DE19649738A1 - High capacity pressure wave source for producing short bursts of high- energy pressure waves - Google Patents

Abstract

Flat pressure waves are produced by a membrane by a pressure wave generator (2). A second membrane (4) is set spaced parallel to the membrane (3) of the generator and the space between the two membranes forms a closable combustion chamber (6). An inlet valve (7) forms a supply device for a fluid mixture which can be ignited by a shock like a detonator whilst an outlet valve (8) discharges the ensuing exhaust gas. The second membrane forms the acoustic transfer element for the detonation front/pressure wave to a transfer medium (14) or to a substance (16) which is to be treated. The device can be technically adapted for operation with a gas mixture comprising for the most part hydrogen and oxygen.

Description

The invention relates to a high-performance pressure wave source for generation single high-energy pressure that can be repeated at short intervals waves, with a flat pressure wave generated by a membrane Pressure wave generator, according to the preamble of claim 1.

Relatively low power pressure and shock wave sources, i. H. with a radiated acoustic energy in the range of about 10 to 100 mJ are ins especially known from medical technology, where it is often used as a lithotripter be set. Current versions usually work according to the elektroma gnetic principle, using a coil / membrane unit level pressure waves are generated. Through a certain barrel length in an acoustic Transmission medium, e.g. B. water and by focusing by means of acousti Sheer lenses create steep-edged, "hard" shock waves, which on a de defined point (focus / focus).

There is a Be for non-medical, especially industrial applications may after a much higher pressure wave energy, which is about 50 to Should be 100 times larger than the values usual in medical technology. A simple enlargement / scaling of the known electromagnetic shock Wave sources do not make sense because their poor efficiency is too extreme large and correspondingly expensive electrical components would ren. Such components are e.g. B. the capacitor, the capacitor charger, switch etc.

From DE-OS 39 21 808 is a device for focused shock waves known tumors for which different options for Pressure or shock wave generation are called, for. B. by means of spark  ductor or piezo effect. Claim 10 of this document mentions further possibilities the generation of pressure surges using an explosive gas mixture nice. However, there are no indications as to how this principle can be achieved is to be implemented structurally.

Explosives are known to have a very high energy density and very high efficiency in terms of pressure wave generation. They are therefore also used commercially, e.g. B. in mining and tunneling. The wedge and notch effect of explosion pressure waves is, for example used to cut solid solids. Let it this way felling trees, cutting metal girders etc. The exploits used Sion sources (detonating cords, bar loads, etc.) usually generate divergent pressure waves with spherical or cylindrical propagation, which rapidly increases in energy density as the distance from the source increases te lose.

Hollow and cut are originally from the military sector charges known, which with generated according to the concave principle, con emitted pressure waves work, and with which punctiform or linear have extremely high pressures (millions of bar) generated. The explosives are additionally coated with heavy metals, which - after explosion - as parties increase the drilling or cutting performance.

The explosive pressure wave sources mentioned are all only for one time use Use provided and not suitable for using defined plane shock waves to generate predetermined energy or energy density. Of course it is known to generate pressure waves by igniting explosive fluid mixtures, which is used, for example, in reciprocating piston engines. From The advantage here is that this process can be repeated as often as required very short intervals. But here, too, they usually generate local tightness limited, d. H. "point" ignition sources (spark plugs) i. w. spherical Pressure waves with rapidly decreasing energy density.  

Another advantage of explosive fluid mixtures is that the generated one Power or energy over the composition and the amount of the fluid mixture is changeable.

Given these known solutions with their specific disadvantages The object of the invention is to provide a high-performance pressure wave source to create, which is able to raise individual highs in short time intervals ergetische, at least approximately flat pressure waves with defined, in certain limits of targeted variable energy and with good focusability testify, and which are characterized by a robust, relatively simple construction, ge light weight, easy handling and low purchase and Maintenance costs.

This object is characterized by the features in claim 1 solved, in connection with the generic features in its upper term.

The invention uses a known, low-energy pressure wave genes rator, which flat pressure waves by means of a shock with small amplitude de movable membrane generated to be in a closable combustion chamber, one wall of which forms the membrane, a detonation-like chemically reacting fluid mixture over the entire ver ignite the combustion chamber surface (across the longitudinal axis of the membrane) simultaneously and so create a flat detonation front in the combustion chamber. The detonation front accelerates a second membrane, which is that of the first Membrane opposite wall of the combustion chamber forms and thus to the outside a high-energy, at least approximately flat pressure wave sends out. This pressure wave can be direct or indirect via an acoustic Transfer medium are transferred into the substance to be processed. The second membrane will, depending on the ratio of the current Geometrically deform the internal combustion chamber pressure to the external pressure and so at least temporarily deviate from a flat shape. The  pressure waves generated by it nevertheless have a largely "flat" Character "on, with decreasing over the barrel length, only due to loss Energy density. By means of acoustic lenses, the energy density can reach up to Focus can also be increased if necessary.

The combustion chamber is periodically filled with a fresh fluid mixture and emptied of the exhaust gas, whereby defined purging cycles may be required.

Fluids are understood to mean liquids and gases, a mixture comprises two or more components. By adding inert components th or by deviation from the stoichiometric ratio, the che mixing reaction is slowed down and weakened, d. H. the temporal The course of the chemical reaction can be changed in a targeted manner. Leave changes of course by using a different type of fuel or Achieve oxidizer, e.g. B. of kerosene instead of hydrogen.

The sub-claims 2 to 9 characterize preferred configurations of the High-performance pressure wave source according to the main claim.

The invention will be explained in more detail with reference to the drawing. This shows a schematic representation of a longitudinal section through a print wave source, with a version with focus to the left of the center line, a version without focus is shown on the right.

The high-performance pressure wave source 1 , hereinafter simply referred to as the pressure wave source, consists in the simplest case of two functional units, namely the pressure wave generator 2 with membrane 3 and the combustion chamber 6 with membrane 4 and with other components, the units being combined in a housing 11 are. The Druckwellengene rator 2 preferably works on the electromagnetic principle, ie with electromagnetically generated eddy currents in the membrane 3 and repulsive force between the coil and membrane. However, it can also function, for example, according to the reverse piezoelectric principle, with a change in length of crystal elements being caused by current. It is important that a very fast, jerky, simultaneous movement of the entire membrane 3 is achieved if possible, the amplitude across the membrane surface should also be largely the same.

At this point it should be mentioned that the pressure wave source 1 is designed as rotationally symmetrical as possible for physical and structural reasons, which is also assumed in the following explanations. The combustion chamber 6 , which represents a hollow space, is delimited at the end by the two membranes 3 and 4 and at the circumference by the housing 11 . It has at least one inlet valve 7 for the supply of fresh, detonable fluid mixture and at least one outlet valve 8 for the discharge of the exhaust gas or the exhaust gas components. At the moment of ignition / detonation, the combustion chamber 6 will normally be hermetically sealed. But it is also conceivable to leave the outlet valve 8 or additional blow-off openings more or less open during the detonation. The emanating from the membrane 3 , flat, ie flat, pressure wave ignites the combustion chamber content in a certain plane simultaneously, ie across the entire cross-section transversely to the longitudinal axis, an - at least largely - flat detonation front being generated. It is currently not foreseeable whether the ignition will start from the membrane 3 , the membrane 4 or from the combustion chamber interior. Trials are certainly required to clarify this question. The catalytic coating shown on the membrane 3 (cross) and the catalytic element 10 inside, for. B. in the form of a braid, are in this aspect hen only as conceivable variants to see, the catalytic effect as such with certain probability speed is advantageous.

When the detonation front strikes the membrane 4 , it is moved in a jerky manner and emits a high-energy, at least approximately flat, pressure wave to adjacent, acoustically conductive media or substances. With a view to simple attachment or structural extensions, the housing 11 is provided in the area of the membrane 4 with a flange 12 .

The variant to the left of the center line provides for focusing the initially plane waves by means of a lens 13 . The acoustic edge beam before and after refraction is shown in dash-dotted lines with arrows, labeled 18 and ends in focus F.

The pressure wave source 1 is here provided with a truncated cone-shaped housing top 15 and a further membrane 5 and sealed, with a defined volume of liquid transmission medium, for. B. water to be closed.

The substance to be processed is not shown here and would be brought into direct or indirect contact with the membrane 5 .

The variant on the right of the center line works without focusing, that is to say with a straight pressure wave propagation, as symbolized by the marginal jet 19 .

The pressure wave source 1 can be detached here from a container 17 , e.g. B. flanged a tank or a pipe section with a corresponding opening, the membrane 4 being in direct contact with the substance 16 to be processed. The substance 16 can be, for example, a liquid / solid mixture which is influenced in a targeted manner by the acoustic pressure waves.

With regard to the possible applications of the invention, it can be said that the actual scope of which is not yet foreseeable. Probably can most substances are treated from solid to gaseous. In particular is special on liquids with solids admixture, on dust, powder and Thinking granules.  

Conceivable effects are e.g. B. homogenizing, crushing, removing Cavities or other "defects", dissolving of deposits, Ver crusts etc. and thus cleaning surfaces and much more.

Claims (9)

1. High-performance pressure wave source for the generation of individual high-pressure waves that can be repeated at short intervals, with a flat pressure waves by means of a membrane-producing pressure wave generator, preferably according to the electromagnetic principle with a coil / membrane unit, characterized by a distance parallel to the membrane ( 3 ) the pressure wave generator ( 2 ) arranged, second membrane ( 4 ) and an embodiment of the space between the two membranes ( 3 , 4 ) as a closable combustion chamber ( 6 ), with at least one feed device (inlet valve 7 ) for a detonation-like combustion, fluid mixture ignitable by impact and with at least one discharge device (outlet valve 8 ) for the resulting exhaust gas, the second membrane ( 4 ) transmitting the acoustic transmission element for the detonation front / pressure wave to a transmission medium ( 14 ) or to a substance to be processed ( 16 ) out there. 2. High-performance pressure wave source according to claim 1, characterized through a technical design for operation with at least a large part gas mixture consisting of hydrogen and oxygen. 3. High-performance pressure wave source according to claim 1 or 2, characterized by a liquid, as a defined, encapsulated volume in the pressure wave source ( 1 ) integrated and there to the second membrane ( 4 ) to adjacent transmission medium ( 14 ). 4. High-performance pressure wave source according to claim 3, characterized by water as the acoustic transmission medium ( 14 ). 5. High-performance pressure wave source according to one or more of claims 1 to 4, characterized by a catalytic coating ( 9 ) egg ner membrane ( 3 ) or both membranes ( 3 , 4 ) on the combustion chamber side and / or at least one catalytic element ( 10 ) inside the combustion chamber ( 6 ). 6. High performance pressure wave source according to one or more of the types sayings 1 to 5, characterized by a radiated acoustic energy of about 1 to 10 J (joules), a pulse duration of about 1 to 100 µs (microscope customers) and a repetition rate of at least about 1 Hz (Hertz). 7. High-performance pressure wave source according to one or more of claims 1 to 6, characterized by a structural design of the "Ver wear components", for. B. the membranes ( 3 , 4 , 5 ) to about 1 million pulses (pressure waves). 8. High-performance pressure wave source according to one or more of claims 1 to 7, characterized by one of the second membrane ( 4 ) downstream focusing device in the form of at least one acoustic lens ( 13 ). 9. High-performance pressure wave source according to one or more of claims 1 to 7, characterized by a structural design which has a releasable fastening (flange 12 ) directly to the substance to be processed or to a container ( 17 ) receiving the substance ( 16 ), e.g. B. a tank or pipe section.