DE2043251A1 - Explosive forming - by shock wave conducted into the workpiece from outside - Google Patents

Abstract

Explosive metal forming of hollow objects is effected by conducting a high speed high energy gas stream generated by an explosion outside the workpiece into it thereby deforming it dynamically. The method affords good control over the forming operation and is primarily intended for tube forming.

Description

Process and device for metal deformation with the aid of explosives The invention relates to a method and a device for metal deformation with The aid of explosives, for objects having a recess, in particular Tube.

There are numerous methods of forming metals using explosives known, for example also for pipe expansion. The most important areas of application the explosive pipe expansion are the inner lining of pipes with a so-called Shirt made of a different material, as well as fastening pipes in the bottoms of Shell and tube heat exchangers.

In these, for example, in German patent specification 956.934 and The method described in British Patent 1,160,761 becomes an explosive Load placed inside the pipe (s). After detonating the explosive charge is caused by the shock wave of the detonation and by the pressure of the expanding plumes the pipe wall in the area of the explosive charge accelerates outwards and lies against it the inner wall of the outer tube or the bore. It refers to a dynamic stress, so that it also leads to plastic deformation Deformation degrees below the elastic limit comes. But that means that Even with very small deformation paths, pressing into pipe grooves, annular grooves etc. takes place, whereby in itself a good adhesion between the two nested Pipes or the pipe and the bore wall is effected.

These procedures have, for example, compared to the conventional ones methods of rolling in with cold deformation and / or cutting in the pipes into the base plate of the Rörenbündel- Heat exchanger the advantage on that they are particularly suitable for smaller pipe diameters and / or longer bores are less difficult and tedious.

However, these known methods are not fully satisfactory because the attachment and / or the proper ignition of the explosive charge inside the Pipes is often still too difficult or possibly even impossible. So is particular in the case of longer pipes, the centering and / or the exact dosage of the amount of explosives not always easy, while there is an explosive column with too small a cross-section The detonation can even break off, i.e. perfect ignition is not guaranteed. Another disadvantage is that the inside of the pipe remaining explosion fumes even after deformation has taken place under one high pressure and thus possibly silver the desired pressure and another Can cause expansion. In addition, sometimes the pressure is unevenly namely stronger in the middle than at the ends of the area to be pressed, because the vapor pressure drops faster at the ends. Strengthen one to avoid this Effect the charge at the ends.

so, instead, an undesirable bulge can, for example occur on the part of the pipes protruding from the base plate.

It is also known that in the detonative implementation of explosive devices Gas flows can occur, their duration and energy content in particular then are extremely large if the explosive device has a cavity in a FOJW Bore, a channel, gap or the like. Have in which the gas flow is formed can (see, for example, h.

Ahrens, ~ On the detonation process in cylindrical explosive charges with axial hollow ", Explosivstoffe, 1965, issue No. 5, pages 124-134). Conditional The compression of the air in front of such a gas flow creates a shock wave off, In the case of explosive substances, the speed of this gas flow is to the Part considerably greater than the detonation speed, d. H. such a gas flow then precedes the detonation front.

The invention is based on the above-mentioned object Disadvantages of metal deformation with the aid of explosives with regard to the application in the case of objects having a recess, in particular pipes.

To solve this problem, according to the invention, the at the detonative implementation of an explosive charge occurring in a manner known per se High speed gas flow and high energy content at least partially to lead into the recess of the object and to deform the area to be deformed in a predetermined manner by dynamic compressive stress.

By using the effect of gas flow in metal deformation it is surprisingly possible to use the explosive that supplies the deformation energy, not to be attached inside the objects to be deformed, but outside. The gas flow of great speed and high energy content is generated by the explosive charge guided out with the help of pipes into the object to be deformed. By doing The object then forms a high pressure gas jet that is sufficient to deform the Area of the object by means of an extremely brief dynamic pressure load to deform to the desired extent.

In an expedient embodiment of the invention, an explosive charge is provided to use the at least one cavity in the form of a bore, a channel, Gap or the like.

has, in which the gas flow used for the deformation trains. The cavity need neither be cylindrical nor must it be as well as the conduction pipe for the gas flow necessarily has a circular cross-section rather, it can also be any other advantageous in the particular application Have shape, as such cascades are trispecial with explosive Form explosives in any type and shape appropriately sized cavities. For example, a Syrengstofsäule can be used, which consists of two nested Consists of pillars, the inner of which is solid and the outer of which is hollow, and interconnected form an annular gap. In the detonative implementation of the column In this intermediate space, a gas flow which leads the detonation front is formed which can be used for metal deformation with the appropriate forwarding.

The pipe serving as a guide device for the gas flow needs not necessarily to be straight. It can be curved, for example, depending on the circumstances be, several kinks, any angle or the shape of a spiral or helical line to have. What material is the pipe for the gas flow and in which Thickness it is made depends on the requirements of the individual case. For example it can consist of glass, paper, plastic or metal. Preferably it will designed so that it is under the action of the gas flow on its entire Disassembled length. However, even with a greater distance between the explosive charge and to achieve the greatest possible effect in the area to be deformed, according to Another proposal of the invention can be provided, in these cases the transmission pipe between the explosive charge and the area to be deformed, at least in sections designed so that it does not decompose under the action of the gas flow.

If the cross-section of the area to be deformed is greater than the optimal cross-section of the gas flow is, according to another proposal, the Invention between the gas flow.

and the wall of the area to be deformed a transmission medium intended. Gaseous, liquid or solid phases can be used as the transmission medium are used, the former of all things expediently only in lesser amounts Layer thickness, i.e. with smaller differences in cross-section. As a liquid phase can for example oil or water can be used while as fixed Phase, such substances can be used that can be sufficiently easily deformed, So for example sand, plastic granulate or other powdery substances. as well but a solid body made of plastic, for example, can also be used, which is sufficiently plastic and / or elastic.

The size of the pressure build-up or the dynamic pressure load in the area to be deformed can be controlled, for example, by the distance between the explosive charge and the area to be deformed, through the diameter and the material of the propagation tube, by the type and quantity of the explosive and through the transmission medium. The pressure jam is of course also dependent on whether the conduction tube simply rests on a surface of the explosive charge or connected to a Hditaum, for example an axial bore, the explosive charge is. In the latter case, the diameter of the bore and that of the propagation pipe can be varied within wide limits. Suitable values for this are generally those which are between 1 and 30 mm, preferably between 4 and 18 mm.

Is the cross-section of the area to be deformed compared to the optimal cross-section of the gas flow is very large, so it is advantageous at least to use two gas flows which - based on the same cross-sections of the to deforming area - take effect at the same time. The at least two '~ gas Currents are distributed over the cross-section of the area to be deformed supplied that a pressure load that is as equal as possible is achieved everywhere. If, for example, the cross-section of the area to be deformed is symmetrical, then so the different gas flows acting simultaneously become symmetrical initiate.

The at least two gas flows can each have a special explosive charge be generated. With a view to the simplest possible, efficient way of working However, it is more advantageous to use a demolition according to the invention with as many cavities is formed as gas flows are to be generated. Each A conduction pipe for the gas flow is assigned to the cavity. Form the explosive charge is selected according to the requirements. For example, you can cylindrical, cuboid or plate-shaped.

Apart from the fact that the transmission pipes are all one and the same to be deformed object can be supplied, but you also have the Possibility of foaming on different objects in an advantageous way at the same time, d. H. To be able to do in one operation, by the with an explosive charge generated gas flows are fed to various objects.

Is the area to be deformed so large, for example so long that the deformation cannot be carried out by means of a single gas flow, so can on the use of special ones that do not decompose under the action of the gas flow Sections of the transfer pipes may be omitted if at least two gas flows to be deformed simultaneously or one after the other from different sides Area to be fed, as in this way the distance between the respective Explosive charge and the associated part of the "deformed area" as small as possible can be held.

The inventive separation of the explosive charge from that to be deformed The subject has many advantages. The explosive charge can e.g. in a steel case be housed as a protective device, from which then the transmission pipes to the object to be deformed. This can increase the security of such Working method can be increased significantly. The transfer pipes for the gas flow can moreover with much greater accuracy in the objects to be deformed be introduced as this with the conventional method, the explosives within to arrange the object to be formed, has been possible so far. Also is, 7 the Pressure build-up in the object to be deformed - as explained above - very precisely adjustable.

The inventive method of metal deformation can, for example are used in the following cases 1. Lining of cavities, in particular Pipes, with a so-called shirt made of a different material. The cross-section the cavities, for example, by drilling grooves or grooves on the individual Make different.

2. Fastening pipes in floors, flanges or the like.

3. Joining pipes together.

4. Calibrating tubes with and without external matrices.

5. Deformation of any object having recesses .mit and without outer matrices.

The invention is shown in the drawing in execution examples and is explained in more detail below on the basis of this.

They each show in longitudinal section - with the same parts with the same Reference numerals are provided -Fig. 1 an arrangement for lining a pipe, Fig. 2 + 3 an arrangement for fastening a pipe in a flange, Fig. 4 a Arrangement for the simultaneous fastening of several pipes in a base plate, Fig. 5 + 6 an arrangement for connecting two pipes to one another and Fig. 7 shows an arrangement for deforming a pipe.

According to FIG. 1, the explosive charge 1 has a cavity 2, an axial one Bore, formed. The conduction pipe 3 is connected to the bore extending over the entire length of the lining pipe inserted into the pipe 4 5 extends and is surrounded within this by the transmission medium 6. On that of the end facing away from the explosive charge 1 is the conduction pipe 3 depending on the requirements, for example the length of the lining tube 5 to be deformed, open or - in order to increase the pressure build-up - closed by means of a plug 7. To that Transmission medium 6, e.g.

Water to keep in the pipe 4, this is at the lower end by means of a Disc or a plug 8 closed.

Is the explosive charge 1 by means of the ignition 9 and the booster charge 10 ignited, a gas flow forms in the cavity 2, which is directed to the connected forward pipe 3 exerts such a strong lateral pressure surge that that this is broken down into the smallest particles. Through the transmission medium 6 the pressure surge propagates outward to the lining pipe 5, the one undergoes extremely short-term dynamic pressure stress and is therefore firmly attached to the outer tube 4 is pressed.

In the case of the linings carried out in practice according to FIG As in the other exemplary embodiments, an explosive charge 1 was used, the one from 150 g Composition B - an explosive from 39.5 wt .- # trinitrotoluene, 59.5 wt% cyclotrimethylene trinitramine and 1 wt% wax.

The cylindrical explosive charge 1 has a length of 140 mm.

a diameter of 30 mm and had an axial bore of 10 mm. A detonator Nn8 was used as the ignition 9, which is an aluminum capsule with a squib, one. Primary set of 0.3 g lead ricinate and a secondary set of 0.9 g of tetryl is used. Booster charge 10 was a pre-ling off 26 g of pentaerythritol tetranitrate. The transmission pipe 3 existed the end Glass (outer diameter 13 mm, 1.5 mm thick) or PVC (outer diameter 12 mm, 1 mm thick) and was attached to the end of the explosive charge 1 in alignment with its bore or inserted into them to a length of a few millimeters.

Inside coverings on pipes with a tight shirt were e.g. made with the following pipes, with the numbers indicating the inside and outside diameter specify 1. water pipe, 36 or 42 mm, with copper pipe, 30 or 33 mm, 2. Water pipe, 27 or 34 mm, with stainless steel pipe, 23 or 35 mm, 3rd drawn iron pipe, 36 or 42 mm, with copper pipe, 30 or 33 mm, 4th drawn Iron pipe, 36 or 42 mm, with lead pipe, 35 or 33 mm, 5. Drawn iron pipe, 36 or 42 mm, with brass tube, 33.5 or 34.5 mm, 6th drawn iron tube, 36 or 42 mm, with aluminum tube, 24 or 28 mm, 7th tube made of plasticized PVC, 33 or 60 mm, with lead pipe, 20 or 30 mm, 8th pipe made of plasticized PVC, 22 or 52 mm, with copper tube, 15 or 18 mm.

The pipe lengths were between 0.5 and 2 m.

With explosive charges 1 in the form of cylinders, cuboids or plates, which had several bores and transfer pipes 3 for the gas flow, were with one shot at the same time several tubes 4 with a shirt Inside covered from a different material.

The liner pipe 5 serving as a shirt was the same length as the tube 4, or was also longer or shorter.

The assembly shown in Fig. 2 is used to press in one end of the tube 4 in a flange 11, while the arrangement according to FIG. 3, the pressing any point of the tube 4 in a flange 11 allows. Here is that Forward pipe 3 for the gas flow in the area of the pipe 4 to be deformed again surrounded with a transmission medium 6, which at the required point of the pipe 4 is held in accordance with FIG. 2 by means of a plug 8. Instead, for example also be provided, the water used as the transmission medium 6 in one to accommodate the cross-section of the tube 4 filling plastic bag (not shown) and to attach it to the forwarding pipe 3, for example by gluing. In order to it is possible in a simple manner, the compressive stress on the pipe 4 substantially to be limited to the area of the pushed-on flange 11.

In a practical example, an iron pipe 4 with 52 mm inner and 60 mm outer diameter in a flange 11 with an inner diameter of 60.5 mm with an outer diameter of 165 mm and a thickness of 15 mm. the The height of the water column introduced with a plastic bag was 75 mm.

In the arrangement shown in FIG. 4 for simultaneous press-fitting a plurality of tubes 4 in the base plate 12 of a tube bundle # ärmeaustauschers an explosive charge 1 with three cavities 2 and, accordingly, three conduction pipes 3 used. The rest of the arrangement and the sequence of the press-fit process are the same otherwise of FIG. 2. Of course, this must be done by means of known devices it is ensured that the explosive charge 1 is as possible on its entire face is ignited simultaneously by the booster charge 10.

In a practical example, drawn iron pipes were used with a Inside diameter of 36 mm and an outside diameter of 42 mm into a 15 mm thick Iron base plate with holes 42.5 mm in diameter. The height the water column used as the transmission medium 6 was 60 mm. The cylindrical In this case, explosive charge 1 had a diameter of 50 mm.

According to Fig. 5 is provided for the purpose of connecting two tubes 13 and 14, to let these butt against each other with their end faces and in the area of the Joint to arrange an inner sleeve 15, the length of which is such that it after pressing against the tubes 13 and 14 their sufficiently firm connection is guaranteed. In the sleeve 15 is the forwarding pipe 3 with the plug arranged at the end 7 guessed. The transmission medium 6 extends over the entire length of the sleeve 15 and is held in this by means of a stopper, bag or the like, not shown. If the forwarding pipe 3 with its end facing away from the explosive line 1 leads out of the sleeve 15, so can of course on the use of the plug 7 may be waived, provided that the resulting reduction in pressure build-up is permissible is, for the connection of two pipes 13 and 14 with an inner diameter of 36 mm and an outer diameter of 42 mm was a copper sleeve 15 with an inner diameter of 30 mm, an outer diameter of 33 mm and a length of 70 mm are used, before pressing in the area of the joint, for example by hanging was held. The column of water used to transmit the surge was So mm high, i.e. slightly larger than the length of the sleeve 15.

In Fig. 6 is a slightly different arrangement for connecting.

two tubes 13 and 14 are shown, which compared to the ones according to Fig. 5 has the advantage that the clear cross section of the tubes 13, 14 in the area of Connection point is not changed, so the flow resistance is at most slightly increased. For this purpose the tube 13 is on its outer surface with a twist and the tube 14 on its inner surface with a corresponding to it Provided from rotation that both tubes 13, 14 can be plugged into one another. Even here is the pressure effect of the gas flow through a column of water, which in not shown Way in a plastic bag, above a stopper or between two spaced-apart plugs are filled onto the to be deformed Area of the connection point limited. The junction itself is at this one Surround the type of pipe connection with an outer two-part die.

In a practical example, two drawn iron pipes were used an inner diameter of 52 mm and an outer diameter of 60 mm with each other tied together. For this purpose, one tube was turned off to a diameter of 54.7 mm and the other turned to a diameter of 55 mm. The length of the ab- or The recess was 40 mm, while the water column and the matrite 16 had a height of loo mm.

According to Fig. 7, the tube 17 to be deformed is at its two ends loosely inserted into the spaced apart tubes 18 and 19. In the manner explained above, the transmission medium 6 is provided in the pipe 17 and the forwarding pipe 3 into the transmission medium 6 or possibly also through it this passed through. After the pressure load has taken place, the tube 17 takes about the expanded shape 20 indicated by dashed lines. You have it accordingly the above explanations in hand, if necessary the pipe 17 as well to connect to the tubes 18 and 19 at the same time. Will the deformation without external Die carried out, the final shape achieved depends on the relationship between the dimensions and the material properties of the pipe 17 and the magnitude of the compressive stress away. When using an outer die, not shown, the end shape of the tube is 17 predetermined by this.

To a. Copper pipe 17 with an inner diameter of 30 mm, a Outside diameter of 35 mm and a length of 100 mm in the protruding To deform as explained, this was in the two at a distance of 60 mm from each other arranged iron pipes 18, 19 with an inner diameter of 36 mm and an outer diameter of 42 mm inserted into it. The pressure surge was limited to the copper pipe 17 through a water column loo mm high. The copper pipe became 17 expanded by 13 mm to 48 mm at the point with the largest diameter. the Deformation took place here without an external die.

If relatively long pipes are to be provided with an inner lining, this may have to be carried out with two or more at the same time or one after the other Shelling take place. In such a case, on the one hand, the gas flows be introduced from both ends of the pipe to be lined in order to shorten it to achieve the required length of the transmission pipes. On the other hand you can but these transmission pipes are also designed as so-called armored pipes, which are made of a metal of sufficient thickness so that they are the side Resist the pressure of the gas flow.

In this way it is possible to control the gas flows over long periods of time To guide routes without significant energy losses. At least within of the area to be deformed, the conduction pipes are designed so that they can be dismantled again, so that the gas flows the required compressive stress on the to be deformed Can exercise pipe wall. Are several gas flows through in the at the same time Length of suitably stepped armored pipes introduced, so can be on this Also make relatively long pipes in one operation with one shirt from another Material provided.

When pressing pipes into base plates, boiler floors or the like. can be the number of tubes that are simultaneously in one operation according to the invention Procedure to be pressed in, be considerable and is to the respective proportions adapt. Depending on the requirements, the end of the pipe with the base plate, the boiler bottom or the like. Cut off, protrude or only partially inserted into this be.

In order to act on the object to be deformed in the detonative To exclude implementation of the explosives by the shock wave and the vapor flow, was in the specified embodiments between the explosive charge and the object to be deformed a protective shield (not shown) with one or more Openings for the implementation of the transfer pipes for the gas flow set up.

The exemplary embodiments demonstrate the versatility of the invention Use of a gas jet of high speed and high energy content for Metal deformation. The deformations shown on and in pipes can be analogous also in bores or recesses of larger components, for example for warehouse clothing on machines or for pressing pipes into drill holes in concrete walls.

Except for the explosive composition B already mentioned above all explosives suitable for the method according to the invention, with their detonative Implementation, gas flows of high speed and high energy content develop.

During the practical testing, trinitrotoluene, Nitropenta, Hexogen and Tetryl as well as trinitrotoluene and low density nitropenta - as described in the Norwegian patent application no. 119.717 - used, whereby the explosive charges were shot with or without an external insert.

Claims (10)

Claims 1. Process for metal deformation with the help of explosives, for a Objects having recesses, in particular pipes, are d u r c h e k e n n z e i c h n e t that the detonative implementation of an explosive charge in gas flow occurring in a manner known per se, high speed and high Energy content6 at least partially directed into the recess of the object and its area to be deformed by dynamic compressive stress in a predetermined Way defonned. 2. The method according to claim 1, characterized in that the explosive charge at least one cavity in the form of a bore, a channel, gap or the like. in which the gas flow used for the deformation is formed. 3. The method according to claim 1 or 2, characterized in that the Gas flow is directed by means of a guide device, which is located under the Effect of gas flow decomposed. 4. The method according to claim 1 or 2, characterized in that the Gas flow between the explosive charge and the area to be deformed by means of a Guide device is directed, which is at least partially under the effect the gas flow is not decomposed. 5. The method according to any one of claims 1 to 4, characterized in ^ that between the gas flow and the wall of the area to be deformed there is a transmission medication is provided. 6. The method according to any one of claims 1 to 5, characterized gekermzeichnot, that at least two gas flows are used which - based on the same Cross-section ~ of the area to be deformed - become effective at the same time. 7. The method according to any one of claims 1 to 6, characterized in that that at least two gas currents are generated with one explosive charge, the same or can be fed to various objects. 8. The method according to nem of claims 1 to 7, characterized in that that at least two gas flows simultaneously or successively from different ones Pages are fed forward to the area to be deformed. 9. Device for performing the method according to one of the claims 1 to 8, characterized in that at least one tube is attached to the explosive charge (1) (3) is connected as a guide device for the gas flow. 10. Device according to claim 9, with at least one cavity having explosive charge, characterized in that the tube (3) directly with the Cavity (2) is connected. L e r s e i t e