RU53367U1 - PIPE FOR SHAFT VENTILATION PIPELINE - Google Patents

Abstract

The utility model relates to the ventilation of mines or tunnels and can be used in pipelines, both for discharge and for suction ventilation of mine workings and industrial facilities. The objective of the utility model is to create a pipe with high strength, tightness, when used in an aggressive environment, typical for the operating conditions of a mine ventilation pipe. To solve this problem, a pipe was proposed for a mine ventilation pipe, which is made of a one-piece sleeve, in the shape of a figure eight with a jumper separating the figure eight loops, while the size of one figure eight loop used to accommodate the pipe suspension cable is smaller than the other and has an airtight coating applied from the outside, and the other loop of the figure eight sleeves has a bilateral airtight coating in the form of a single monolithic structure.

Description

The utility model relates to the ventilation of mines or tunnels and can be used in pipelines, both for discharge and for suction ventilation of mine workings and industrial facilities.

Known rubber-fabric sleeve product manufactured by the method (RF Patent for the invention No. 2096178, published on November 20, 1997 in BPIM No. 32, page 190, IPC ⁶ : B 29 D 23/00), which consists in rubberizing the fabric sleeve blank with two sides with rubber sheets followed by vulcanization on the press.

The product made by this method has a flexible structure and high strength.

At the same time, such properties as increased combustibility and high weight make it impossible to use it in a mine.

A known pipe made by the method (Application for a patent of the Russian Federation No. 2002121101, publ. March 27, 2004 in BIPM No. 9, p. 318, IPC ⁷ : B 29 D 23/00), which includes forming a polyethylene tubular workpiece, calibrating it with cooling and reinforcing by winding and polymerizing a fibrous material with a binder. A pipe made in this way has high strength. However, given that polyethylene is highly flammable and highly electrified, it is unacceptable to use such pipes in a mine environment.

A known pipe made by welding with high-frequency currents from fabric for ventilation pipes (RF Patent for the invention No. 2104345, publ. 02/10/1998 in BIPM No. 4, p. 315-316, MPK ⁶ : D 03 D 1/00) having a polymer coating and containing warp and weft threads intertwined with each other with the formation of cells. The fabric in which the polymer coating is used has increased tightness, adhesion strength.

However, taking into account that the pipe is made by means of longitudinal seam joining of fabric edges using high frequency current welding, the pipe is characterized by a rather low ratio of weld strength to material strength. Longitudinal welds, having low strength, very often diverge during operation.

To install the fastening elements to the pipe, an additional scallop-shaped strip of fabric is attached in half.

At the same time, the seam that attaches the strip for fasteners is an additional source of reducing the strength of the finished product.

The closest technical solution, selected as a prototype, is a ventilation pipe (Copyright certificate No. 1430546, published on December 19, 1986 in Bull. No. 38, p. 126), including a flexible airtight shell made of a spiral-rolled fabric strip, the edges of which are glued or overlap welded, forming a spiral-shaped connecting seam, and a flexible reinforcing element located in the connecting seam. Pipes having a connecting seam have a fairly low ratio of weld strength to material strength. Longitudinal welds, having low strength, very often diverge at startup and during operation.

It should be noted that the fabric is covered with an airtight shell only on the outside, which is exposed to the aggressive external environment characteristic of mines. If the outer shell is damaged, the integrity of the entire pipe is impaired. The presence of a reinforcing element, providing longitudinal stiffness of the pipe, improves the aerodynamic properties of the pipe. However, the reinforcing element installed in the connecting seam can lead to a violation of the tightness of the pipe during its manufacture. Additional loads on the seam reduce its strength, which can disperse during operation, which will lead to air leakage through the formed cracks in the pipe.

To install fastening elements to the pipe, it is necessary to attach an additionally bent in half strip of fabric in the form of a scallop. At the same time, the seam with which the strip for fastening elements is attached is an additional source of strength reduction.

The objective of the utility model is to create a pipe with high strength, tightness, when used in an aggressive environment.

It is possible to solve the problem by using the claimed utility model, in which the pipe for the mine ventilation pipe is made of a whole-woven sleeve, in the shape of a figure eight with a jumper separating the figure eight loops, while the size of one sleeve figure eight used to accommodate the pipe suspension cable, smaller than the other and has an airtight coating applied on the outside, and the other loop of the eight of the sleeve has a two-sided airtight coating, in the form of a single monolithic structure.

Due to the implementation of the pipe from a whole-woven sleeve, in contrast to the prototype having a connecting seam, it has higher strength and tightness.

The implementation of the pipe from a one-piece sleeve in the form of a figure eight with a jumper separating the figure eight loops eliminated the need for additional fastening of the strip, in the form of a scallop, to accommodate the cable and install the fastening elements, which significantly increased the strength and tightness and simplified the pipe manufacturing technology. The implementation of the pipe from the whole-woven sleeve simplified the technology of creating a two-sided airtight coating. A two-sided airtight coating provides high tightness, durability during operation, since if the outer layer of the coating is destroyed when working in an aggressive environment in a mine environment, the tightness will not be broken due to the presence of an inner layer that does not directly contact the external environment.

The possibility of manufacturing a pipe, one part of which is used to place the cable, the other to install the fastening elements, simplifies the technology, since in a single technological cycle it is possible to provide the necessary dimensions of the individual parts of the sleeve to accommodate the metal cable and through holes for the grommets for the fastening elements.

The use of yarns made of polyamide or polyester fibers having low weight at high strength, allows you to increase the strength of the product, without weighing it down.

At the same time, one can weave a sleeve from such threads by the plain weave method with the formation of cells, which makes it possible to quickly penetrate the sleeve.

The presence of a jumper dividing the eight loops and having through impregnation made it possible to make through holes for eyelets capable of withstanding the heavy loads experienced by the fastening elements installed in them during operation.

Obtaining the inner shell by extrusion and subsequent curing ensures the simplicity and manufacturability of the pipe, since the blank from the polyvinyl chloride film can be made in advance, and the finished blank can be used in the pipe manufacturing process.

The use of a shell made of polyvinyl chloride and external impregnation made in the form of an aqueous emulsion of polyvinyl chloride makes it possible to combine two layers into a single monolithic structure during melting and to obtain an airtight coating after curing, both on the external and internal sides of the pipe.

Considering that polyvinyl chloride does not support combustion and relates to self-extinguishing materials, the use of an inner shell made of polyvinyl chloride and an external impregnation material made in the form of an aqueous emulsion of polyvinyl chloride provides a high level of fire resistance, which is an important parameter when using the pipe in a mine environment.

The following is an example of a specific construction of a pipe for a mine ventilation pipe. Figure 1 schematically shows the design of the pipe. Figure 2 schematically shows the manufacturing technology of the pipe. The pipe shown in figure 1, consists of a one-piece sleeve 1 in the form of a figure eight, with an airtight coating, consisting of a loop of small diameter 1.1, a bridge 1.2, a loop of large diameter 1.3; metal cable 2, which does not allow the pipe to sag; eyelets 3 installed in through holes made along the entire length of the jumper of the sleeve 1.

The pipe is made as follows (see figure 2). Preliminarily, for the sleeve 1, a woven blank is made by the method of plain weaving of threads of polyester fiber with the formation of cells on a flat loom in the form of a figure of eight, consisting of a loop 1.1 of small diameter 20 mm, a jumper 1.2, dividing loops of a figure of 10 10 mm wide. and loops 1.3 large diameter 500 mm. (and can be made with a diameter of 600, 800, 1000, 1200 mm.), 50 m long. (Depending on the requirements of the operating conditions, a woven blank can be made 20-100 m long.)

By a separate extrusion method, a polyvinyl chloride sheath is made of the same size as loop 1.3 of the woven blank for sleeve 1 and placed inside the woven blank, carefully extending it along the length and width of the woven blank. Then, the woven blank for the sleeve 1 with the polyvinyl chloride shell placed inside, flattening and leveling with the help of rollers 4, is placed on the table 5, from which, using the immersion roller 6, the impregnation solution in the form of an aqueous emulsion of polyvinyl chloride is impregnated in the container 7, which impregnates through the woven blank of the sleeve 1, while the inner surface of the sheath of polyvinyl chloride remains dry. The excess emulsion of polyvinyl chloride is removed by squeezing rollers 8 and poured into the tank 7. After pressing the blank sleeve 1 is fed into the tunnel 9 with infrared heaters, equipped with an exhaust ventilation device 10.

At the same time, air from the fan (not shown in Fig. 2) is supplied into the preform under a slight pressure of 400-500 Pa, which allows you to uniformly inflate the polyvinyl chloride shell and press it to the surface of the impregnated woven blank of the sleeve 1. In the tunnel with infrared heaters 9, the blank 1 heats up to the melting point of polyvinyl chloride, the impregnation composition is polymerized and a solid homogeneous connection of the polyvinyl chloride shell of sleeve 1 and external impregnation occurs, due to which the shell of sleeve 1 and the image by a single monolithic structure. Vapors from the heating zone are removed using the exhaust ventilation device 10. The pipe 1 is cooled in air and quality control is carried out.

Then, in the jumper 1.2, dividing the eight loops, the sleeves 1 make through holes and eyelets 3 are installed, after which a metal cable 2 is inserted into a smaller loop 1.1.

Thus, through the use of a seamless pipe design, in the form of a one-piece sleeve, in the shape of a figure eight, with a two-sided airtight coating, in the form of a single monolithic structure

It was possible to provide the product with high strength, tightness during operation in an aggressive environment, which is confirmed by tests. When testing revealed:

- at a test pressure of 1500 daPa for 10 minutes No defects were observed, the geometric parameters were normal, for example, torsion was 10 deg / 10 m, with a standard value of 30, which confirms the high strength of the product;

- air permeability at a pressure of 1000 daPa was 0.4 dm ³ , with a standardized rate of 4.5 dm ³ , which confirms the high tightness of the product.

The product is characterized by a high level of fire safety and low surface electrostatic resistance:

- combustibility, determined in accordance with GOST 12.1.044 in terms of the “oxygen index” - 30.2% with a standardized value of 28.0%;

- surface electrostatic resistance was 2.5 × 1080 m with a normalized limit of 3 × 108.

The use of pipes with such parameters increases the safety of tunneling in mine workings by gas and dust factors, eliminates the ignition and explosions of methane and dust, and creates normal climatic conditions in the bottomhole spaces and mine workings as a whole.

Claims (5)

1. The pipe for the mine ventilation pipe, made of a one-piece sleeve, in the shape of a figure eight with a jumper separating the figure eight loops, while the size of one figure eight loop used to accommodate the pipe suspension cable is smaller than the other and has an airtight coating applied from the outside side, and the other loop of the figure eight sleeves has a two-sided airtight coating, in the form of a single monolithic structure. 2. The pipe according to claim 1, a one-piece sleeve, which is made with plain weaving of threads from polyamide or polyester fibers with the formation of cells. 3. The pipe according to claim 1, along the entire length of the jumper which separates the loop of figure eight, through holes for the eyelets for fasteners are made. 4. The pipe according to claim 3, the inner shell of polyvinyl chloride of which is obtained by extrusion, followed by threading it into the sleeve after curing. 5. The pipe according to claim 1, the airtight coating of which is obtained by melting the inner shell of polyvinyl chloride and an external impregnation material made in the form of an aqueous emulsion of polyvinyl chloride, followed by curing.