavity 41. Since the cooling rate of the plastic melt in contact with the metal ring member 11 is relatively faster than the thick portion of the cavity 41, the outer peripheral surface or the spherical surface 10a of the spherical valve 10 is recessed due to shrinkage imbalance. There is a problem that the curvature of the spherical surface 10a is not produced uniformly.

If the spherical surface 10a of the spherical valve 10 is not manufactured with a constant curvature, such as a round shape, a gap is generated between the spherical surface 10a and the sealed seat 24 when the spherical surface is in close contact with the sealing seat 24. Fatal defects in which the opening and closing functions of (1) are unreliable are generated.

Therefore, the spherical valve 10 manufactured by injection molding manufactures the finished spherical valve 10 by precisely polishing its surface with a grinder, but it is economical because the mechanical post-processing process is performed separately, and the spherical valve of the spherical valve ( Even though mechanical polishing of 10a) is required, some operations involve manual work, and thus it is difficult to employ spherical valves 10 that require precision because the curvature of the spherical surface 10a is difficult to manufacture into a full hemispherical surface such as a round shape. The disadvantage is that mass production is difficult.

The present invention was invented to solve the problems caused by the conventional manufacturing of the spherical valve as described above. The main object of the present invention is the mass production of the spherical valve in the manufacture of the spherical surface by injection molding by a mold, injection molding The present invention provides a spherical valve manufacturing method and a product which can increase the functional precision of a spherical valve and reliability according to opening and closing of a pipe by manufacturing a spherical valve having the same curvature radius in a round shape even after the post processing is not performed separately.

It is another object of the present invention to secure the metal ring member so that the metal ring member embedded in the spherical valve is accurately inserted at a predetermined position so that the position of the metal ring member is not changed in the spherical valve forming process. It is to provide a spherical valve manufactured so that the ring member is not exposed to the outside of the uniformity and the molded sphere.

Implementation means of the spherical valve manufacturing method according to the present invention,

In the spherical valve manufacturing method,

A first lower mold 220 including a first center pin 221 having a step 222 on which the metal ring member 410 is placed, and a metal ring member coupled to the first center pin 221. A pair of support pins 212b extending from the first upper mold 210 to the surface of the metal ring member 410 is provided to fix the metal ring member 410 while accommodating the 410. After merging the first upper mold 210 including the first cavity 211 having the alignment pin 212a with the first lower mold 220, the plastic melt is introduced into the first cavity 211. After injection and solidifying, demolding the first upper / lower molds 210 and 220 to manufacture the spherical valve 400 preformed in the shape of the first cavity 211;

A second center pin 321 inserted into the first center hole 411 formed by the first center pin 221 and supporting the bottom surface of the preformed spherical valve 400 so as to be spaced apart by a predetermined height; A second lower mold 320 and a second alignment pin 312a inserted into the alignment hole 412 formed by the first alignment pin 212a, and the preformed spherical valve 400 After incorporating the second upper mold 310 constituting the second cavity 311 spaced from the surface with the second lower mold 320 and injecting a plastic melt into the second cavity 311, the preliminary The surface of the molded spherical valve 400 may be formed by coating a plastic melt with a predetermined thickness to form a spherical valve 500 corresponding to the shape of the second cavity 311 by demolding the upper / lower mold.

According to the present invention, in the manufacture of the spherical valve, the preformed spherical valve is first manufactured, and the surface of the manufactured preformed spherical valve is coated with a plastic melt to a certain thickness to manufacture a finished spherical valve. It is possible to manufacture spherical valves with precise spherical surface while overcoming the elements.

In manufacturing the preformed spherical valve, the metal ring member can be accurately embedded in a desired position by fixing the metal ring member with a pair of support pins so as not to move in the first cavity.

When the preformed spherical valve is post-molded into a finished product, by processing the second cavity precisely, a spherical shape having a curvature of roundness can be formed on the surface of the preformed spherical valve, and also when manufacturing the preformed spherical valve. Since the generated shrinkage defects are covered by the plastic melt coated in the manufacturing process of the finished spherical valve, the completed spherical valve can be manufactured with precise spherical valve having spherical curvature equal to the roundness even if the spherical curvature is not further processed after molding. have.

Therefore, the spherical valve manufactured according to the present invention can be processed to a very precise degree of curvature of the spherical surface can be employed in a variety of spherical valves requiring precision as well as do not separately post-processing is simplified and economical There is an effect that can greatly increase the reliability of the opening and closing operation.

1 is an exploded perspective view illustrating a conventional spherical valve assembly
Figure 2a is a longitudinal sectional view illustrating the assembled state of the spherical valve assembly shown in Figure 1,
FIG. 2B is a half sectional view taken along line AA of FIG. 2A;
3A and 3B are cross-sectional views illustrating a state in which a conventional upper / lower mold for spherical valve manufacturing is combined or separated;
4 is a cross-sectional view of a spherical valve manufactured by a conventional spherical valve manufacturing method,
5A and 5B are cross-sectional views illustrating a state in which a first mold for manufacturing a preformed spherical valve according to the present invention is coalesced or separated;
6 is a cross-sectional view of a preformed spherical valve according to the present invention;
7A and 7B are cross-sectional views illustrating a state in which the second mold is combined or separated to complete the preformed spherical valve according to the present invention;
8 is a cross-sectional view of the spherical valve completed by the second mold according to the present invention.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the spherical valve manufacturing method according to the present invention will be described in detail.

5A and 5B, FIGS. 5A and 5B are cross-sectional views illustrating before and after coalescence of a first mold for manufacturing a preformed spherical valve according to the present invention, which is described with reference to FIGS. 3A and 3B. Detailed description of the same configuration as that described above is omitted.

5A and 5B illustrate a mold for preforming the spherical valve prior to manufacturing the finished spherical valve, and the mold for forming the spherical valve preliminarily to manufacture the finished spherical valve as the first mold 200. And a mold for forming the preformed spherical valve into a complete product spherical valve is defined as a second mold 300.

The first mold 200 is composed of upper and lower molds 210 and 220.

The first upper mold 210 has a first cavity 211 corresponding to the shape of the spherical valve 10 (see FIG. 4) and extends toward the first cavity 211 at the center of the first cavity 211. A first alignment pin 212a is provided, and a pair of support pins 212b extending from the first upper mold 210 toward the first cavity 211 at a position adjacent to the first alignment pin 212a is provided. It is provided symmetrically.

The first cavity 211 is provided in a size of 2 to 3 mm smaller than the second cavity 311 provided in the second mold 300 (see FIGS. 7A and 7B) described later.

The first lower mold 220 has a first center pin 221 disposed perpendicular to the first cavity 211.

The first center pin 221 is provided with a step 222 having a relatively large diameter at a predetermined height from the bottom surface of the first lower mold 220.

The step 222 has an outer diameter into which the inner diameter of the metal ring member 410 can be inserted.

In the drawings, reference numerals 213 and 223 denote post holes 223 to which guide posts 213 are coupled to guide both molds without error when the first upper and lower molds 210 and 220 are combined. to be.

As shown in FIG. 5B, the first mold 200 configured as described above incorporates the first upper and lower molds 210 and 220 and injects a plastic melt into the first cavity 211. After the injection molding is solidified in the first cavity 211, the first upper and lower molds 210 and 220 are separated to prepare a preformed spherical valve 400 (see FIG. 6).

The spherical valve 400 manufactured by the first mold 200 has a hemispherical spherical surface 400a formed on one side thereof, and a center hole 411 and a first alignment pin 212a formed by the first center pin 221. A pair of hollow holes 413 formed by separation of the alignment hole 412 and the pair of support pins 212b formed by the two holes are provided.

In addition, since the metal ring member 410 is fixed to the preformed spherical valve 400 by the support pin 212b provided in the first upper mold 210, the plastic melt is injected at a high pressure into the first cavity 211. The metal ring member 410 does not move. Therefore, by the manufacturing method of the preformed spherical valve 400, the metal ring member 410 can be accurately embedded in the spherical valve desired by the manufacturer.

On the other hand, a part of the metal ring member 410 is exposed in the center hole 411 of the preformed spherical valve 400, there may be some shrinkage defects on the circumferential surface or the spherical surface (400a).

As described above, the spherical valve 400 preformed by the first mold 200 is completed by the second mold 300, which will be described in detail.

As shown in FIGS. 7A and 7B, the second mold 300 is composed of a second upper mold 310 and a second lower mold 320 similar to the configuration of the first mold 200. The difference between the mold 300 and the first mold 200 is that the second cavity 311 provided in the second upper mold 310 is 2 to 3 mm larger than the first cavity 211, and the second lower mold is formed. The second center pin 321 provided at 320 is the same as the smallest diameter of the first center hole 411, the length is a little longer and there is no difference in the step without the step 222 (see Fig. 5a) on the circumferential surface, The length of the second alignment pin 312a provided in the center of the second cavity 311 of the upper mold 310 is longer than that of the first alignment pin 212a.

When the first center hole 411 of the preformed spherical valve 400 is coupled to the second center pin 321 provided on the second lower mold 320, the bottom surface of the preformed spherical valve 400 is second. The lower mold 320 is spaced apart from the bottom surface 320a by a predetermined height ((T, see FIG. 7A)).

In the present invention, a distance between the preformed spherical valve 400 and the wall surface of the second cavity 311 and the bottom surface 320a of the second lower mold 320 is 2 to 3 mm apart.

When the preformed spherical valve 400 coupled to the second center pin 321 is coalesced with the second upper / lower mold 310 and 320, the second alignment pin is arranged in the alignment hole 412 of the spherical valve 400. As the 312a is inserted, the preformed spherical valve 400 is fixed in the second cavity 311.

At this time, the separation distance between the preformed spherical valve 400 and the wall surface of the second cavity 311 constitutes a space of about 2 to 3mm.

In this way, the plastic melt is injected into the second cavity 311 of the second upper / lower molds 310 and 320 to be solidified, and then the second upper / lower molds 310 and 320 are separated. It is possible to manufacture a solidified spherical valve 500 as shown.

 In the spherical valve 500 manufactured by the second mold 300, as shown in FIG. 8, the metal ring member 410 exposed through the first center hole 411 (see FIG. 6) is filled with the plastic melt. Therefore, it is not exposed to the outside at all, and the hollow hole 413 (see FIG. 6) is filled with a plastic melt, and the plastic melt is coated with a thickness of 2-3 mm on the entire surface of the preformed spherical valve 400.

Therefore, since the spherical valve 500 manufactured by the second mold 300 has a shrinkage of the plastic melt at about the same time, the outer circumferential surface of the spherical valve 500 and the surface of the spherical surface 500a have no shrinkage defects, and there are no surface wrinkles or bends. Or no distortion occurs, and the spherical surface of the spherical valve 500 is formed by precise processing of the second cavity 311 by manufacturing the spherical valve by covering the entire surface of the preformed spherical valve 400 with a plastic melt. It is possible to manufacture a spherical surface having a constant curvature such as 500a, and since the post-processing of the spherical surface 500a is not required at all, the spherical valve 500 can be easily manufactured in large quantities.

The spherical valve 500 manufactured according to the present invention has an advantage of ensuring reliability according to the opening and closing operation of the pipeline by accurately mating with the valve seat 24 (see FIGS. 1 and 2), and the metal ring member 410. Since the metal ring member 410 is not oxidized since the spherical valve 500 is not exposed out of the spherical valve 500, the durability of the spherical valve 500 may be greatly increased.

In addition, the present invention can omit subsequent processing operations that require precise processing of the spherical surface of the injection-molded spherical valve as in the conventional spherical valve manufacturing, and thus greatly reduce the cost in time and significantly reduce the incidence of defective spherical valves. There is an advantage to this.

On the other hand, when the plastic melt is further coated to a thickness of 1 to 2 mm with a third mold (not shown) on the surface of the spherical valve formed by the second mold 300 as in the second mold, a spherical surface having a more precise spherical surface is formed. In the case of manufacturing a spherical valve, the first mold 200 and the second mold 300 described in the present invention may be manufactured in one mold and the first and second cavities 211 and 311 are respectively provided in the mold. More useful for molding preformed spherical valves into finished products.

200, 300: first mold and second mold
210, 310: first upper mold and second upper mold
220, 320: first upper and lower molds and second lower molds
211, 311: first cavity and second cavity
212a, 312a: first and second alignment pins
212b: support pin
213: Guide Post
221 and 321: first center pin and second center pin
222: step
223: post hole
320a: bottom surface of second lower mold
410: metal ring member
400: preformed spherical valve
400a: spherical surface of preformed spherical valve
411: center ball
412: alignment ball
413: empty hole
500: spherical valve manufactured by the second mold
500a: spherical surface of the spherical valve manufactured by the second mold

Claims (2)

In the spherical valve manufacturing method,
A first lower mold 220 including a first center pin 221 having a step 222 on which the metal ring member 410 is placed, and a metal ring member coupled to the first center pin 221. A pair of support pins 212b extending from the first upper mold 210 to the surface of the metal ring member 410 is provided to fix the metal ring member 410 while accommodating the 410. After merging the first upper mold 210 including the first cavity 211 having the alignment pin 212a with the first lower mold 220, the plastic melt is introduced into the first cavity 211. Manufacturing the spherical valve 400 preformed in the shape of the first cavity 211 by demolding the first upper / lower mold 210 and 220 after injection and solidifying;
A second center pin 321 inserted into the first center hole 411 formed by the first center pin 221 and supporting the bottom surface of the preformed spherical valve 400 so as to be spaced apart by a predetermined height; A second lower mold 320 and a second alignment pin 312a inserted into the alignment hole 412 formed by the first alignment pin 212a, and the preformed spherical valve 400 After incorporating the second upper mold 320 constituting the second cavity 311 spaced from the surface with the second lower mold 310, the plastic melt is injected into the second cavity 311 and then preliminarily Spherical valve manufacturing, characterized in that consisting of forming a spherical valve 500 in the shape of the second cavity 311 by coating the plastic melt on the surface of the molded spherical valve 400 to a predetermined thickness and demolding the upper and lower molds Way. The method of claim 1,
A spherical valve product made according to claim 1.

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