NL8005276A - DEVICE AND METHOD FOR ABSORBING GASES ESCAPING FROM CHEMICAL LASERS. - Google Patents

Description

Short designation: Device and method for absorbing gases escaping from chemical lasers *

The invention relates to a device for absorbing gases escaping from chemical dischargers and more particularly to a device for absorbing gases from a hydrogen acid laser, and to a method for operating this device.

As is known, chemical hydrogen acid lasers are fed with a flammable gas, for example deuterium or hydrogen, and a combustion-sustaining gas containing a halogen, for example chlorine, bromine, iodine or a halogen compound. The reactive gases, usually diluted with a neutral gas, for example, nitrogen, burn in a combustion chamber to form free halogen atoms which are fed into the optical chamber of the laser. Hydrogen or deuterium is then injected into this chamber, which bonds to the free halogen atoms to form excited halide molecules. When going to a lower vibration level, the energized molecules generate a laser beam. Since the laser operates at low pressure (below 50 Torr), the gases are pumped out of the chamber.

These gases, for example D2, HF and DF, are highly toxic and cannot be released directly into the atmosphere, especially if the chemical laser belongs to the equipment of, for example, an aircraft.

French Patent 2,298,205 describes an apparatus for absorbing gases from a hydrogen acid laser. This device consists of a gas-tight cylindrical metal container, in which calcium is contained under vacuum and which is coated on the outside with a heat-absorbing material, for example sodium chloride, while other heat-absorbing materials, for example lithium hydride, can also be used.

The device further includes means for heating calcium to about 400 ° C before the laser is operated, thereby being able to absorb the gases escaping from the laser. Preheating can be carried out electrically or with the help of a pyrotechnic charge. The jacket-tight wall of the metal body contains a pierceable disc surrounded by a gastight connector, with which the container can be connected in a vacuum-tight manner to the discharge of the laser. After the connection is made by perforating the disc, the evasive gas is fed into the holder.

The disadvantage of the known device described above is that the gas absorption capacity is relatively low, and only about 30% of the added calcium mass is consumed.

The object of the invention is to overcome this drawback and to provide a device for absorbing gases eluding from chemical lasers, in which a larger amount of calcium is consumed, while the device with the chemical laser together forms a light and compact system that is easy to install on airplanes can be mounted.

The object of the invention is therefore to provide an apparatus for absorbing gases escaping from hydrochloric acid lasers, ie reactive gases and inert nitrogen gas, consisting of a gas-tight container in which, under vacuum, calcium, a heat-absorbing material and means to store calcium to be heated, the container comprising a valve which can be connected in a vacuum-tight manner to the gas discharge of a laser and controllable means for opening the valve to allow the evasive gases into the container, characterized in that that the container contains at least a piece of a homogeneous porous material, consisting of at least calcium and the said heat-absorbing material.

Furthermore, the present invention aims to provide a method of operating this device, wherein a homogeneous mixture of powdered calcium and heat-absorbing material is compressed under an inert gas in a mold to form the piece to be placed in the container.

According to a special embodiment of the device according to the invention, the heat-absorbing material consists of lithium fluoride or lithium hydride.

According to another embodiment of the present device, the porous homogeneous material consists of lanthanum or cerium

One of the embodiments according to the invention will now be further elucidated with reference to the drawing.

In this drawing, the cylindrical metal container 1, in which the vacuum is applied, is connected on one side via the vacuum-tight valve 3 to the gas discharge of chemical laser 2. Within the longitudinal section shown in holder 1, a number of parts are e.g. the plates 4 mounted on the inner wall of container 1 with carriers not shown. The plates are arranged in holder 1 at an equal distance and parallel to the direction of flow 5 of the gases escaping from laser 2 when valve 3 is opened.

Laser 2, for example, consists of a deuterium fluorine water-DF vacuum cleaner, fed with hydrogen and fluorine diluted with an inert always nitrogen gas. The combustion of fluorine and hydrogen in the combustion chamber of the laser produces free fluorine atoms that enter the laser's optical chamber. These atoms bond with the deuterium molecules injected into the chamber to form excited DF molecules. The gases which escape from the laser consist of nitrogen, deuterium, hydrofluoric acid and deuterium hydrofluoric acid.

Shut-off valve 3 consists, for example, of a pierceable disc forming part of the wall of holder 1 and means for perforating this disc, as soon as the laser is activated. The gases evading from the laser thus penetrate parallel to arrow 5 through the perforated disc in holder 1.

The components arranged in container 1 need not have the plate shape shown, but may also, for example, be in the form of balls or rods consisting of a homogeneous porous material of calcium and a heat-absorbing material. The pores are open and are preferably more than 75% of the material.

The porous material is prepared in the following manner.

For example, granular calcium is dissolved in liquid anhydrous ammonia and the ammonia is evaporated under vacuum. First calcium-ammonium precipitates CaiNH ^) ^ and then finely divided metallic calcium, with a surface area of 15 m2 per gram.

This powder ignites automatically in the air and must therefore be treated and stored in a glove box under an inert atmosphere, for example arg * on.

The calcium powder thus obtained is mixed with a heat-absorbing material which can consist of lithium fluoride or lithium hydride. The heat absorbing material has a high specific heat and heat of fusion and must be finely powdered in order to be thoroughly mixed with the calcium powder. Preferably, the weight amounts of heat absorbing material and calcium are equal.

Still under an inert atmosphere, the homogeneous powder mixture is compressed in a mold in the desired shape, for example plate, granules or rods. Under a pressure of about 500 kg / cm2, the material obtains a sufficient stiffness at a porosity of more than 75%.

Since calcium does not react with the gas eluding from the laser at ambient temperature; a heating system, for example a pyrotechnic charge or an electric heating system, which is switched on shortly before the laser is activated and supplies a temperature of 350 to 400 °, must be added to the porous parts arranged in Holder 1.

At this temperature, calcium absorbs the gas from the laser and forms with the hydrogen-containing products hydrides and deuterides and nitrides with the nitrogen. The reaction is highly exothermic and the heat absorbing material serves to keep the temperature in the container below 700 ° C. This prevents decomposition of the hydrides and deuterides formed and reduces gas absorption.

With the device according to the invention, provided with porous parts consisting of 1 kg of calcium and 1 kg of lithium fluoride, an HF / DF laser with a gas flow rate of 5.8 g / s can operate for 30 seconds.

Excellent absorption efficiency can be achieved with the device according to the invention. When using lithium fluoride as a heat absorbing material, the absorption reaction consumes 60% of the calcium applied in the container, while consuming 70% with lithium hydride, which is more than about 00% with the known device.

The high calcium consumption in the device according to the invention is presumably based on the fact that the gas eluding from the laser can penetrate into the core of the porous parts placed in the container and that calcium and heat-absorbing medium are intimately mixed in the porous parts. material can penetrate the gas continuously t> t into its core. In the known device, as soon as gas absorption starts, the calcium contracts on the surface by frying, which prevents further access of the gas to the calcium core.

Although it is possible to use a known electric or pyrotechnic preheating system, as indicated above, it is preferable to add a small amount of finely divided lanthanum or cerium powder to the mixture of calcium powder and heat absorbing material before compression in the mold which react with the hydrogen containing products as soon as the ambient temperature and reaction provide sufficient heat to reach the preheating temperature.

In some cases the device must be connected to bottle 6 which contains a small amount of fluorine and which communicates with the interior of container 1 via a pipe and a remote-controlled valve 7. Fluorine is fed into container 1 before the laser is operated. The reaction of fluorine with calcium provides sufficient heat to quickly reach the preheating temperature.

The present invention is applicable to aircraft hydrogen hydrogen lasers.

Claims (10)

An apparatus for absorbing reactive gases escaping from chemical hydrogen-acid lasers and gases containing inert nitrogen gas, the apparatus consisting of a gastight container containing, under vacuum, calcium, a heat-absorbing material and means for heating calcium, provided with a valve which is connected in a vacuum-tight manner to the gas discharge of a laser, and remote-controlled means for opening the valve to allow the evasive gases into the container, characterized in that the container is at least one piece of a homogeneous porous material, consisting of at least said calcium and heat absorbing agent. Device according to claim 1, characterized in that the heat-absorbing material consists of lithium fluoride or lithium hydride. Device according to claim 1, characterized in that the pores of this piece are open and the porosity is more than 75%. Device according to claim 2, characterized in that the weight amounts of heat-absorbing material and calcium in the homogeneous material are approximately equal. Device as claimed in claim 2, characterized in that the container contains a number of these pieces in the form of plates, which are arranged equidistantly parallel to the direction of flow of the gas flowing in the container. Device according to claim 2, characterized in that the homogeneous porous material additionally contains lanthanum. Device according to claim 2, characterized in that the homogeneous porous material additionally contains cerium. 8. Device as claimed in one or more of the claims 1, 6 and 7, characterized in that in addition remote control means are available for supplying fluorine in the container. Method for the device according to claim 1, characterized in that a homogeneous powder mixture consisting of calcium and heat-absorbing material is compressed under an inert atmosphere in a mold to form said pieces, which are placed in the container. Method according to claim 9, characterized in that the homogeneous powdery mixture additionally contains powdered lanthanum or cerium.