KR200150510Y1 - Pig structure - Google Patents

Abstract

The present invention is to provide a pigtail for the removal of high hardness scale.

It is manufactured to maintain the total density of the pig body within the range of 0.25g / cm³ ~ 0.6g / cm³, and the metal pin placed on one end of the pig body of the metal pins planted on the pig body diameter of the pipe for descaling It is formed in the optimum range according to the change. As a result, when the pipe is provided for descaling work, the pipe cleaning can be more effectively processed without being damaged by the pressure feeding pressure.

Description

Piping Pigment for Hard Scale Removal

1 is a perspective view of a pig (Pig) according to the present invention.

2A-2F are perspective views of various embodiments of the metal pin of the FIG. 1 pig.

3 is a cross-sectional view of a pipe with a built-in pig for explaining the use state of the pig according to the present invention, Figure 3a is a view before the pig is inserted into the pipe, Figure 3b is a view of the state in which the pig is inserted into the pipe and conveyed. .

* Explanation of symbols for main parts of the drawings

10, 20: pig 12, 22: pig body

13, 23a-23d: metal pin h: metal pin head height

a: Metal pin head dimension

The present invention relates to a pig (Pig) used to remove the high hardness scale in the pipe, and particularly relates to a pig for removing the high hardness scale consisting of a plurality of metal pins integrally to the elastic body.

In general, the pigtail to remove the high hardness scale attached to the inner wall of the pipe is made by forcing a high pressure resin, such as polyurethane, with high wear resistance, chemical resistance, and tearing strength. Consists of a metal pin planted in a circumferential direction on a circular body.

As such, the basic structure is simple, but in order to create a product that can actually be used, various complex factors must be examined.

First of all, the density of products that can be made of polyurethane resin varies according to the order of ten thousand, and accordingly, the thermal step strength and hardness vary according to only the ten thousand only. A variety of phenomena are also occurring. Therefore, it is impossible to manufacture a pig with reasonable structure as a method of defining the performance of the product by simply measuring the hardness of the pig body with a test apparatus such as a rubber hardness tester.

Polyurethane foam products, for example, vary in hardness, ranging from the hardness of a normal sponge to a hard solid state with no elasticity, so that metal pins cannot be planted if they are too soft or vice versa. However, when the pig is manufactured on the basis of density, it is possible to obtain an excellent pig product that effectively supports the metal pins.

Because no matter how high the hardness of the pig's epidermis, the metal pins planted in the pig body travel and move inside the tube if the metal pin is not held more strongly by the strong density of the body. This is because they are easily pulled out of the pig body when they collide with the high adhesion to the inner wall, the welding beads formed on the pipe joint, and the high hardness scale attached to the inner wall of the pipe. In this case, the high hardness descaling effect attached to the inner wall of the tube cannot be obtained.

The present invention is to solve the above-mentioned defects and to manufacture the pig body on the basis of the density, to provide a pipe for the pigtail so that the metal pin provided for high-scale descaling work is firmly supported on the pig body.

A feature of the present invention for achieving the above object is a pig body provided in a high hardness scale cleaning operation formed on the inner wall of the pipe, the body having a density of 0.25g / cm³ ~ 0.6g / cm³; And it is in a pig pipe for removing the high-hardness scale including a metal pin planted at regular intervals in the pig body.

Hereinafter, on the basis of the accompanying drawings will be described in detail a more preferred embodiment of the piping pig according to the present invention.

1 is a perspective view showing the appearance of the pipe pig according to the present invention, FIG. 3 is a cross-sectional view of the pipe with a pig built in to explain the state of use of the pipe pig in the display of FIG. It is a figure which shows the state before being inserted, and FIG. 3b is a figure which shows the state in which a pig is inserted and conveyed in piping.

As shown in the figure, the pig 10 according to the present invention is composed of a substantially cylindrical circumferential pig body 12 and metal pins 13 planted at regular intervals along the circumferential wall portion of the pig body 12. The outer diameter D2 of the pig body 12 and the total diameter D1 including the metal pins 13 are formed so that the pig body 12 is effective to effectively remove scale formed in the pipe P2 as shown in FIG. It is formed larger than the inner diameter D of the piping P2 which travels (D1D2D).

When there is no scale on the inner circumferential wall of the pipe P2, the inner diameter D of the pipe P2 itself is the passage dimension of the pipe, and when a large number of scales are formed, the average diameter of the flow path actually remaining considering the thickness of the scale This is the dimension of the passage. Therefore, when the metal pin 13 is not implanted in the pig body 12, the pig body 12 positioned in the pig firing tube P1 is pressed into the running passage of the scale removing pipe P2 to run. This requires a considerable pressure pressure from the pressure pump (P). On the other hand, when the pig 10, in which the metal pins 13 are planted on the pig body 12, is inserted into the pipe P2, the metal pin 13 is moved to the pig body (as shown in FIG. Since it acts as a pressure increasing element up to a great force to push into the inside of 12), the hardness of the pig body 12 and the dimensions of the metal pins 13 have the closest inseparable correlation in the use of such pigs.

Therefore, when the pig 10 is driven through the same inner diameter, it is necessary to adjust the running pressure since the running of the pig 10 becomes impossible when the running pressure of the pig exceeds a given pressure supply pressure that can be supplied. There are two methods for adjusting the running pressure of the pig 10. One of them is a method of molding the density of the pig body 12 to be maintained within a predetermined range. However, there is a difficulty in adjusting the density of the pig body 12 to a certain range. That is, when the density of the pig body 10 falls below a certain level, the metal pins 13 cannot be planted, and even if they are planted, the purpose of planting the metal pins 13 is lost because the metal pins 13 are easily pulled out. In extreme cases, sponges are of low density and cannot be planted with metal pins. On the other hand, if the density is too high, the material becomes hard so that the metal pins 13 do not enter, and the hardness is too high so that even the metal pins 13 are not inserted, the insertion into the pipe P2 is impossible.

For this reason, the present invention is manufactured so that the density of the pig body 12 is maintained in an appropriate range that is not too small or large, that is, 0.25 g / cm 3-0.6 g / cm 3. This allows the pig body 12 to be adjusted so that the running pressure of the pig body 12 is not made larger than the feeding pressure (approximately 20Kg / cm²) by the pump P, and the high hardness scale attached to the pipe P2. This makes the removal more efficient.

Another method of adjusting the running pressure of the pig is to adjust the size of the metal pins that are planted in the pig body. A detailed description thereof will be described in detail with reference to FIG. 2.

2a to 2f are perspective views showing various embodiments of the metal pin of the first degree pig. Fig. 2 shows the pigs 20 integrally installed at regular intervals with the metal pins 23a to 23b having a predetermined shape with respect to the pig body 22. Figs. Among the metal pins 23a to 23b, in particular, the first metal pin 23a positioned at the head of the pig body 22 is circular, elliptical, compared to the other second to fourth metal pins 23b to 23d. It is formed in various shapes such as squares, triangles, hexagons, and cones. The reason is that only one metal pin needs to be in contact with the inner diameter provided as the running passage of the descaling pipe. Therefore, the running pressure of the pig 20 is adjusted by the size of the first metal pin 23a located in the head portion. When the size of the first metal pin 23a is reduced, it may be easily bent or worn, and thus, the first metal pin 23a may be worn out for several meters, and the scraping effect of the scale is lost. . That is, if the head dimension "a" of the first metal pin 23a is too large compared to the diameter of the pipe, the running pressure is rapidly increased, and the dimension "a" of the first metal pin 23a is too small compared to the diameter of the pipe. If there is a lot of gaps inside the pipe, the leakage of the pressurized fluid is large, and if the amount of the pressurized fluid is insufficient, the vehicle stops immediately and causes a serious problem of being blocked in the middle of the pipeline. In addition, if the height "h" of the head of the first metal pin 23a is too high, it not only increases the driving pressure rapidly and greatly, but also easily slips out of the pipe during driving, and is pressed too deep into the pig, so the body of the pig is torn. It loses and loses the cleaning effect of the scale. If the first metal pin 23a is too large, the pressure of the pressurized fluid that pushes the pig back is excessively increased, and in actual cases, there is no corresponding high pressure pump in the field, and the work pressure is exceeded because the design pressure of the pipe is exceeded. It becomes impossible. In case of excessive driving, it may cause a serious problem of being blocked due to inability to run inside the pipe. On the other hand, if the head height "h" of the first metal pin 23a is too low, it is easily pushed into the pig body 22 when it is forcibly inserted into the pipe, and thus there is no adhesive force. It will not be possible to remove the scale by the scraping effect.

Pig 20 according to the present invention is reasonably manufactured in view of these points will be described with reference to the following table.

The table shown above shows the optimum size range of the first metal pins 23a of the pigs shown in FIG. 2 manufactured according to the change in the pipe diameter.

That is, when the size of the metal pin 23a which increases in proportion to the pipe diameter increase according to the above table is a, the effective dimension range of a = 2 + (2n) Where n represents a group fraction proportional to the pipe diameter increase in the table.

Therefore, when n is 1, the metal pin size " a " is 4 to 6 (a) × h in the above table, and the corresponding pipe diameter can be in the range of 20-50 mm, and when n is 2, the value of " a " 8 (a) x h and the pipe diameter is possible in the range of 32-80mm.

On the other hand, the head height "h" of the first metal pin 23a as described above is preferably 80% ^{± 5%} of the size "a" of the metal pin 23a.

The tolerance of 5% here is for adjusting the diameter of the pig and the dimension below the decimal point during processing.

Among the pigs shown in Figs. 2A to 2F, the head having the longest width on the head surface is "a" in the case of an oval, a hexagon, a triangle, or the like, and thus "h" is also determined.

In addition, the use range overlaps in the above table is a range to be adjusted according to the supplyable maximum pressure of the fluid to feed the pig and the capacity of the feeding flow rate. In addition, if the maximum pressure that can be supplied to feed the pigs for the same pipe diameter is low, a small metal pin head is used to reduce the driving pressure even if the cleaning effect is reduced.

On the contrary, if the maximum supply pressure and flow rate are available, the metal pin head size can be increased to increase the scale cleaning effect. If it is out of this category, not only the rapid pressure rise factor and the pressure flow rate are required, but also the pigs are broken immediately while traveling in the pipe, and cannot be used.

Meanwhile, the use of the pigs 20 shown in FIG. 2 is the same as that of FIG.

As described above, according to the present invention, the body of the pig body used for the high hardness scale removing work formed inside the pipe may be molded to a certain range of density, and the size of the metal pin head planted on the pig body may be According to the change, it is possible to enable the optimum dimension, and when it is provided for the descaling work in the pipe, it has the effect of maximizing the scale work in the pipe by adjusting the running pressure of the pig body appropriately. .

Claims (2)

A pig for cleaning a high hardness scale formed on the inner circumferential wall of the pipe, comprising: a plurality of metal pins embedded in the pig body at predetermined intervals; And a pig body having a body density of 0.25g / cm³ to 0.6g / cm³ of polyurethane in order to secure the minimum supporting force by planting the metal pins. The pipe pigtail of claim 1, wherein the head height h of the metal pin is 80% ^{± 5%} of the maximum diameter (a) of the metal pin head.