HU193635B - Device for closing tubings - Google Patents

Abstract

The device according to the invention has an elongated, axial symmetrical, inflatable hose (I) and a frame element connecting the two ends of the hose. The frame is a pipe (2) extending beyond the inner space of the hose (1), which extends beyond the two ends of the hose (1), having at least one end with a cap (6). The tube (2) comprises fixed flanges (4) of the two flanges of the hose (1), which fit inwardly to the two flanges, and separate clamps (3) forming part of the flanges (5) attached to the fixed flanges (4). 7 v_ feet -1-

Description

The present invention relates to a device for blocking pipes.

No. 1,401,758. The use of inflatable hoses for blocking gas pipelines is known from the British patent. In this known embodiment, it is inserted radially through a bore formed on the side of the gas pipe and is axially positioned by means of a curved baffle formed from a leaf spring while inflating it through the neck portion remaining in the lateral bore.

This solution is only applicable to small diameter pipes and requires a special tool, but at the same time dismantles the pipe wall and allows closure only in the immediate vicinity of the open area.

U. S. Patent No. 1,433,884 discloses a device for blocking pipelines having a rigid frame structure and an elongated, axially symmetrical, inflatable hose carried by the frame structure. In this embodiment, the frame structure, when inflated, is formed by a rod coaxial to its axis connecting the two ends of the hose, the outer surface of which is provided with longitudinal channels for easier evacuation of air remaining after the hose is lowered. These channels are connected to the hose filler / drain connection.

The latter solution is theoretically suitable for blocking larger diameter pipelines, however, its disadvantage is that it is sensitive to damage. not applicable in sewers. Another disadvantage is that, when inflated, the hose takes the form of an ovoid and thus lies on a relatively small surface on the wall of the tube, so that it does not provide a good quality seal on uneven, rough surfaces.

For large gravity drains with no cross-sections, it is a special task to temporarily close broken or liquid-conducting pipe sections. A known solution for this purpose is, for example, lining the two wells enclosing the section and filling them with sand. This method is extremely cumbersome, time consuming and costly.

The use of various tube manipulators is also known. These devices are disc-shaped, circumferentially rubber-coated members, the diameter of which can be increased by means of a mechanical tensioner and thus secured in the tube.

The disadvantage is that these devices are very heavy, so they are difficult to handle and their tensioning mechanism is easily damaged (eg due to corrosion). Due to the narrow surface, the device may turn and eject at higher pressures. Pipe manipulators can only be used in shafts and cannot be inserted into intermediate pipe sections. Wires that are not perfectly circular in cross-section may not provide sufficient closure in advance.

In the pressure test of gravity sewers, the sections between adjacent shafts shall be separated from further sections. Water shall be introduced into the cut-off at the required pressure and it shall be measured that the amount of water leaking during that period is not greater than the allowable value. After completion of the test at one stage, the water shall be drained and the test carried out at the next stage. The known pipe manipulators and other blocking devices do not allow the water used in one section to pass into the other section, thus wasting large amounts of clean water (mostly drinking water).

It is an object of the present invention to overcome the aforementioned drawbacks of the known solutions.

It is therefore an object of the present invention to provide a means for sealing pipelines that provides impermeable closure even for large, non-perfectly circular pipes, is easy to handle, can withstand rough operating conditions, can be introduced into passage of liquid (eg tap water used for pressure testing) to the next sealed section.

SUMMARY OF THE INVENTION A device for sealing pipelines having a rigid body structure and an elongated axially symmetrical, inflatable hose bearing a valve, and the body structure being coaxial with the axis connecting the two ends of the hose, According to the present invention, the frame member is an inner tube enclosed within the hose and extending at both ends of the hose and having at least one end provided with a closure, preferably a cap.

In a preferred embodiment of the device according to the invention, the tube has fixed flanges fitting internally to the two ends of the hose and clamping flanges which form a separate part and which are connected externally to the fixed flanges by means of fasteners, preferably clamping screws.

In another preferred embodiment, the flanges surrounding the hose ends of the fixed flanges and clamping flanges are provided with ribs.

In a further preferred embodiment, the ends of the hose between the fixed flanges and the clamping flanges are provided with an annular rim having a thickness greater than the material thickness of the hose.

Preferably, at least one end of the tube is threaded and provided with a threaded cap.

In another preferred embodiment, the device of the present invention has an eccentric tube parallel to the tubular member, which is enclosed within the hose and extends over both ends of the hose.

In another preferred embodiment, at least one end of the eccentric tube is sealed

-2193635 has an organ. Preferably, at least one end of the eccentric tube is bent radially outward relative to the axis of the tubular member.

Finally, it is advantageous if the eccentric tube is attached to the fixed flanges.

The invention will now be described with reference to the embodiments outlined in the accompanying drawings. The

Figure 1 is a side view, partly in section, of the device of the first example, a

Figure 2 is a side view, partly in section, of the device of the second example, a

Figure 3 is a schematic longitudinal sectional view of a section of the gravity drainage system closed by the device of the present invention, and

Figure 4 is a partially sectional side view of the device of the third example.

The device of Fig. 1 has a frame structure consisting of 2 tubes and a fixed disc 4 flange welded to each end near the two ends. The fixed flanges 4 are welded to their ends by clamping screws 5 towards the ends of the tube 2, on which are mounted separate ring flanges 3 of a circular shape, concentric with the tube 2 and secured with suitable nuts.

Between the fixed flanges 4 and the clamping flanges 3 the ends of the cylindrical hose I made of flexible material, preferably rubber, are clamped in the plane perpendicular to the axis of the tube 2 by means of the clamping screws 5. The surfaces of the fixed flanges 4 and the clamping flanges surrounding the ends of the hose 1 are provided with ribs for better closure. The ends of the tube 2 extend beyond the clamping flanges 3 and are provided with an external thread. One of the threads is fitted with a removable cap 6 with an internal thread. On the outside of the fixed flanges 4 there is a U-shaped handle 8 welded to facilitate transport or movement of the device. Also, a valve 7 (e.g., a car tire valve) is led to the outside of the flanges 4 to the inside of the hose 1.

The device of Fig. 2 differs from that of Fig. 1 in that the two ends of the hose 1 are provided with a toroidal annular rim having a thickness greater than the material of the hose 1 and this rim is clamped between the fixed flange 4 and the clamping flange 3. , which are provided with a perforated groove in the right place.

The frame structure consisting of the tube 2 and the fixed flanges 4 and the clamping flanges 3 ensure the cylindrical shape of the hose 1 in the inflated state.

The device according to the invention may be used, for example, as shown in FIG. In the case shown, it is intended to provide closure between the two gravity drains 11, 14 of the gravity sewer 17. To this end, a rope 13 is attached to one end of the hose 1, then lowered into the shaft 11, the unexploded hose 1 is floated in the dirty water 16 in the sewer 17 and secured at the desired position. The hose (1) is then blown through a manifold (12) through a manifold (14) which compresses the hose wall (17) to provide impeccable closure.

Naturally, the hose 1 can also be introduced from the shaft 14. The rope 13 is then pulled to the correct position against the flow of waste water 16. In both cases, of course, the cap 6 of the tube 2 is previously screwed onto the upper end in the direction of flow.

In this application, valve 7 is permanently open and a suitable valve is installed in the surface portion of the air tube 12, as well as a pressure control (nanometer). Operating pressure is usually 0.05 MPa. , but too much pressure can damage the sewer 17.

Optionally, it may be desirable to apply the air tube 12 and the rope 13 on the same side of the hose 1.

If the hose (1) is to be sealed at one of the manhole joints, it is advisable to remove the cap (6) of the tube (2) beforehand in order to facilitate the insertion of the device.

When the closure is to be terminated, the valve 7 and the valve of the air tube 12 (not shown) are opened by lowering the hose 1 and pulling it out of the channel using the rope 13 and lifting it out of the shaft.

In the case of pipeline pressure testing, after removing the cap 6 from the sealed section at both ends, pass through the pipe 2 of one of the hoses 1 to the next section the part of the water used for the test which can flow. Of course, the other end of the next section will be closed beforehand. In this way, we can save large amounts of valuable water.

The structure of Fig. 4 allows the passage of water into the next section almost completely when the structure is in the position shown in the figure. This structure differs from that shown in Fig. 1 in that it has an eccentric tube 9 which is parallel to the tube 2 and which is closed off from the inside of the hose 1 and extends at both ends of the tube 1 and is provided with a stopper 10 at one end. The two ends of the tube 9 are bent radially outward relative to the axis of the tube 2. The tube 9 is guided through the fixed flanges 4 and the clamping flanges 3 and is preferably welded to the flanges 4.

The tube 9, when mounted in a 180 ° rotation about its longitudinal axis relative to Fig. 4, may also perform a bleed function. In the position shown in Figure 4, a complete pump for the fluid in the sealed section (eg chemical treatment fluid) can be used3

-3193635 or pumping it to the next closed section.

The frame structure of the device according to the invention ensures that the hose 1 is not stretched longitudinally after inflation and thus provides a perfect seal. The hose 1 is located on a large surface of the pipeline wall and fits well even if the pipeline is not perfectly circular or the inside surface of its wall is not perfectly crying. The device has no moving parts, so it is not prone to failure. Lightweight, easy to handle and transport. It tolerates harsh operating conditions.

Claims (9)

PATENT CLAIMS A device for sealing pipelines having a rigid body structure and an elongated, axially symmetrical, inflatable hose carried by the valve body, and the body structure being coaxial with its axis when the hose is inflated, a tube (2) extending from both ends of the hose (1) and having at least one end provided with a closure, preferably a cap (6). (05.05.1982) Device according to Claim 1, characterized in that the fixed flanges (4) of the tube (2) which fit inside the two ends of the hose (1) and the fasteners - preferably clamping screws (5) - fit to the fixed flanges (4). - having clamping flanges (3) connected as separate components. (05.05.1982) An embodiment of the device according to claim 2, characterized in that the fixed flanges (4) and the clamping flanges (3) are provided with ribs at the ends of the hose (1). (05.05.1982) Device according to Claim 2, characterized in that the ends of the hose (1) caught between the fixed flanges (4) and the clamping flanges (3) are provided with an annular flange with a thickness greater than the material thickness of the hose (1). (05.05.1982) The device of claim 1, further comprising 15, characterized in that at least one end of the tube (2) is threaded and provided with a threaded cap (6). (05.05.1982) Device according to claim 1, characterized in that it comprises a tube constituting the body element 20 (2) has an eccentric tube (9) extending parallel to the inside of the hose (1) and extending over both ends of the hose (1). (7/18/1985). The device of claim 6, further comprising 25. characterized in that at least one end of the eccentric tube (9) is provided with a closing device (10). (July 18, 1985) Device according to claim 6 or 7, 30, characterized in that at least one end of the eccentric tube (9) is bent radially outward relative to the axis of the tube (2) forming the skeleton. (July 18, 1985) 9. A 6-8. A process according to any one of claims 1 to 4 35, characterized in that the eccentric tube (9) is fixed to the fixed flanges (4).