RU175855U1 - PIPE PLUG - Google Patents

Abstract

The proposed utility model relates to the field of protection of cylindrical pipes from moisture, dirt, debris, mechanical damage to the chamfer or thread during storage, transportation, preparation for use and installation. In particular, this utility model relates to a plug for protecting pipes used in the oil and gas industries and for transporting oil, gas and oil products. A plug for protecting a pipe made of oxo-biodegradable polymer material is proposed, the plug comprising: an external hollow cylindrical element , an inner hollow cylindrical element located inside the outer cylindrical element with the formation of a gap between the walls of the outer and inner cylindrical elements, the base e, having a circular shape and covering the lower end of the inner cylindrical element with the formation of the first connection angles, and the upper annular element connecting the upper ends of the external and internal cylindrical elements with the formation of the second connection angles. (Figure 1)

Description

FIELD OF TECHNOLOGY TO WHICH A USEFUL MODEL IS

This utility model relates to the field of protection of cylindrical pipes from moisture, dirt, debris, mechanical damage to the chamfer or thread during storage, transportation, preparation for use and installation. In particular, this utility model relates to a plug for protecting pipes used in the oil and gas industries and in the transportation of oil, gas and oil products.

BACKGROUND

In the prior art there are many different protective devices used to protect the inner and outer surfaces of pipes or other cylindrical products. Protective devices are mainly made of polymeric materials or, less commonly, of metal. Recently, a very serious question has arisen regarding the protection of the environment from human exposure. In many areas of industry, manufacturers, as far as possible, try to switch to materials that do not pollute the environment or pollute the environment to a lesser extent.

The above also applies to pipe manufacturers and pipe protection devices. This fact especially applies to the oil and gas industry, industries related to the transportation of oil, gas and oil products, since the disposal of used disposable (or even reusable) products, including pipe protection devices in the form of plugs, caps, plugs, is long and costly due to the remoteness of the targets. Thus, for the disposal of waste disposable materials, it is necessary to collect, load, transport, followed by disposal.

Currently, the use of oxo-biodegradable materials is promising in the production of various industrial and everyday products. Oxy-biodegradation, unlike other types of decomposition of the material, includes the effect on the bio-biodegradable material of several factors at once, such as oxidation, light (in particular UV light), moisture, temperature and exposure to microorganisms in the environment especially in the soil. Thus, when developing products from oxo-biodegradable materials, attention should be paid not only to the oxo-biodegradable material itself, but also to its design, structure and shape in order to provide exposure factors with the best conditions and opportunities for decomposition of the product.

In the prior art, from document CN205678348 (published 09.11.2016, IPC F16L 55/10, F16L 55/18), a pipe plug is known that comprises an annular sealing plate with a plurality of support elements having recesses near the annular sealing plate and connected by a reinforcing ring, this annular sealing plate, the supporting elements and the reinforcing ring are made of material degradable by moisture. The disadvantage of this technical solution is the fact that the plug material decomposes only under the influence of moisture. Thus, in some cases, the plug will practically not decompose or will decompose too long (for example, in arid regions or areas characterized by prolonged frosts).

In the prior art from the document DE202006019193 (publ. 05/31/2007, IPC F16L 57/00, F16L 58/00) a protective element for the pipe, made in the form of a plug or cap. The security element is threaded on the outer surface or on the inner surface. In a preferred embodiment, the security element is slidably mounted on the pipe. The specified protective element is made of biodegradable material. The disadvantage of this technical solution is the implementation of the protective element from biodegradable material, implying decomposition only as a result of the activity of living organisms, which leads to a rather long process of disposal.

The closest analogue of this utility model is the technical solution disclosed in document CN106586244 (publ. 04/26/2017, IPC B65D 59/06, B65D 65/46). The technical solution relates to a pipe thread protection device comprising a hollow cylinder, the outer surface of which includes a layer of biodegradable material. The disadvantage of this technical solution is that the device contains only a layer of biodegradable material, so that the rest of the device will not be subject to decomposition to a large extent, thereby polluting the environment and, preferably, requiring additional disposal. Additionally, as well as other sources of the aforementioned prior art, technical solution CN106586244 does not mention the importance of the structural design of the device for protecting the pipe, plugs for a more complete and proper decomposition of the product. Thus, the device according to CN106586244 is only a hollow cylinder, the impact of microorganisms on which is limited due to the smooth structure and relatively small area of contact with biodegradation factors.

Thus, in the prior art there is a problem of creating a device for protecting the pipe, which would be made of oxo-biodegradable material and at the same time would have a structure that provides the most rational decomposition of the device while maintaining functionality regarding the protection of the pipe. Having such a device, it is possible to solve the problem of environmental pollution and significantly reduce the cost of disposal.

DISCLOSURE OF THE ESSENCE OF A USEFUL MODEL

The authors of this utility model have found that it is desirable that from the time the plug was manufactured to the moment of its complete decomposition in natural conditions, approximately seven years would pass.

The technical result achieved by the present utility model is the implementation of a plug for protecting a pipe from oxo-biodegradable material and imparting to the plug for protecting the pipe a structure that in combination would ensure complete decomposition of the plug by oxo-biodegradation after approximately seven years. Thus, the oxo-biodegradable material and the special structure of the stub work in combination to provide the necessary characteristics of oxo-biodegradation, namely, to ensure complete decomposition of the stub by oxo-biodegradation after approximately seven years.

The above technical problem is solved and the technical result is achieved by means of a real utility model.

The present utility model claims a plug for protecting a pipe made of an oxo-biodegradable polymer material, the plug comprising:

- external hollow cylindrical element,

- an inner hollow cylindrical element located inside the outer cylindrical element with the formation of a gap between the walls of the outer and inner cylindrical elements,

- a base made in the shape of a circle and covering the lower end of the inner cylindrical element with the formation of the first connection angles, and

- the upper annular element connecting the upper ends of the outer and inner cylindrical elements with the formation of the second connection angles.

In one embodiment of the present utility model, the wall thicknesses of the inner and outer cylindrical elements are from 2 to 4 mm.

In another embodiment of the present utility model, the surface of the plug has a roughness of 10 μm to 40 μm.

In one embodiment of the present utility model, the base comprises from 1 to 3 through holes.

In yet another embodiment of the present utility model, the upper ends of the outer and inner cylindrical elements are rounded.

In one embodiment of the present utility model, the lower end of the inner cylindrical element is rounded.

In an additional embodiment of the present utility model, the length of the outer cylindrical element is from 10 to 120 mm.

In one embodiment of the present utility model, the length of the inner cylindrical element is from 20 to 85 mm.

In one embodiment of the present utility model, an oxo-biodegradable polymer material comprises an oxo-biodegradable additive.

In one embodiment of the present utility model, the oxo-biodegradable polymer material is polyethylene containing an oxo-biodegradable additive.

In one embodiment of the present utility model, a polyethylene containing an oxo biodegradable additive is a high density polyethylene containing an oxo biodegradable additive.

In one embodiment of the present utility model, polyethylene containing an oxo biodegradable additive is a low density polyethylene containing an oxo biodegradable additive.

In one embodiment of the present utility model, the oxo-biodegradable additive is from 2 to 3% by weight relative to the total weight of the polymeric material, for example, polyethylene.

In one embodiment of the present utility model, 1 to 3 through holes are spaced 100 mm from the wall of the inner cylindrical element.

Thus, the implementation of the stub from oxo-biodegradable material and giving it a special shape complement each other to ensure the specified technical result.

BRIEF DESCRIPTION OF THE DRAWINGS

The proposed utility model is illustrated in the drawings, in which:

figure 1 schematically shows a General view of the proposed plugs;

figure 2 schematically shows the plug of figure 1 in a side view in cross section.

IMPLEMENTATION OF A USEFUL MODEL

Figures 1 and 2 show an embodiment of the present utility model. Figure 1 presents the plug 1 to protect the pipe. The plug 1 contains an external hollow cylindrical element 2, an internal hollow cylindrical element 3 located inside the outer cylindrical element 2 with the formation of a gap between the walls of these outer and inner cylindrical elements. This gap is designed to hold the walls of a cylindrical product, such as a pipe. Also, the cap 1 comprises a base 5 having a circular shape and covering the lower end 7 of the inner cylindrical element 3. In the upper part of the cap is an upper annular element 4 connecting the upper end of the outer cylindrical element 2 and the upper end of the inner cylindrical element 3. In FIG. 2 is a cross-sectional side view of the plug 1 illustrated in FIG. 1. As can be seen from figure 2, the upper annular element 4 connects the upper end 8 of the inner cylindrical element 3 and the upper end 9 of the outer cylindrical element 2, while the base 5 closes the lower end 7 of the inner cylindrical element 3.

During installation, the plug 1 is slidably mounted on the outer surface of the pipe so that the outer surface of the pipe wall is in contact with the inner surface of the wall of the outer cylindrical element 2, while the inner surface of the pipe wall is in contact with the outer surface of the wall of the inner cylindrical element. Thus, after installing the plug 1, the base 5 tightly plugs the pipe to protect it from moisture, dirt, mechanical debris, while the walls of the external and internal cylindrical elements (2, 3) protect the chamfer (s) and / or thread located on internal or external surface of the pipe wall.

As indicated, there is a need in the art for a plug to protect the pipe, which could undergo complete decomposition by oxo-biodegradation.

The authors of this utility model found that the shape of the product (i.e., plugs), along with the manufacture of the product from oxo-biodegradable material, significantly affects the decomposition of the product through oxo-biodegradation, since during oxo-biodegradation, they immediately participate in the decomposition process many factors: oxidation by ambient air, light (in particular UV light), moisture, temperature and exposure to microorganisms in the environment, in particular bacteria in the soil. Thus, the special shape of the product and the implementation of the product from oxo-biodegradable material complement each other to solve the problems of the prior art.

The authors of this utility model found that the implementation of the plug with a cross section in the form of some similarity to the letter "M" (see figure 2) and its implementation with large open areas allows you to expose the plug to the necessary effects of oxo-biodegradation.

After completion of the use of plugs, for example, during oil or gas production activities, used plugs of oxo-biodegradable material are stored in an open area of the earth, exposing them to the environment. Over time, due to precipitation or other influences, the used stubs begin to go under the soil, as a result of which the soil is retained in them, providing decomposition by microorganisms.

The presence of external and internal cylindrical elements 2, 3 provide a large open surface for exposure to ambient air (oxidation process), UV light and temperature, which contributes to a more rapid and uniform decomposition of the plug. The cylindrical shape provides uniform exposure to ambient air and UV light to achieve uniform and complete decomposition of the plug.

The presence of the base 5 in the form of a circle also provides a large area for exposure to ambient air and UV light. At the same time, due to the presence of the connection angles 10 shown in FIG. 2 formed by the wall of the inner cylindrical element 3 and the base 5, niches are provided in which moisture and soil are retained, containing microbial stub decomposing material. The retention of moisture and soil in these niches formed by the corners 10 of the connection, allows you to provide the necessary decomposition process in these areas and further throughout the plug. A similar action is provided and observed in the corners 11 of the connection shown in figure 2, formed by the upper ends 8,9 and the annular element 4. The authors of this utility model found that in the areas of connection of the elements, i.e. in the corners of the joint formed by the elements of the plug, the decomposition of the material occurs in the fastest way due to the presence of a higher concentration of internal stresses in the material. Thus, due to the accumulation of moisture, soil, providing oxo-biodegradation of the material, and the presence of stresses, upon decomposition, the plug is thinned at the corners 10 and 11 of the joint, thereby the plug is divided into several parts over time, which ensures its decomposition as necessary.

The gaps located between the outer and inner cylindrical elements also ensure the accumulation of moisture and soil, which allows to achieve the necessary decomposition of the plug through oxo-biodegradation.

Thus, in the manufacture of plugs from oxo-biodegradable material, the presence of large cylindrical surfaces of the external, internal cylindrical elements and the presence of a large flat surface of the base provide the necessary exposure to ambient air, UV light and temperature. At the same time, the presence of connections between the inner cylindrical element and the base, and the presence of connections between the outer and inner cylindrical elements by means of the upper ring element, provide angles and niches due to which moisture and soil are trapped in the plug, which also provide the necessary degree of decomposition.

At the same time, it should be noted that the manufacture of plugs from traditional plastic materials or metal does not provide the necessary decomposition. Thus, the plug must be made of oxo-biodegradable material.

The oxo-biodegradable material according to the present utility model can be made of a polyolefin material, such as high density polyethylene, low density polyethylene, polyethylene terephthalate, polypropylene, with the addition of an oxo biodegradable additive, filler. Oxo-biodegradable additives and fillers are biodegradable polymers based on polylactides, polydioxanone, -caprolactone, glycolide and their copolymers containing transition metals such as iron, magnesium, cobalt, nickel, which are added to accelerate natural oxidative degradation. Additionally, the oxo-biodegradable material according to the present utility model may be made from organically modified clays.

The authors of this utility model found that the implementation of the stub from oxo-biodegradable material and giving it a special shape, as described above, provide the necessary decomposition by oxo-biodegradation for about seven years.

Further, it should be noted that it is preferable to further improve the decomposition of the plugs, the walls of the inner and outer cylindrical elements should be performed with a thickness of from 2 to 4 mm. This wall thickness ensures complete decomposition of the plug while maintaining the necessary strength to function as a protective device.

Also, the authors found that the surface roughness of the plug also affects its ability to oxo-biodegradation. Thus, preferably, the surface roughness of the plug is from 10 μm to 40 μm. With less roughness, the surface of the plug will be too smooth, as a result of which the moisture necessary for decomposition and soil particles carrying microorganisms will not be retained on the surface. Moreover, with greater roughness, the surface of the plug will tend to become contaminated, which is undesirable due to its too rapid decomposition, which can lead to its decomposition directly on the pipe being protected. In addition, the large roughness complicates the process of installing the plug on the pipe and removing it from the pipe.

As can be seen from FIG. 1, the base 5 may have through holes 6. The authors of this utility model have found that making 1 to 3 holes in the base also promotes oxo-biodegradation, as it provides moisture and soil to the interior of the plug during storage after use, as well as provides additional areas with increased tension in which rupture of the plug may occur.

Also, the authors came to the conclusion that the implementation of the upper ends of the outer and inner cylindrical elements and the lower end of the inner cylindrical element rounded allows to reduce the reflection of sunlight (or UV light). As a result, the temperature of the plug when exposed to sunlight will be slightly higher than if the ends of the elements were made with clear sharp edges. Higher temperatures contribute to better decomposition of the plug, due to the beneficial effects on microorganisms and the destruction of the main chains in the polymer material of the plug.

Additionally, it should be noted that the implementation of the outer cylindrical element and the inner cylindrical element with a length of from 10 to 120 mm and from 20 to 85 mm, respectively, allows you to perform a plug, which can function as a protective device, while it has a reduced mass. The reduced mass leads to the necessary degree and speed of decomposition, i.e. to complete decomposition after approximately 7 years.

As indicated above, an indispensable condition of this utility model is the implementation of the stub from oxo-biodegradable material. The inventors of the present invention have found that the addition of an oxo-biodegradable additive in an amount of 2 to 3% by weight relative to the total weight of the polymeric material (for example, polyethylene or other polyolefins) provides the necessary degree and rate of decomposition of the material by oxo-biodegradation.

Pipe protection plugs according to the present utility model can be manufactured by conventional conventional methods for producing articles from polymeric materials, such as extrusion, pressing, injection molding, vacuum molding, and other known methods of molding polymer materials into articles. At the same time, in the production of plugs, the required amount (2-3 wt.%) Of an oxo-biodegradable additive is added to the granules of a polymer, such as polyethylene, with subsequent processing by traditional methods to obtain products.

Claims (18)

1. The plug for protecting the pipe, made of oxo-biodegradable polymer material, and the plug contains: - external hollow cylindrical element, - an inner hollow cylindrical element located inside the outer cylindrical element with the formation of a gap between the walls of the outer and inner cylindrical elements, - a base having a circular shape and covering the lower end of the inner cylindrical element with the formation of the first connection angles, and - the upper annular element connecting the upper ends of the outer and inner cylindrical elements with the formation of the second connection angles.            2. The cap according to claim 1, in which the wall thickness of the inner and outer cylindrical elements is from 2 to 4 mm 3. The plug according to claim 1, in which the surface of the plug has a roughness of 10 μm to 40 μm. 4. The plug according to claim 1, in which the base contains from 1 to 3 through holes. 5. The cap according to claim 1, in which the upper ends of the outer and inner cylindrical elements are rounded.             6. The plug according to claim 1, in which the lower end of the inner cylindrical element is rounded. 7. The plug according to claim 1, in which the length of the outer cylindrical element is from 10 to 120 mm 8. The plug according to claim 1, in which the length of the inner cylindrical element is from 20 to 85 mm 9. The cap according to claim 1, in which the oxo-biodegradable polymer material contains an oxo-biodegradable additive. 10. The cap according to claim 1, in which the oxo-biodegradable polymer material is a polyethylene containing an oxo-biodegradable additive. 11. The plug of claim 10, in which the polyethylene containing an oxo-biodegradable additive is a high density polyethylene containing an oxo-biodegradable additive. 12. The plug of claim 10, in which the polyethylene containing an oxo-biodegradable additive is a low density polyethylene containing an oxo-biodegradable additive. 13. The cap according to claim 9, in which the oxo-biodegradable additive is from 2 to 3 wt.% Relative to the total weight of the polymer material. 14. The plug according to claim 4, in which from 1 to 3 through holes are located at a distance of 100 mm from the wall of the inner cylindrical element.

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