RU2851908C1 - High-speed device for radial compression of tubes - Google Patents

Abstract

FIELD: radiation materials.

SUBSTANCE: invention relates to technological equipment for working with toxic and radiation materials, specifically to devices for forming explosive load for compressing metal tubes. Includes tube from aluminium alloy with wall thickness d not less than 10% of internal tube diameter, cushioning gasket with thickness of 0.4¸0.6d, annular layer of explosive material, strong steel housing. Layer of explosive material is installed on cylindrical impactor from same material as tube, with wall thickness of 0.4¸0.6d, located coaxially with tube at distance of 1.5¸2.5d. On impactor two groups of pairwise symmetrical longitudinal grooves of same or different width are made, uniformly located along circumference, overlapping in length layer of explosive material lying on them. Initiation is carried out from two detonators fixed on housing in two opposite points in middle of one of groove groups, for which under initiation points in grooves on impactor bridge with explosive material is left, and in housing of device two holes for outlet of explosion products are made, lying in same cross-section with detonators and turned relative to initiation points by angle of 90°.

EFFECT: improved design.

6 cl, 4 dwg

Description

Field of technology to which the invention relates

The present invention relates to process equipment for handling toxic and radioactive materials, specifically to devices for generating explosive loads for compressing metal pipes. It can be advantageously used in equipment for ensuring environmental and industrial safety during the study of toxic and radioactive materials at high pressures generated by shock wave methods. Furthermore, the device can be used as a quickly created anti-fragmentation shield in process openings, as well as for emergency shutoff of gas pipelines.

Disclosure of the essence of the invention

A device for installing pipes using explosives is known from the prior art (patent RU2468276, published April 10, 2012). A coupling with a sealing element is installed at the junction of the pipes being connected, after which compression is performed by detonating ring charges mounted on the outer surface of the coupling. At least two compressions are performed at each coupling-to-pipe connection.

The disadvantage of this device is that the compression force created is only sufficient for connecting pipelines; such force is not sufficient for shutting off the pipeline in emergency situations that require its compression.

A device for shutting off a pipeline transporting a hazardous liquid is also known (patent US4140041, published February 20, 1979, applicant – the French Atomic Energy Commission). The device is designed to deform the pipe so as to achieve a hermetic seal without causing a noticeable displacement of its axis. The device comprises two pipe-compressing elements connected to a pusher driven by the pressure of gases generated during the activation of a pyrotechnic device, activated by an electric pulse generator adapted to ignite said device, and a detector for activating said generator. The seal is achieved within 5 milliseconds.

The disadvantage of this device is the lengthy process of squeezing the pipe, which reduces the effectiveness of its use in emergency situations.

The Ultra-Fast Closure Valve (UCV) is a device designed to close heat-treated aluminum tubes in the JASPER facility at the Lawrence Livermore National Laboratory (USA, report No. LLNL-TR-824372 dated July 12, 2021). The device includes a layer of plastic explosive material (PEM) with a density of less than 1 g/ ^cm3 , which is wrapped around a central tube made of aluminum alloy. Between the PEM and the tube, there is a softening gasket that reduces the peak pressure on the tube. The tube with the gasket and PEM layer is installed in a robust steel housing and closed with a steel flange. In the cross-section of the housing, corresponding to the middle of the PEM layer, there are 12 evenly spaced holes in which detonators are placed. Two holes are made in the housing to remove explosion products.

When the detonators are triggered, the outer surface of the explosive layer is simultaneously detonated at twelve points. The resulting converging detonation wave impacts the aluminum tube through the cushioning pad, causing it to move toward the central axis until the inner cross-section is completely sealed within 100 microseconds.

The disadvantages of this device include the complexity of the explosive initiation system, which requires twelve detonators. Furthermore, to reduce the pressure in the detonation wave and prevent the resulting destruction of the central tube, the device uses a special explosive material with a density of less than 1 g/ ^cm³ , which increases the cost of the design.

The closest device chosen as a prototype is a high-speed device for radial pipe crimping, according to patent CN102778181 (published November 14, 2012). The device comprises a pipeline to be crimped, 6-20 mm in diameter, wrapped in several layers of flexible composite material (FCM) with a density of 1.4 g/ ^cm3 and a thickness of 0.2-2.5 mm. The number of layers depends on the pipe diameter. Between the FCM and the pipe is a cushioning gasket, which reduces peak pressure on the pipe and consists of several layers of rubber and/or copper foil. The FCM is connected by detonating cords of equal length to a snap-action electric detonator connected to a power source. Initiation points are evenly distributed in the middle of the FCM layer along the cross-section of the axial center. Detonating cords initiate explosive masses at each detonation point along the outer circumference of the cross-section towards the center, and a circular blast wave is formed that converges toward the axis and acts on the outer surface of the pipe until the internal cross-section is completely blocked within 100 μs.

A drawback of the prototype is the complex design of the cushioning pad, which has a layered structure. Another drawback is the initiation system, which uses multiple detonating cords, which must be placed outside the device and protected from possible damage during operation.

The technical result, which the claimed invention is aimed at achieving, is expressed in ensuring rapid closure of the pipe while guaranteeing the preservation of its integrity.

The said technical result is achieved due to the fact that in a high-speed device for radial compression of pipes, including a pipe made of an aluminum alloy, with a wall thickness δ of at least 10% of the internal diameter of the pipe, a softening gasket with a thickness of 0.4 ÷ 0.6 δ, an annular layer of explosive material, a durable steel body, what is new is that the explosive material is installed on a cylindrical striker made of the same material as the pipe, with a wall thickness of 0.4 ÷ 0.6 δ, located coaxially with the pipe at a distance of 1.5 ÷ 2.5 δ, on the striker there are two groups of paired symmetrical longitudinal grooves, uniformly spaced around the circumference, overlapping along the length of the layer of explosive material lying on them, while two detonators are fixed on the body at two opposite points in the middle of one of the groups of grooves with the possibility of their initiation, for which a space is left under the initiation points in the grooves on the striker a jumper with explosive material, and in the body of the device there are two openings for the removal of explosion products, lying in the same cross-section with the detonators and turned relative to the initiation points at an angle of 90°.

The explosive material can be removed in the area of two opposite grooves.

Explosive material can be removed in the area of all four grooves.

The grooves can be made of the same width and evenly distributed around the circumference and filled with explosive material, and initiation is carried out at two opposite points of the longitudinal section, rotated relative to the sections in which the grooves are located, at an angle of 45°.

The longitudinal axis of the grooves can be rotated relative to the striker axis at an angle of 10-45°.

When developing radial crimping devices for metal pipes, two main challenges must be addressed: first, the pipe's movement must be as axisymmetric as possible; second, the pressure on the pipe's surface must be uniform and not too high to prevent pipe failure. In the analogs discussed, axial symmetry of movement is ensured by a multi-point initiation system. Limiting the pipe's loading amplitude is achieved in the first case by using a special low-density CM (and therefore low Jouguet pressure), and in the second case, by creating a multi-layer cushioning lining with alternating layers of soft and hard material.

The two-point initiation scheme proposed in the described device leads to the formation of high-pressure zones at the points of collision of detonation waves and gas flows. During detonation of the explosive, some of the explosion products (EP) flow through the grooves in the striker into the gap between the striker and the pipe. This creates eight high-pressure zones on the pipe surface: under the grooves and in the areas of collision of the explosion product flows entering the gap through each groove. Due to the significant difference in the detonation propagation velocity and the EP expansion velocity compared to the pipe velocity, it can be assumed that the formation of high-pressure zones occurs instantaneously. This feature of gas-dynamic flows ensures good axial symmetry of the pipe movement. Moreover, the grooves in the striker and the initiation points can be oriented relative to each other in two ways. In the first case, the initiation points lie on the longitudinal axis of one pair of opposing grooves; in the second, they are offset relative to them in cross-section by an angle of 45°.

In the proposed device, peak impacts on the pipe are limited by limiting the amount of PM flowing through the grooves in the striker into the gap between it and the pipe. The amount of PM is regulated by adjusting the groove width and/or removing the PM in the groove area. An additional design element that reduces pressure on the pipe surface is a softening tape lining wound around the pipe.

To quickly reduce the maximum pressure in the collision zone of detonation waves from each initiation point, which occur in a longitudinal cross-section rotated at a 90° angle relative to the cross-section containing the detonation initiation points, holes in the device's housing are used. Pressure in these zones is regulated by the diameter of the holes.

The use of a striker in which the grooves are located at an angle to the central axis leads to a “twisting” effect on the pipe, which in some cases ensures a higher tightness of the ceiling.

Brief description of the drawings

Fig. 1 shows a diagram of the claimed device, where: 1 - aluminum alloy tube; 2 - softening gasket; 3 - striker; 4 - annular layer of VM; 5 - steel body; 6 - holes for removing PV (2 pieces); 7 - flange; 8 - detonators (2 pieces).

Fig. 2, 3, 4 show various designs of the striker variants.

Implementation of the invention

An example of a specific embodiment of the claimed device is a high-speed device for radial crimping of an aluminum pipe with an internal diameter of 55 mm. The device comprises an aluminum alloy pipe with a wall thickness of 6 mm, a 3 mm thick cushioning lining, an annular explosive layer initiated at two opposite points in the middle of the layer, a robust steel housing with two holes for removing explosion products, rotated relative to the initiation points at an angle of 90° in cross-section, and a steel flange. The annular explosive layer is mounted on a cylindrical striker with a wall thickness of 3 mm, located coaxially with the pipe at a distance of 12 mm. The striker is made of the same material as the pipe and has four paired symmetrical longitudinal grooves, evenly spaced on the striker and overlapping the explosive layer lying on them along the length. The width of the two groups of grooves differs by a factor of 1.5. The explosive material in the groove area is removed. The explosive device is initiated in the middle of one of the slot groups. To achieve this, a bridge is left under the initiation points in the slots on the striker, above which the explosive device is not removed. This design proved to be the most favorable compared to test results for devices with different cushioning pad thicknesses, striker wall sizes, and distances between the pipe and striker, varying within the limits specified above.

In the second version of the device, the striker has four evenly spaced identical grooves. The explosive composition in the groove area is not removed. The explosive is initiated in the middle of the layer at two opposite points, centered between the closest grooves of the striker.

The third version of the device differs from the first and second in that the axial line of the grooves has an angle of 45° relative to the longitudinal axis of the striker.

When the detonators (8) are triggered, detonation is initiated at two points on the surface of the explosive layer (4). The explosion products (EP) generated by the propagation of the detonation wave impact the striker (3), causing it to move toward the axis of the device. When the detonation wave intersects the grooves in the striker, some of the explosion products flow into the gap between the striker and the pipe (1). As a result, the impulse from the EP to the pipe is transmitted through the striker and the gas layer between the striker and the pipe, ensuring shock-free loading of the pipe.

Claims (6)

1. A high-speed device for radial compression of pipes, including a pipe made of an aluminum alloy with a wall thickness δ of at least 10% of the internal diameter of the pipe, a softening gasket with a thickness of 0.4÷0.6δ, an annular layer of explosive material, a durable steel body, characterized in that the layer of explosive material is installed on a cylindrical striker made of the same material as the pipe, with a wall thickness of 0.4÷0.6δ, located coaxially with the pipe at a distance of 1.5÷2.5δ, on the striker there are two groups of paired symmetrical longitudinal grooves, evenly spaced around the circumference, overlapping along the length of the layer of explosive material lying on them, while two detonators are fixed on the body at two opposite points in the middle of one of the groups of grooves with the possibility of their initiation, for which a jumper with explosive material is left under the initiation points in the grooves on the striker, and in The device body has two openings for removing explosion products, located in the same cross-section as the detonators and turned at an angle of 90° relative to the initiation points. 2. The device according to item 1, characterized in that the grooves are made of different widths. 3. The device according to paragraph 1 or 2, characterized in that the grooves are filled with explosive material. 4. The device according to claim 1, characterized in that only two opposite grooves are filled with explosive material. 5. The device according to claim 1, characterized in that the grooves are made of the same width and filled with explosive material, and initiation is carried out at two opposite points of a longitudinal section, rotated relative to the sections in which the grooves are located, at an angle of 45°. 6. A device according to any of paragraphs 1-5, characterized in that the longitudinal axis of the grooves is rotated relative to the axis of the striker at an angle of 10÷45°.