RU166132U1 - PIPELINE THERMAL SHrinkable Coupling - Google Patents

Abstract

A heat-shrinkable sleeve for a pipeline, comprising a body, characterized in that it is made of polyethylene, contains a stretched socket part on both sides of the sleeve body, the average outer diameter of the socket part being from 1.05 to 1.2 of the nominal outer diameter, and the length of the heat-shrinkable socket part ranges from 0.2 to 2 nominal outer diameters.

Description

The utility model relates to the field of installation of pipelines and is intended primarily for connecting pressure-free pipelines made of polymer materials, but is suitable for steel and asbestos-cement pipelines, and under low pressure, as well as other types, including electrical cable channels.

A device for detachable connection of plastic pipelines with flanges (Plumbing: how it works and how to fix it: reference book / V.A. Volkov. - M.: Astrel: ACT, 2006. - 439 pp., Ill. See page 370- 372, Fig. 2-2-22, c. Appendix 1). The device contains loose union flanges, gasket, bolts, nuts, formed on the piping sockets.

The disadvantages of the known device are the complexity of the design, the complexity of the technological process of forming the sockets at the ends of the pipes at the places of installation, the length of the installation period, the need to use portable equipment for forming the sockets.

A device is known for an electrically welded coupling (ROFITT. POLYETHYLENE FITTINGS. BALL VALVES. PRODUCT CATALOG 2015 / www.rofitt.ru. (Access date 09/02/2015) See page 2. Appendix 2), consisting of a polymer case, a heating electric spiral, electrical contacts.

When the contacts are connected to a current source, the coil heats the pipe and the coupling so much that the material on the outer surface of the pipe and the inner surface of the coupling melts. Since the coupling slightly decreases in diameter between the pipe and the pipe, it provides good contact, resulting in fusion of the surfaces.

A disadvantage of the known device is the structural complexity of the device, the difficulty of providing a sealed output of electrical contacts to the outer surface of the electric-welded coupling, the need to use a current source at the installation site of the pipeline, the risk of electrical injury when working in high humidity.

A compression clutch device is known (URL: http://www.trubotorg-irk.ru/katalog/kompressionnye_fitingi_muftysoedinitelnye/mufta_soedinitelnaya (Date of access 04.09.2015). Appendix 3), comprising a housing with thread on both sides and an internal ridge, two elastic o-rings, two collet-type clamping bushings, two clamping nuts.

The disadvantages of the device are: the structural complexity of the device, the increased cost of production, the inability to connect pipelines with a diameter of more than 110 mm.

In terms of technical nature, the closest to the claimed solution is the known device of the coupling with elastic sealing rings (http://www.ost-m.ru/catalog/kanalizatsiya_truby_i_fitingi_dlya_vnutrenney_kanalizatsii_truby_i_fitingi_iz_pp_mufty_04.04.2015). The device comprises a housing with an internal ridge and molded annular grooves, two elastic sealing rings. The body is molded from plastic and has an inner diameter exceeding the outer diameter of the connected pipelines. The coupling body is made of polypropylene.

The disadvantages of this device are the structural complexity of the device, the difficulty of forming on both sides of the coupling of the annular grooves for the sealing rings, aging of the rubber rings and, as a result, the loss of tightness of the connection with time.

The technical task of the claimed utility model is to create a simple device for connecting, mainly pressure-free pipelines, containing a minimum number of elements and easy to install.

The specified technical problem is achieved by the fact that in the known device containing a housing made of plastic, in contrast to it, the proposed device is made of low-pressure polyethylene in the form of a coupling, which has a bell-shaped extension on both sides. The body is made of extruded polyethylene pipe of the same diameter as the connected pipelines. The bells on the coupling body are formed by stretching at elevated temperatures on both sides and have an average diameter larger than the sum of the outer diameter of the pipeline and the doubled wall thickness of the coupling. The middle part of the coupling has an initial pipe diameter.

The drawing shows a longitudinal section of a heat-shrinkable sleeve.

It is known that when heated, the strength of polyethylene is significantly reduced, and the products made of it can noticeably deform without breaking. If the preform for the coupling, in the form of a part of a polyethylene pipe, is heated below the temperature of the structural transition, subjected to deformation of a certain size and cooled, then such a product will remain deformed. With subsequent heating, such a product will manifest a “shape memory effect”. The heated product will return to its previous geometric dimensions. A significant effect on the intensity of the manifestation of the "shape memory effect" is exerted by the magnitude of the deformation, the heating temperature and the cooling rate of the deformed product. With insufficient heating and deformation, a spontaneous gradual return to the original state of the product occurs. With excessive heating (above the temperature of the structural transition) and the amount of deformation of the product, the "shape memory effect" does not occur. The combination of the heating temperature and the strain allows you to choose the parameters at which the coupler remains stable in the deformed state, and when heated, the "shape memory effect" is manifested.

For further description of the claimed utility model, the parameters specified in paragraph 3 of GOST 18599-2001 “HEADING PIPES OF POLYETHYLENE. Specifications ":

- average outer diameter d _cp , (mm): The quotient of dividing the measured value of the outer perimeter of the pipe by the value Pi = 3.142, rounded up to 0.1 mm.

- nominal outer diameter d (mm): Symbol for the size corresponding to the minimum average outer diameter.

Implementation of a utility model. The claimed technical solution is made of pipe with the same nominal outer diameter as the connected sections of the pipeline. From it, blanks are cut for the coupling body 1 of the required length. Each workpiece is heated on one side to a temperature not exceeding the temperature of the structural transition. A tensile mandrel is pressed into the heated billet. Together with the mandrel, the workpiece is intensively cooled. After cooling, the mandrel is removed from the extended sleeve of the coupling, and the operation is repeated on its other side. A coupling made in this way has a “shape memory effect”. For reliable connection of sections of the pipeline in the elongated bell-shaped parts of the sleeve 2 are inserted the edges of the connected pipes. The sleeve heats up, the “shape memory effect” is triggered and the extended sockets are seated. A tight, reliable connection is created.

The parameters of the heat-shrinkable sleeve, at which the “shape memory effect” is manifested, there is no spontaneous shrinkage of the sleeve and at the same time the most reliable connection of the pipeline sections is obtained, lie in the following ranges:

1. for a pipeline with a nominal outer diameter of 50 mm - the average outer diameter of the bell-shaped part is from 0.053 m to 0.062 m

(which is from 1.05 to 1.2 of the nominal outer diameter), and the length of the heat-shrinkable bell-shaped part is from 0.01 m to 0.1 m (which is from 0.2 to 2 nominal outer diameters);

2. for a pipeline with a nominal outer diameter of 63 mm, the average outer diameter of the bell-shaped part is from 0.066 m to 0.076 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.012 m to 0.126 m (which is from 1.05 to 1.2 of the nominal outer diameter);

3. for a pipeline with a nominal outer diameter of 75 mm, the average outer diameter of the bell-shaped part is from 0.079 m to 0.092 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.015 m to 0 , 15 m (which is from 1.05 to 1.2 of the nominal outer diameter);

4. for a pipeline with a nominal outer diameter of 90 mm - the average outer diameter of the bell-shaped part is from 0.095 m to 0.108 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.018 m to 0 , 18 m (which is from 1.05 to 1.2 of the nominal outer diameter);

5. for a pipeline with a nominal outer diameter of 110 mm, the average outer diameter of the bell-shaped part is from 0.115 m to 0.132 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.022 m to 0 , 22 m (which is from 0.2 to 2 nominal external diameters);

6. for a pipeline with a nominal outer diameter of 125 mm, the average outer diameter of the bell-shaped part is from 0.131 m to 0.142 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.025 m to 0 , 25 m (which is from 0.2 to 2 nominal external diameters);

7. for a pipeline with a nominal outer diameter of 140 mm - the average outer diameter of the bell-shaped part is from 0.147 m to

0.168 m (which is from 1.05 to 1.2 of the nominal outer diameter), and the length of the heat-shrinkable bell-shaped part is from 0.028 m to 0.28 m (which is from 0.2 to 2 nominal outer diameters);

8. for a pipeline with a nominal outer diameter of 150 mm - the average outer diameter of the bell-shaped part is from 0.157 m to 0.180 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.03 m up to 0.3 m (which is from 1.05 to 1.2 of the nominal outer diameter);

9. for a pipeline with a nominal outer diameter of 160 mm, the average outer diameter of the bell-shaped part is from 0.168 m to 0.192 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.032 m to 0 , 32 m (which is from 0.2 to 2 nominal external diameters);

10. for a pipeline with a nominal outer diameter of 180 mm - the average outer diameter of the bell-shaped part is from 0.188 m to 0.216 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.036 m to 0 , 36 m (which is from 0.2 to 2 nominal external diameters);

11. for a pipeline with a nominal outer diameter of 200 mm, the average outer diameter of the bell-shaped part is from 0.210 m to 0.240 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.04 m up to 0.4 m (which is from 0.2 to 2 nominal external diameters);

12. for a pipeline with a nominal outer diameter of 225 mm, the average outer diameter of the bell-shaped part is from 0.236 m to 0.270 m (which is from 0.2 to 2 nominal external diameters), and the length of the heat-shrinkable bell-shaped part is from 0.045 m to 0.45 m (which is from 0.2 to 2 nominal external diameters);

13. for a pipeline with a nominal outer diameter of 250 mm - the average outer diameter of the bell-shaped part is from 0.262 m to

0.300 m (which is from 1.05 to 1.2 of the nominal outer diameter), and the length of the heat-shrinkable bell-shaped part is from 0.05 m to 0.5 m (which is from 0.2 to 2 nominal outer diameters);

14. for a pipeline with a nominal outer diameter of 280 mm, the average outer diameter of the bell-shaped part is from 0.293 m to 0.336 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.056 m to 0 56 m (which is from 0.2 to 2 nominal external diameters);

15. for a pipeline with a nominal outer diameter of 315 mm - the average outer diameter of the bell-shaped part is from 0.330 m to 0.378 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.063 m to 0 , 63 m (which is from 0.2 to 2 nominal external diameters);

16. for a pipeline with a nominal outer diameter of 355 mm - the average outer diameter of the bell-shaped part is from 0.372 m to 0.426 m (which is from 1.05 to 1.2 of the nominal external diameter), and the length of the heat-shrinkable bell-shaped part is from 0.071 m to 0 , 71 m (which is from 0.2 to 2 nominal outer diameters).

Claims (1)

A heat-shrinkable sleeve for a pipeline, comprising a body, characterized in that it is made of polyethylene, contains a stretched socket part on both sides of the sleeve body, the average outer diameter of the socket part being from 1.05 to 1.2 of the nominal outer diameter, and the length of the heat-shrinkable socket part ranges from 0.2 to 2 nominal outer diameters.

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