DE3928241C1 - Explosion chamber for metal processing - has steel upper section with impact absorbing lining - Google Patents

Abstract

Explosion chamber for explosive processing of metals has an upper part (1) of inverted pot shape, mfd. from steel, with impact-absorbing lining, forming a hollow space (2). One connection (3) leads to a vacuum pump, while a second (4) allows toxic gases to be exhausted. A lower part (6) consists of steel (7), surrounded by a foundation (8). The two parts have cylindrical cross sections, the upper part fitting in the lower part in telescope fashion, with a sealing element (12) between them. ADVANTAGE - Escape of toxic gases with high charges and high pressure wave outside the chamber are avoided.

Description

The invention relates to an explosion chamber for Explosive processing of metals according to the generic term of Claim 1.

An explosion chamber of this type is from DE-PS 35 27 730 known. The chamber cavity is a hood formed, the energy-converting installation materials is provided. The chamber cavity can be evacuated.

In explosive processing, z. T. toxic gases, which contain CO, CO ₂ and NO ₂ . These gases must be withdrawn from the explosion chamber in a semi-targeted manner, and it must be reliably prevented that these gases escape in an uncontrolled manner.

In the known device star must be used ker explosion charges are expected that the Seal between hood and floor pan during detonation is canceled at short notice. This leads to one inadmissible escape of the gases mentioned. Moreover, in the area surrounding the explosion chamber when ineffective seal with damage due to a high pressure wave can be expected, which are then outside of the Explo sion chamber spreads during a detonation.

In contrast, there is the object of the present invention in ver ver the disadvantages of the known explosion chamber avoid and create an explosion chamber where too in the case of particularly high loads, an escape of toxic gases reliably excluded and a high pressure wave except half of the explosion chamber can be avoided.

This object is achieved in an explosion mer of the type mentioned in that the Kam  reverse upper part is pot-shaped and teles like a head into the lower part of the chamber and its filling engages and that the sealing element a seal between Outer surface of the upper chamber part and inner surface of the Lower chamber causes.

The explosion chamber according to the invention cannot either with certainty that the Chamber Detonation top against the chamber bottom suddenly shifted. Such a shift, however, eliminates the explosion chamber of the invention the effect of Seal does not open, so even then guarantees a si More reluctance to use harmful gases and emissions high pressure wave. This will undermine this effect supports that the filling of the lower part of the chamber has a dampening effect and also represents a significant resistance that prevents the escape of harmful gases. A te Lescope-like displacement of the pot-like upper part of the chamber the lower part of the chamber is therefore generally harmless. The upper part of the chamber will be in such a case after detonation due to its own weight lower back to the starting position.

The explosion chamber according to the invention can also be so forms that a loading opening in the upper chamber part for the introduction of the explosively processed metals is seen. Basically, it is also possible to go to the one bring the chamber part of the metals to be processed pull out of the lower part of the chamber. The necessary for this however, the amount of work involved is usually not lost be pedalable. There will therefore be a loading opening recommend, for the pressure-resistant and tight doors principle are known.

The explosion chamber according to the invention can also be so forms that the lower chamber part of a concrete funda ment is surrounded.  

The explosion chamber according to the invention can also be so forms that the filling of the lower chamber part from Rie selkorn and / or sand.

The explosion chamber according to the invention can also be so forms that the filling is the contact surface for the Ex plosion processing forms.

The explosion chamber according to the invention can also be so forms a plate lying on the filling part of the contact surface for explosion processing bil det.

The explosion chamber according to the invention can also be so forms that the wall thickness of the upper chamber part whose lower edge tapers downwards. This will the introduction of the upper chamber part into the lower chamber part promoted. Also the lowering of the upper chamber part again after a lift due to a detonation is on this Way accelerated and supported.

The explosion chamber according to the invention can also be so forms that the chamber upper part in the area of the filling level is reinforced on the inside. This reinforcement can also consist of such materials which convert the impact energy noticed during the detonation.

Finally, the explosion chamber according to the invention can do so be designed so that at least the upper part of the chamber Use of impact materials converting impact energy is constructed. Here are for the construction and the coating all materials that can be used according to the state of the art Technology for relevant hoods have already been described are.

In the following part of the description, an execution shape of the explosion chamber according to the invention using a Drawing described.  

The embodiment shown in the drawing of the explosion chamber according to the invention has a chamber upper part 1 , which is conversely pot-shaped. Its wall is made of a suitable steel and can be equipped with shock-absorbing linings and reinforcements in a known manner. The upper chamber part 1 forms a chamber cavity 2 . A connection 3 leads to a vacuum pump, not shown. A connection 4 can be used to remove toxic gases that may be generated during the detonation.

At its lower edge 5 , the wall thickness of the upper chamber part 1 tapers downwards.

A lower chamber part 6 is provided, which is formed from an inner pot 7 made of steel and from a surrounding foundation 8 .

Upper chamber part 1 and lower chamber part 6 have a cylindrical cross section. The outer diameter of the upper chamber part 1 is adapted to the inner diameter of the lower chamber part 6 , so that the upper chamber part 1 is guided roughly telescopically in the lower chamber part 6 .

In the lower chamber part 6 there is a filling 9 made of grit or sand. This filling 9 has a level 10 , which directly forms a support surface for the metal or metal parts to be treated. However, it is also possible to place a plate part 9 ' as a support on this filling 9 and then place the metals or metal parts to be machined on it.

In the wall of the upper chamber part 1 there is a loading opening 11 which can be closed in a suitable manner by a known pressure-proof and sealed door.

Finally, a seal 12 is provided, which closes the gap between the outer surface of the upper chamber part 1 and the inner surface of the pot 7 , even when the upper chamber part 1 is shifted relative to the lower chamber part 6 .

A reinforcement 13 is provided on the inner surface of the upper chamber part 1 in the area of the filling level 10 .

The lower chamber part 6 is embedded in a bed 14 of sand, gravel and the like.

Claims (9)

1. Explosion chamber for explosive processing of metals with a chamber lower and a chamber upper part inserted into a foundation, which work together via a sealing element between two parts effecting sealing element th, with a vacuum connection and a discharge line for explosion gases, the lower chamber part forming like a pot and is filled with a shock-absorbing filling in wesent union, characterized in that the chamber upper part ( 1 ) is reversely cup-shaped and telescopically engages in the lower chamber part ( 6 ) and its filling ( 9 ) and that the sealing element ( 12 ) has a seal between the outer surface of the upper chamber part ( 1 ) and the inner surface of the lower chamber part ( 6 ). 2. Explosion chamber according to claim 1, characterized in that in the upper chamber part ( 1 ) a Beschickungsöff opening ( 11 ) for introducing the explosively processed Me metals is provided. 3. Explosion chamber according to claim 1 or 2, characterized in that the lower chamber part ( 6 ) is surrounded by a clay foundation Be. 4. Explosion chamber according to one of the preceding claims, characterized in that the filling ( 9 ) of the lower chamber part ( 6 ) consists of grit and / or sand. 5. Explosion chamber according to one of the preceding claims, characterized in that the filling ( 9 ) forms the bearing surface for the explosion processing. 6. Explosion chamber according to one of claims 1 to 4, characterized in that one on the filling ( 9 ) on lying plate part ( 9 ' ) forms the bearing surface for the explosion processing. 7. Explosion chamber according to one of the preceding claims, characterized in that the wall thickness of the upper chamber part ( 1 ) tapers downwards at its lower edge. 8. Explosion chamber according to one of the preceding claims, characterized in that the upper chamber part ( 1 ) is reinforced on the inside in the region of the filling level. 9. Explosion chamber according to one of the preceding claims, characterized in that at least the chamber upper part ( 1 ) is constructed using installation materials converting impact energy.