DE2414412C3 - Equipment for the explosive processing of metals - Google Patents

Description

30th

The present invention relates to a device for the explosive processing of metals, the has a closed chamber in which the workpieces to be processed and the explosive are accommodated and means for damping the explosion wave are provided.

Such chambers, which have a thin-walled single-layer or multi-layer container with a lid and Represent soil are known (DT-OS 16 52 642). The explosion chamber has a capacity that is determined by the permissible quantity of the explosive substance that will explode in this chamber, as well as the size of the working volume, which must allow the expansion of the explosion products, as well as the strength of the housing.

It follows that to increase the capacity of the explosion chambers, the working volume of the Explosion chambers, d. H. the external dimensions, and also the strength of the housing and the other components of the Explosion chamber must be increased. In the case of an increase in the external dimensions of the known The explosion chamber must have the thickness and rigidity of the housing walls in order to maintain its load-bearing capacity Reinforced (e.g. by means of ribbing) and the strength of the parts used to fasten the shelves, the cover frames, etc. serving components are increased, what the manufacture and operation of the known explosion chambers of increased capacity made more difficult and expensive.

The need to use thick sheet metal for the housing and other components of the Explosion chambers with larger external dimensions make the manufacture of the chamber, especially in die forging and in the subsequent welding, especially of the components of the chamber housing, difficult.

In addition, the weld seams connecting the thick sheets are significantly lower Have strength compared to the base material, especially when it comes to the action of

dynamic loads on the construction

The high costs for thick sheet metal and the increased tendency of thick Bbch to form defects, which can lead to local damage to the chamber during the explosion, are also disadvantageous. Even if damage that has occurred, for example breakthroughs caused by splinters , is repaired by welding, the load-bearing capacity of the explosion chamber is not completely restored as a result.

The above statements characterize the most essential shortcomings of the known types of construction Stand in the way of high-capacity explosion chambers. Practically there are ones made of metal Explosion chambers of high capacity at the moment not at all, and to carry out strong Explosive deformations are used in industrial structures such as tunnels, carriages, etc., first of all are very expensive and, secondly, are usually far from the machine shops. These circumstances oppose the use of explosion deformation technology.

The invention is based on the object of providing a device while avoiding the above-mentioned deficiencies to create explosive processing of metals, which is easy to manufacture and a compared to the known chambers larger working volume with high strength, energy capacity and operational reliability of the housing and its other components, which in turn significantly increases the Performance of the explosions generated in the chamber should be made possible.

This object is achieved in that the explosion chamber in the generic device through the end faces of many tubes abutting one another with the edges, which are essentially normal to the imaginary wall surface of this chamber are arranged, is formed, with the spaces between these tube ends are closed and each tube is at least half the length of the smallest Length dimension of the chamber.

Such a constructive solution makes it possible in the Chamber to generate explosions of high power for the explosive processing of metals and simultaneously also to increase the operational safety of the chamber. With the construction mentioned, it is possible to Manufacture of the chamber a thin-walled semi-finished product (sheet metal and tubes) that has high strength values and has a low tendency to damage, to use and the manufacture of the chamber, in particular to simplify the work of the welder of the thin-walled components of the housing.

The material of the tubes is fully used in terms of strength that the deformation of the Pipes through the explosion takes place one after the other in the circumferential and axial direction. The danger that the chamber fails due to local damage is low because individual tubes can be easily replaced and the safety of the chamber is thereby fully restored to the initial state. In addition, the proposed construction makes it possible to reduce the energy of the gas flows in each pipe to which their considerable length in comparison to the dimensions of the chamber contributes and the size of the effective surface area of the components of the housing (the tubes) causes a intensive heat transfer from the gas flow to the pipe

and from this to the atmosphere, causing excessive overheating of the pipe walls when in use of the chamber in flow production.

According to the invention, adjacent «pipes can be connected to one another be rigidly connected by means of webs, and the free space between the tubes mentioned can with Bulk goods are filled.

This allows the load-bearing capacity of the chamber to be additionally increased, namely by the fact that the Due to its inertia, the mass of the bulk material contributes to the absorption of the dynamic impulse loads and the vibrations of the components of the chamber housing caused by the explosion are damped.

The outer ends of the pipes in question can be sealed airtight, creating the possibility is created to evacuate the chamber before the explosion as well as the flying out of explosion products to avoid being in the open air.

A concrete example of the construction of the device is made with reference to the drawings described below.

Fig. 1 shows the device for explosive processing of metals according to the invention; View partly in section,

F i g. 2 the top view with the cover removed.

The device for explosive processing of metals contains several rows that are laid horizontally on top of one another straight tubes 1 (Fig. 1) of round cross-section. In plan, the tubes 1 are fan-shaped in the same way Distances from one another so arranged that their facing end faces 2 are cylindrical Form chamber 3. The edges of the mentioned end faces 2 of the adjacent tubes 1 come into contact with one another Contact, and the axes of the tubes 1 are normal to the cylindrical chamber 3 at the point where the chamber 3 is in communication with each pipe 1. In the present case, the tubes 1 are radial arranged, the length ..mes of each tube 1 is taken equal to the diameter of the cylindrical chamber 3.

The outer ends of the tubes 1 can be blocked off with floors 4 (FIG. 2).

At some points along their length, the tubes 1 are firmly connected to one another by means of horizontal webs 5, which in turn are firmly connected to one another by means of vertical webs 6.

The spaces between the inner ends of the tubes 1 are along the circumference of the tubes 1 with sealed seams welded molded metal insert pieces 7 shut off. The free space between the Pipes 1 is with bulk material 8, z. B. sand, earth, metal particles, etc. filled. The chamber 3 is with a Metal base 10 and a cover 9 are provided.

Inside the tubes 1 are plate elements 11 arranged, which are connected to the walls of the tubes 1 in such a way that between their Edges and the tubes 1 a sufficient clearance for the passage of the gas flow is maintained and their height increases the closer they are to the bottom 4 of the tube 1. The elements listed above can have different shape and different angles of inclination to the axis of the tubes 1, they can also not with the walls of the tubes 1, but by means of a rod set up along their axis with the Floors 4 be connected. In this case the plate elements become normal to the direction of the gas flow set up.

When setting up the proposed design for the explosive processing of metals, the chamber 3 different shapes such as parallelepiped, cylinder, sphere, hemisphere, etc. In some cases the above construction of the chamber 3 makes it possible to dispense with some of the known explosion chambers traditional components, e.g. B. Lids and bottoms. In particular, one of the tubes 1 can be used as a tunnel for the Access to the interior of the chamber 3 can be used and the underground can serve as a base area, with to which the chamber is connected via piles. If there are floors 4 on the pipes, you can do before evacuate the chamber space after the explosion.

The operation of the device is as follows:

As is the case in the known constructions of the explosion chambers, the to machined workpieces and the charge of the explosive in the proposed device im Central part! the chamber 3 housed. In the event of an explosion, the explosion products fly apart, whereby (in the case of the non-evacuated chamber) a shock wave roughly spherical in the Chamber 3 filling air is generated. The shock wave reaches the open ends of the tubes 1 and continues its movement by dividing into individual gas streams in each of the tubes 1. With the Penetrating into the tubes 1, the material of the tubes becomes deformed in the circumferential direction subject, in that the overpressure behind the shock front exerts its effect. Accordingly and also through the intensive heat exchange with the inner surface of the pipe 1, the characteristic values (temperature and pressure) of the gas flow with the advance of this flow. When the meeting on the floor 4 occurs lower braking of the current and the material of the tubes 1 begins to be subjected to deformation in the axial direction which means that the energy of the current continues to be attenuated and its characteristic values are reduced will. The interaction of the currents with the Pipes 1 causes elastic damped vibrations of the pipes 1 and a gradually going on Dissipation of the energy as a result of the damping of the vibrations and the intensive heat exchange.

As an additional means to increase the load-bearing capacity of the chamber 3, the space between the Tubes 1 filling bulk material, which increases the inertial mass of the chamber 3 and the damping of the Vibrations of the pipes 1 as a result of the dissipation caused by the above-mentioned bulk material the energy amplified.

The plate elements 11 inserted into the interior of the tubes 1 deflect the path of the gas flows, by swirling the latter and directing them towards the walls of the tubes 1, which to a fuller extent the Dissipation of the energy of the same promotes and in that the passage cross section of the tubes 1 with the Approaching the bottoms 4 decreases, the more intensive braking of the currents with the advance the same along the tubes 1 and thus consequently - their more even loading ensured along the length.

The choice of the dimensions, in particular the length of the tubes 1 forming the chamber 3, these Length should not be less than 1/2 of the smallest length dimension of the chamber 3, takes place on the basis from the fact that the requirements for the optimal metal content and the high rigidity of the Chamber 3 as well as the required dissipation of the energy of the gas streams in the pipes

will. Here are the requirements listed above the better to meet the longer the pipes I are.

The dimensions and the number of webs 5 and 6 are chosen while satisfying the condition of the same Strength of the tubes 1 and the chamber 3 under conditions where the pulse pressure and the static pressure (residual pressure of the explosion products) can be assumed.

The introduction of the workpieces and the explosive charges as well as the removal of the same will be carried out either by hand or with the help of means of transport and lifting equipment through the upper with the Lid 10 closable opening of the chamber 3 or through one (serving as a tunnel) the horizontal running pipes 1 carried out. After the explosion, eggs

becomes the cavity oer chamber 3 and the tubes 1 vented to dispose of explosive gases.

Characterized in that as the main elements of the chamber 3 of the proposed device thin-walled tubes I serve, it turns out that with comparable metal expenditure for a known and the proposed Chamber the carrying capacity of the proposed chamber is significantly higher, which prevents explosions greater force can be generated in the chamber.

Due to the ease of manufacture and the security of the Chambers are also possible with large dimensions, the same also for series of over-sized To use explosions, whereby these generate explosives with a load of several hundred kilograms could be.

1 sheet of drawings

Claims (3)

Patent claims: 1. Device for explosive processing of metals, which has a closed chamber, in which the workpieces to be processed and the explosive are accommodated, as well as means are provided for damping the explosion wave, characterized in that the Explo sion chamber (3) through the end faces (2) of many more straight lines lying against one another with the edges Pipes (1) which are arranged essentially normal to the imaginary wall surface of this chamber (3), is formed, the spaces between these end faces (2) of the tubes (1) being closed and each tube (1) is at least 1/2 the length of the smallest length dimension of the chamber (3). 2. Device according to claim 1, characterized in that adjacent tubes (1) are rigid are connected to each other by means of webs (5,6) and the free space between the tubes (1) with Bulk material (8) is filled. 3. Device according to one of the claims 1 or 2, characterized in that the outer ends the tubes (1) can be sealed airtight.