DE1433147C - Device for generating mechanical shear, technical work performing vibrations by means of a medium flowing through Strahlver and Energiespeicherungseinnchtun conditions - Google Patents

Description

The invention relates to a device for generating mechanical, technical work Vibrations by means of a flowing through beam amplifiers and energy storage devices Medium.

Systems with flowing media are used in military and industrial equipment widely used. Machine tools, steam engines, Internal combustion engines, rocket motors, and numerous other devices hang on the precise and timely control of the movement of such media, if a proper one Effectiveness should be ensured.

These systems are generally moving parts such as pistons, valves, or diaphragms Propeller blades used. In some areas of application, however, moving parts are disadvantageous or require a restriction of the operating range, which for example on the friction, wear, thermal expansion, weight or moment of inertia of the parts concerned is. It is therefore often desirable to eliminate moving parts from fluid systems.

The invention is based on the object of a device for generating mechanical, technical Vibrations performing work by means of beam amplifiers and energy storage devices to create a flowing medium, in which the use of movable, mechanical Parts are superfluous, but which has a large frequency range and can be produced with simple means, practical works maintenance-free, has an unlimited service life and vibrations of sine, triangle, Can produce rectangular or sawtooth shape.

This is achieved by the fact that collecting openings of the main beam of a beam amplifier Feedback paths to one or more feedback nozzles located to the side of the main jet nozzle lead and that the feedback paths are energy storage or contain such.

The vibrations generated by the device according to the invention can be used in a variety of ways * used and used. In principle, they can be used wherever there are vibrations certain waveform are required.

The invention can be used both in the processing of ores, with the vibrations generated by it be transferred to a suspension in the form of liquid impulses, as well as for storage of information that is converted into medium vibrations of certain waveforms for Calculating machines are used. The invention is also used to drive vibrating screens in screening systems Device excellently suited.

Another area of application is control and regulation technology.

For all these applications, the device of the invention is particularly suitable because it contains no fixed, moving parts. As a result, it is not subject to wear and tear, to the influences the inertia, the tolerances in the manufacture of such parts and the resulting errors. From it This in turn results in a practically unlimited service life without any maintenance.

The device according to the invention is ultimately simple in its design, because practically only one certain pattern of flow channels with accumulators and resistors in a plate. Corresponding Thickness needs to be milled, which is covered on both sides by plates, and it can be in any size can be made.

In the case of the beam amplifiers used according to the invention, a main beam of high energy is under Use of a low energy control beam on a multi-aperture capture system directed, resulting in an amplifier. Addition is obtained by using multiple control beams that deflect the main beam in the same direction, a subtraction the use of several control beams that deflect the main beam in the opposite direction, and a multiplication is obtained by regulating the beam strength of the main and control beams. Control jets of the same total pressure level can obtain different effects in that the nozzles of the control jets receive a corresponding cross-section. Algebraic equations can also be solved with beam amplifiers of this type, namely in that a number of Control nozzles are arranged in a suitable manner to one another, with each control jet as required a separate individual variable is changed.

The oscillation frequency that can be achieved according to the invention is higher, the wider the frequency response range the amplifier used is. For example, in previous pneumatic systems the upper still achievable frequency at about 60 Hz, while with the present invention without it It is also possible to cope with frequencies of at least 1000 Hz up to the ultrasonic range.

In the present invention, the beam energy is stored in two forms, namely as potential energy and as kinetic energy.

The potential energy is stored with the help of energy storage devices. in the in general, the energy stored in such a device increases when additional medium is used is introduced. The energy can be stored by compressing a gaseous medium to greater density; Change of the thermodynamic state of the medium; Change of Height of the medium; Compression of a second medium that is separated from the first medium by a flexible wall is separated; Compression of a second medium that is related to the first medium is in contact; Deformation of elastic walls surrounding the medium; modification the altitude of a weight carried by the medium; Compression of vesicles or droplets one medium distributed in a second medium.

A moving medium has kinetic energy, which is a second form of energy to be stored Can represent energy. In order to be able to store the energy as kinetic energy, the medium is accelerated to a higher speed. The inertia is a measure of the pressure that is necessary to accelerate a certain mass of the medium in a flow path. she therefore stands with the flow of the medium z. B. related by a pipe.

The term "medium" is intended to include both compressible and incompressible media, as well as mixtures and combinations of these media. If compressible media are used,

The necessary storage devices do not need to be elastic or expandable, but rather can be made of rigid metal or plastic or other rigid material. If the medium is incompressible, the energy storage devices must be elastically deformable or have a free surface (such as water in an open container). A pressure loaded flexible diaphragm can be provided in an energy storage device. be "if it doesn't is possible to use a resiliently deformable tank or container. A loaded piston is one type of elastically deformable tank.

In the following description, these energy storage devices are referred to as storage.

The term "input signal" is intended to denote the flow signal that the Vibration generator is supplied as a command signal in order to obtain the desired output signal. The term “output signal” should be understood to mean the flow signal that is produced at the vibration generator output appears. The input signals and output signals can have the shape more spatial or changes over time have the following properties of the medium: pressure, density, Flow velocity, mass flow, flow composition, transport properties or others thermodynamic properties, individually or in combination with one another.

The invention is explained in detail below in exemplary embodiments with reference to the drawings. In the drawings represents

Fig. 1 shows a symmetrical oscillation and

F i g. 2 an asymmetrical oscillation that can be generated,

F i g. 3 shows an embodiment of a vibration generator in plan view,

3a shows the side view of the vibration generator according to Fig. 3,

F i g. 4 a second embodiment of a vibration generator in plan view,

F i g. 4 a shows the side view of the embodiment according to FIG. 4,

5 shows a third embodiment of a vibration generator in plan view,

F i g. 5 a shows the side view of the vibration generator according to FIG. 5,

F i g. 6 shows a fourth embodiment of a vibration generator in plan view,

6a shows the side view of the vibration generator according to FIG. 6,

F i g. 7 shows a fifth embodiment of a vibration generator in plan view,

F i g. 7 a the side view of the embodiment according to FIG. 7,

F i g. 8 shows a cross section along the line 8-8 in FIG. 7,

• F i g. 9 is a cross-section along line 9-9 in FIG Fig-8,

10 shows a sixth embodiment of a vibration generator in plan view,

Fig. 11 is a cross-section along the line 11-11 in Fig. 10,

Fig. 12 shows an ultra-low frequency vibrator in plan view,

FIG. 12a the vibration generator according to FIG. 12 in side view,

Figure 13 shows graphically the output of the vibrator according to Fig. 12 and 12a,

FIG. 14 graphically shows an output signal produced by the vibrator of FIG. 12 in conjunction is generated with the memory according to Fig. 15, 15 shows the connection of the output of the vibration generator to a multistable storage system,

16 schematically shows the connection of a vibration generator to another device, e.g. B. a

ίο sorting belt.

According to FIG. 3, to which reference is first made, the vibration generator 10 consists of a Beam amplifiers, energy storage devices and devices for feedback of a part of the medium from the amplifier in a suitable phase to the main beam flowing through the amplifier distract in the necessary manner.

The vibration generator 10 is formed by three flat plates 11, 12 and 13 (Fig. 3a). The plate 12 can be embedded tightly and firmly between the plates 11 and 13 by machine screws 14.

It is assumed that the plates 11, 12 and 13 are made of a clear plastic material.

The elements arranged within the dashed lines form the amplifier Λ. These elements are the chamber 15, the main jet nozzle 16 with nozzle opening 16a, two opposing nozzles 17 and 18 with nozzle openings 17a and 18a, the leading edge of the jet splitter 21 and the outlet openings 19 and 20.

The amplifier can work according to the interface effect. In this case, the front edges 15 a 'and 15 b' of the opposite walls 15 a and 156 of the chamber 15 on each side of the edges 16 a 'and 166' of the nozzle opening 16 a are set back by a certain amount. By formed as soon as a jet from the nozzle 16 exits, 15e on the walls and 15 b from a flow, in which the medium flows with significantly lower speed than the medium in the main beam. This area along the wall 15 a and the wall 15 b forms an artificial interface area. In this area there is reduced pressure, whereby the main jet from the nozzle 16 is caused to apply either to the wall 15 a or the wall 15 b and to adhere there. If a jet of a further medium from any suitable source, for example the control nozzles 17 and 18, is introduced into this area between the main jet and the nearest chamber wall, there is a pressure increase in the interface area, whereby the aforementioned adhesion is canceled. The jet emerging from a control nozzle therefore deflects the main jet against that chamber wall which is opposite the wall to which the jet initially adhered. In this way, a controlled switching of the main jet from one outlet opening 19 to the other outlet opening 20 is possible.

On the other hand, the amplifier Λ can also after work the jet interaction effect. With this type of amplifier, the gain results from the Interaction between a control beam of relatively low energy and a main beam of considerable high energy. The control beam deflects the main beam so that the energy is either total or partially discharged into a particular outlet port or combination of outlet ports

5 6

can be. In this case, the side walls 15a and 15b are "unequal to one another, so that the fertilizer of the chamber 15 is arranged far away from the main jet deflected by the jet exiting the nozzle 16, so that the jet which delivers the greatest proportion of medium If the pressure distribution in the area of the side wall supplies the control nozzle 17 more medium than the control nozzle fertilizes for the operation of this amplifier 5 18, the opening 20 takes up practically the entire main jet, since in this case the jet at the 3 wall 156 is adhered to. The tanks 22 ', 23' and 24 'use a storage tank which consists of three tanks on each side, which are therefore filled with medium, and a pressure side of the chamber 15. rise occurs in these tanks until finally the medium can be used in the interface area instead of the tanks anks with the reference numeral 22, between the main beam and the chamber wall 22 ', 23, 23', 24 and 24 'loading 15 supplies b. During this interval the current flows. Two tanks at a time, forming a pair, should flow from the outlet opening 122. Due to the nozzle having practically the same volume, if a 18 is the main jet but symmetrical output signal against the wall is desired. Each 15 15a steered, and the entire beam enters the öff tank serves as a memory, that is, it stores the voltage 19, so that the output from the Auslüß-Mcdium in an almost static state, so that opening 121 is enlarged . After a certain the stored potential energy of the medium at time interval, the length of which increases from the values of the supply of additional medium. The tanks memory, the resistors and the volume of the are '26 and 26' depends another comparable medium 20 supplied by the amplifier A via pipes 25, 25, is blind. These tubes together with tubes form the beam in turn back against the wall 156 -27, 27 ', 29 and 29' a feedback path for directed. Due to the constantly changing deflection, part of the medium of the main beam leaving the amplifier A from a comb wall becomes medium which leads to the control nozzles 17 and 18. the medium vibrations at the two outlet beam pieces 28 and 28 'conduct a predetermined 25 lines 121 and 122 generate. The amplifier A portion of the entering into the openings 19 and 20 can, however, also according to the interaction effect of the medium into the tubes 29 or 29 '. The rest of the work in to get the same effect. When the medium enters the openings 19 and 20 and the jet enters the opening 19, it reaches the outlet pipes 121 and 122 and the plug 31 forms the speed of the pressure at the output signal of the vibration generator. 3 ° rose in the memory 22 and thereby calls a

The nozzle 16 protrudes with the tank or some time delay (phase shift). the connected to another source, from which the medium combination of storage 23 and 23 'and again below Pressure is supplied to the nozzle 16, stands 31 and 31a or 31 'and 31a' controls the

Flow resistances 31 and 31 ', in the following the speed of the pressure increase in the accumulator

called "resistances" for short, z. B. in the form of porous 35 23 and generates a further phase shift.

Plugs, lie in the tubes 29 and 29 '. The values Another phase shift for the pressure

These resistors can be based on the values of the construction in the memory 24 (or 24 ') is determined by the

Memory 22. 23, 24 and 17 or 22 ', 23' 24 'and 18 Combination of the memory 24 (or 24') with the

be coordinated so that the correct phase for upright porous plug 31 b (or 31 b ') is generated. The Vo-

Preservation of the vibration for the amplifier ^ 4 ° lumen of the nozzle chamber 17 in connection with the

fed back medium is ensured. porous plug 31c finally creates another

The beam splitter 21 can be asymmetrical to the opening phase shift for the pressure build-up in the

16a be arranged so that to trigger the nozzle 17. The same applies to the nozzle 18, if

Vibration is a greater proportion of that in the chamber the jet has entered into the outlet opening 20.

15 entering the main beam through the beam splitter 45 These phase shifts control the oscillation

21 is introduced into one of the openings 19 or 20. frequency. .. .. .- '■■■

If the principal ray is asymmetrical, divide the F i g. 4 shows another embodiment of a part 28 and 28 'a correspondingly enlarged vibration generator 101, in which eight in geAnteil the beam and guide it through the pipes suitably interconnected pipes 33, 29 and 29' in the associated feedback path. 5 ° 33 '. 34, 34 ', 35, 35', 36 and 36 'form the energy storage device when more liquid is in the tubes 29 or 29'. It differs from that according to FIG. 3 flows, a pressure increase occurs in the accumulators 22, 23 due to the accumulator being inert to flow and 24 or 22 ', 23' and 24 '. until finally that is and that the feedback nozzles emerge from the outlet medium from the associated control or return openings of the feedback lines 36 or coupling nozzle 17 or 18, respectively. Since in the asymme- 55 36 'are formed. This means that the medium exiting from the tric state of the main jet in amplifier A and entering through the reservoir, which stores one of the openings 19 or 20 as the medium flowing into the other pipe, stores kinetic energy, also supplies one of the control nozzles 17 or the only one a greater amount of medium than the other via the feedback lines 36 and 36 '18. is fed back to the amplifier A. In pairs, this results in a deflection of the main 60 are porous plugs 37, 37 ', 38, 38'. 39 and 39 'at the beam against or in the opposite outlet the connection points of the pipes 33, 33', 34, 34 ', 35 opening 20 or 19. If the amplifier A is provided with the and 35'. These stoppers act as an opposing boundary surface, the deflection occurs between the local total pressure in the return main jet when the medium is out of the control coupling path and the ambient pressure. They cause nozzles to emerge and, consequently, the pressure in the boundary divides the total feedback pressure area between the main jet and the main jet into two parts, one of which the pressure drop in the next chamber wall increases. The pressures of the tube 33 and the other above the plug 37 are in the interface area along the walls. This is necessary in order to create a pressure in the

bond between the tube 33 and the plug 37 to generate. This pressure is out of phase in related to the outlet pressure. The resulting advantage is a phase shift in the feedback path. When the jet from the nozzle 16 enters the nozzle 19, the inertia creates the Medium in the pipe 33 together with the resistor 37 a phase shift. The same applies accordingly for the inertance 34 with resistance 38 and the inertance 35 with resistance 39 and inertance 36. The phase shift created in this way controls the point in time at which feedback energy at the outlet the inertance 36 is released into the chamber 15, the main jet against the opening 20 distract. .

If a jet emerges from the nozzle 16, the vibration generator 101 begins to close at the frequency vibrate, which mainly depends on the phase shift of the feedback path, as this the point in time for the delivery of control energy stored in the feedback path is determined. Any normal flow of the main jet at the start of operation will result in more liquid entering the one or the other of the openings 19 or 20 is discharged so that the oscillation begins thereby can. ·.

The main jet is deflected by the control nozzle that delivers the greatest control signal at the moment / This deflection remains until a larger control jet emerges from the opposite feedback line. At this moment the main jet swings over to the other outlet opening. Both types of the beam amplifier described above are suitable as amplifier A in this vibration generator.

F i g. 5 and 5 a show a further embodiment of an oscillation generator 102, in which the output oscillations from the amplifier ^ are fed to a further amplifier A ' and are amplified there again. The amplifier A ' receives the medium from the amplifier A via two containers 42 and 42' which have nozzles 43 and 43 'which communicate with the chamber 15. The other ends of the containers 42 and 42 'are also narrowed at 44 and 44'. The reservoirs formed by the tanks 45 and 46 are connected to one another via the inertance pipe 47. The same applies to the combination 45 'and 46' and the inertance tube 47 '. The tanks 46 and 46 'are provided with nozzles 49 and 49' which open into the chamber 15. An inertance pipe 52 connects the tanks 46 and 46 'to one another. Tubes 50 and 51 (Fig. 5a) provide an input signal to amplifiers A and A ', respectively, from any suitable source of pressurized medium. A separate source in each case can serve to supply both tubes 50 and 51, but a common source can also be present.

As soon as a jet emerges from the nozzle 16 the flow pattern is somewhat asymmetrical. Accordingly Initially, a little more medium flows immediately into one of the openings 19 or 20 than into the one other of these openings and accordingly in the container 42 or 42 '. The. Opening 16 η the Hauptstrahldüsc 16 can be arranged symmetrically to the center line of the chamber 15, so that the The main beam is initially divided practically evenly by the beam splitter 21 and for so long in this State remains until an accidental flow deflects it in the direction of one or the other the outlet openings. On the other hand, the opening 16 a can also be asymmetrical to the center line the chamber 15 be arranged, whereby a bias results that a from the outset greater uptake of medium at one of the two outlet openings 20 or 19 causes.

The container 42, 42 'and the tanks 45, 45', 46 and 46 'form storage devices which periodically store or release potential energy in the manner described above. The inertance tubes 53, 53 ', 47, 47' and 52 _N periodically store kinetic energy or emit kinetic energy. The flow entering one of the openings 19 or 20 is absorbed by the associated container 42 or 42 '. From this container, the medium reaches the nozzle 43 or 43 'after a phase shift which is determined by the line required for the pressure build-up in the container in question. The flow emerging from the nozzles 43 or 43 'deflects the jet emerging from the half-jet nozzle 16' either into the opening 20 'or into the opening 19'; : *. ~

If for a certain period of time the container 42 holds more medium than the container 42 '(as a result of asymmetrical distribution of the main jet emerging from the nozzle 16), therefore delivers the nozzle 43 a larger amount of medium into the chamber 15 'and thus directs the main jet out of the nozzle 16 'into the outlet opening 20'. This means that the beam leaving the amplifier ^ to the Partly enters the inertia 53 'and partly into the output line 121. At the beginning of this process the kinematic energy of the jet emerging from the nozzle 43 is not large enough to cause the To deflect the main jet from the nozzle 16 'completely over the Tnertanz 53' into the tank 45 ', so that a A certain proportion of the medium also enters the inertance 53 and the output line 121. As soon as however, as the pressure within the tank 45 'builds up, the velocity of the flow becomes over the inertia 47 'in the tank 46' is enlarged. The inertia of the one who is in the inertia 47 ' However, the medium delays this increase in flow and creates a phase shift. As soon as the maximum flow rate is reached, the flow rate depends on the inertia 47 'only depends on the pressure difference between the tanks 45' and 46 'and that of the flow through the Inertance 47 'from associated resistances. As soon as the pressure difference between the tanks 45 'and 46 'decreases, the inertia of the medium in the inertia 47' acts as an energy source with the tendency that Maintain flow rate from tank 45 'to tank 46'. Affected in this way the inertance 47 'the phase designation between the flow from the inertance 53' to the tank 45 'and from inertia 47 'to tank 46'. As soon as pressure has built up in the tank 46 ', medium flows via the nozzle 49 'into the chamber 15. If the nozzle 49' emits more medium than the nozzle 49, the Main jet deflected from nozzle 16 towards opening 19. .

Furthermore, if the pressure in the tank 46 'is higher than that in the tank 46, an acceleration of the medium in the inertia 52 in FIG Towards the tank 46. The inertia of the medium

the formation which is formed is delayed by the inertia 52. Another pipe 67 communicates This flow between tank 46 'and tank 46. The same with the tank 60. On this pipe 67 is Medium in the inertia 52 flows so long with a pipe 68 slidably mounted so that the length of the

gender speed from tank 46 'to tank 46, pipe is adjustable. The tubes 67 and 68 are long the pressure difference between these tanks 5 bind the memory 60 to the ambient pressure, is still large enough to reduce the flow resistance which is lower than that during operation in the

to overcome inertia 52. This means that pipe 65 has the maximum total available

the maximum flow velocity in the intracranial pressure.

dance 52 occurs after the maximum pressure difference. Further inertances 70, 71 and 72 connect the

rence between the tanks 46 'and 46 built up with each other in series storage. The tank 63 is with

that is. It is therefore possible to supply energy from the tank 46 'to a nozzle 64 which extends over the wall

to the tank 46 and vice versa. This 15 ή opens into chamber 15 of the amplifier / i. the

Transmission is accomplished by means of the kine nozzle opening 16 α is asymmetrical compared to the

table energy of the oscillate through the inertia- center line of the chamber 15, so that other Way of flowing medium. As already mentioned, a considerable proportion of the medium of

As mentioned above, the nozzle 16 entering the opening 19 is supplied from the opening 20. the

Tending medium over the constriction 44 the tank 42 beam splitter 283 'can be arranged so that it

and the control nozzle 43, so that the main jet from a part of the meter entering the opening 20

the nozzle 16 'is deflected towards the opening 20', which absorbs the medium and discharges it into the pipe 65. Here-

whereby medium enters the inertia 53 '. It is 20 pressure is built up in the tank 60. With increasing

a phase shift between the pressure in this tank is provided by the pipes 70,

Time of energy delivery at the nozzle 49 'and 71 and 72 in the following manner medium "to the

Tanks 61, 62 and 63. #,

started energy supply to the tank 46 'via the If the pressure in the tank 60 is greater than that in the

Feedback path. 35 tank 61 ', the pressure difference accelerates the meter

The cross section of the inertance 52 is larger than the medium in the inertance 70 in the direction of the tank

Cross section of the .Düsen 49 and 49 ', so that the flow 61 until the flow resistance of the pipe 70 a

resistance of the inertance 52 generates sufficiently low back pressure, which is equal to the difference of the

and such flow from tank 46 to tank is pressures in the tanks. The mentioned acceleration

46 'can cause that even a small influx 30 of the medium in the inertia 70 results in a

of medium from the inertia 47 into the tank 46 against the delay in the build-up of pressure in the tank 61

Can make control current from the nozzle 49 greater than the pressure change in the tank 60. If the

the pre-existing control flow from the nozzle pressure difference between the tanks 60 and 61

49 '. Due to this change in the energy output which is small to the flow rate of the

Both control nozzles will maintain the main jet from the 35 medium in the 70 inertia

Nozzle 16 deflected towards opening 20; it feeds through the inertia of the medium in inertia 70

via the constriction 44 'and the container 42' which consumes some of its kinetic energy,

Steering nozzle 43 '. The corresponding deflection of the resulting in a higher flow velocity

Main jet from the nozzle 16 'against the nozzle 19' results as it is due to the pressure difference and the

causes the flow to enter the outlet 40 resistance via the inertance 70 would be conditional. on

line 121. Part of the exiting jet is used in this way to feed the outflow from tank 60

absorbed by the inertia 53. The decline is lower and then greater than the steady one

coupling path 45, 47, 46, 49 and 52 serves as the flow velocity because of the resistance

Energy storage and control means for i _m regulatory tube 70. In corresponding manner, the suspended

ren the phase or duration of the flow of the 45 flow through the inertances 67 and 68 of the

Control nozzle 49 and the flow through the inertia 52 actual change in the pressure difference between

to the tank 46 'and to the control nozzle 49'. see the tank 60 and the outlet pressure of the raw

The oscillation time depends on the pressure difference 68, i. H. the ambient pressure and the flow

rence and the resulting speed, change in the inertances 71 and 72 from the

with which the medium changes the pressure difference between the tanks 61 to the two feedback nozzles 50

is fed. It is also dependent on the ab and 62 or 62 and 63.

Measurements of the vibration generator and the values The memory and inertances work together th of the memory, resistors and chokes. If with their resistance and opening 64 as the vibration generator is constructed symmetrically, energy storage and feedback path and is generated a symmetrical waveform like that in Fig. 55 testify to a phase shift representing the point in time F i g. 1 waveform shown at the outlet lines of the delivery of control medium at the nozzle opening 121 and 122 generated if the structure determines 64 asymmetric. In this way, the is tric, an asymmetrical wave form can result be procreated. and the outlet 121 is deflected, whereby

F i g. 6 shows an oscillation generator 103 which, in a speaking manner, controls the delivery of medium into the

the opening 20, the outlet 122 and the pipe 65 are referred to as a one-sided vibration generator

that should because the feedback system only reduces to one.

Side of amplifier A acts. When in tank 60 as a result of the supply of

In the vibration generator 103, four medium from the main nozzle 16 of the maximum pressure tanks 60, 61, 62 and 63 serve as storage, and the pipes 65 rise has entered or is reached through 65, 67, 68, 70, 71 and 72 serve as inertances. The inertia of the tank 60 flowing through the pipe 67 communicates with the amplifier A via medium the medium in the tank 60 as long as a pipe 65, one side of which is passed through the divider 283, until the pressure in the tank is below the

Pressure in the tank 61 is. In this way, the tank 60 is not able to deliver further medium to the tank 61. Furthermore, the supply of medium from tank 61 to tank 62 and from tank 62 to tank 63 is stopped. The tank 63 in turn empties and is therefore no longer able to continue to emit a control jet. The main jet from nozzle 16 returns to outlet port 20 and pressure build-up in tank 60 begins again. After a certain time - depending on the values of the storage and the inertances - the tank 63 therefore again delivers a deflecting beam which deflects the main beam from the opening 20 to the opening 19 and thus from the outlet pipe 122 to the outlet pipe 121. Α by selecting the appropriate position of the Düsenöffung 16, it is possible to obtain a to-symmetrical waveform '(Fig. 1) as the output of the vibration generator 103rd The nozzle opening 16a can, however, also be designed in such a way that an asymmetrical wave shape results. ·

The nozzle 16 is supplied with pressurized medium via a pipe 50 (FIG. 6 a).
) The tube 68 can be displaced in relation to the tube 67 and thereby the effective length of the fluid and its inertia can be increased or decreased. By changing the length of the tubes 67, 68, the exact oscillation frequency of the oscillation generator can be set. The pipe 68 connects mass, ie for example atmospheric pressure, with the connection point of a series circuit of two inertial structures.

The vibration generator 104 according to FIG. 7, 8 and 9 is formed by two sets of plates 11, 12 and 13 (Fig. 8) and 11 ', 12' and 13 '(Fig. 9). The plate sets form a right angle and are held in this position by suitable means.

In Fig. 7 and 8, the medium is fed to the arched reservoir 81 via a pipe 82 which is connected to the opening 20 . The other end of the memory 81 opens into a control nozzle 17 which opens into the chamber 15 of the amplifier A. Furthermore, a pipe 83 with a slidably attached pipe 84 opens into the accumulator 81. The accumulator is connected to the ambient pressure via this pipe, which is generally lower than the maximum total pressure available at the pipe 82 during operation. The tube 83 with the tube 84 form a device for creating a variable flow inertance. They are detailed in FIG. 9 and match in construction with tube 67 and tube 68 in FIG. 6 match.

The nozzle 16 is arranged to the center line of the chamber 15 so that a portion of the jet from the nozzle 16 enters the opening 20 and thus into the tube 82 and the outlet tube 122 . As soon as the medium enters the reservoir 81 through the pipe 82, a pressure increase occurs in the reservoir. As the pressure increases, the control nozzle 17 delivers a deflecting jet. This deflecting jet directs the main jet of the nozzle 16 into the opening 20, so that practically all of the medium passes into the pipe 82 or into the outlet pipe 122. When the pressure in the reservoir 81 rises, the medium flows in the inertance tube 83, 84 with increasing speed. After a certain time interval, the flow in the inertia 83, 84 has reached such a value that the pressure in the memory 81 goes through its maximum, so that the medium flows out of the memory through the pipe 83, and with such a speed that the The pressure in the reservoir 81 is no longer sufficient to generate a deflecting jet at the nozzle 17 for deflecting the main jet into the opening 20. The inertia of the medium flowing through the tubes 83, 84 causes the pressure in the reservoir 81 to drop below the steady-state value, with the medium flowing in through the tube 82, whereupon there is no further discharge of medium from the reservoir 81 via the tubes 83, 84 . Since the main jet is no longer deflected, the flow through the amplifier A returns to its original state, so that the medium flows into both openings 19 and 20. The tube 84 can be positioned on the tube 83 in the manner indicated by the double arrow in FIG. 9 can be shifted in order to tune the vibrator. The medium is fed to the nozzle 16 via a pipe 50 (FIG. 8).

A portion of the medium must always enter the opening 20 so that the storage medium is supplied when an oscillation is to occur. For this reason, the amplifier A must not be bistable in the case of a jet from the control nozzle 17. In the case of the vibration generator 104 , the medium emerges from the two outlet tubes 121 and 122 during a period, with an outlet from the tube 122 always being present. The amount of medium emerging from the pipe 122 depends on the asymmetry of the amplifier A and the time constants of the flow through the control nozzle 17. The frequency of the oscillation can be changed by changing the values of the accumulator 81, the flow inertance 88-89, the nozzle 17, the tube 82 and the dimensions of the amplifier A.

The vibration generator 105 shown in FIGS. 10 and 11 is similar to the 104, also works in the same way, but is operated with an incompressible medium, for example liquids. The vibration generator 104 is, however, operated with compressible media, for example gases. The similarity of the modes of action results from a flexible diaphragm 86 (FIG. 11) in the memory 87. This combination of a flexible diaphragm 86 with the memory 87 fulfills the same function as the memory 81 in FIG. 8. The edge of the diaphragm 86 is tightly connected to the walls of the reservoir 87. The diaphragm 86 can deform elastically under the action of a liquid pressure in the reservoir 87. In Fig. 11 the container 87 is shown practically at right angles, but it can also have any other shape. The space 87 'of the memory 87 is filled with a compressible medium under a suitable pressure.

The pipe 88 is connected to the storage device 87 and slidably supports the pipe 89, whereby the vibration generator 105 can be tuned. The pipes 88, 89 connect the accumulator 87 to the ambient pressure, which is lower than the maximum total pressure available on the pipe 82 during a period. In the present example, the energy is stored in the storage device 87 by the deformation of the elastic diaphragm 86 or by compression of the compressible medium located in the space 87 '.

With the embodiment in FIGS. 12 and 12a, ultra-low frequency vibrations can be generated. The pipes 50, 91 and 92 (Fig. 12 a) are in place

13 14

with the main nozzle 16 or the control nozzles 17 and results in a memory 134, 134 ', 135 and 135', the 18 in connection. The tube 50 is to store a suitable potential energy. The memory 134 Source 90 of a pressurized medium takes up almost the entire length of pipe 99, closed, and the tubes 91 and 92 can only be completely removed while the accumulator 134 ' speaking with print medium sources 90a or 9i> £> 5 small section of the tube 99 occupies. Entverbundeii being. By means of the valves 93, 93 'in the speaking, the accumulator 135 takes almost the pipe 91 or 92, it is possible to measure the entire volume of the pipe 100, pipe 136, through these pipes to throttle. that connects the ends of the pipe 100, and one

The Steiieidüsen 17 and IS exercise in the vibration tank 137. The memory 135 'is only a small one

generator 106 performs two important functions. First io section in the pipe 100. The tank 137 stands with

. is it connected by the delivery of medium from one or both pipe 136,

the control nozzles possible, the tendency of the main To explain the mode of operation of the

strahk's from the main idiosis 16 for adherence to generation generator 106 is to be assumed that

one of the Knniinerwandungcn 15a or iSb to the main jet of the nozzle 16 via the Kammcr-

steer or "pre-tension". The second function 15 wall 15 ″ to the opening 19 flows. The main ray

of the control irons 17 and 18 is to opt for one of the two

paint operation of the vibration generator 106 safe control nozzles 17 or 18 against each chamber wall

to deliver. The pressure of the medium can be directed from the main.

nozzle 16 can be different from the pressure, the Da of the jet splitter 118 in the plane of the wall

gives optimal operation, d. Ii. If there is one, he shares a certain proportion of the medium

a certain number of oscillations of the flow of the main jet and directs it over the oil tension

in the time unit. By adjusting the valves 93, 116 in the feedback tube 99. The remainder

93 'can be the desired vibrations even part of the medium enters the outlet pipe 121 or in

then generate when the pressure of the main exhaust port 20 a. The cross-section of the

the emerging medium for a given constriction 116 is somewhat larger than that of the constriction

Vibration generator is not optimal. If the 113 or the mouth 130. The opening 116 takes

Vibration generator 106 with optimal medium - the medium in a state in which it is still

pressure from the Haiiptdüse 16 works, can and has considerable kinetic energy. To this

the valves 93, 93 'should descend the pipes 91. 92- way, the pressure in the accumulator 134 of the

lock so that'k ^ in medium to the control nozzles 17 30 pipe 99 to a value that is higher than the

or 18 is delivered. Pressure in the memory 134.

In the outlet pipes 121, 122 there are beam splitters 94, ker. the more medium flows into the opening 116.

94 '· arranged. In this way, four flows through the pressure increase in the accumulator 134 '

Exit pipes 95, 96, 97 and 98 at the ends of the corresponding more medium through the constriction

Pipes 121 and 122. The feedback pipes 99 and 35 133 into the accumulator 134.

100 form a feedback system which can store energy from the pressure increase in the store 134 against the medium and periodically emit this energy over the pressure rise in the store 134 'to an amplifier A , so as to delay. However, the pressure in the reservoir 134, oscillation of the main jet from the nozzle 16, is very soon high enough to cause the UbCr ₁ orifice 130 amplifier. To emit a jet into the chamber 15 at the interfaces of 40, which jet presses the walls 15 ″ and 15 b and the side walls main jet against the wall 15 ″. The 126 and 127 of the feedback pipes 99 and 100, respectively supplied via the orifice 130 of flow changed are constrictions 116 and 116 'are provided, the overall changed the interface between the chamber wall forms are represented by the plates 11 and 13 and by 15 b and reduces the main beam and thus the main edges of the beam splitters 118 and 118 '. The tendency of the main beam to adhere to the beam splitter 118 and 118 'extends opposite wall 15b . With increasing pressure in the course of the sloping of the side walls 15a and memory 134 receives the back pressure in the Einschnü-15 b inwardly. These beam splitters increase by a margin 133, and the pressure in the reservoir 134 'of the proportion determined via the associated wall also increases. - ^

fertilize 15 "or 15 /" of flowing current and 50 The pressure build-up in the storage tank 134 'takes so long

guide it into the opening 116 or 116 'and thus to. like medium with greater speed in the

into the feedback tube 99 or 100. 'Opening 116 enters than through the constriction 133

The narrowed openings 130 and 131 in which it flows out. After a certain time - dependent other diaphragm-shaped end of the feedback from the dimensions of the reservoir and the uppipe 99 and 100 open opposite each other 55 building as well as from the flow velocity in the walls 15 ft or 15 ". The function of the main jet - the pressure in the of these two constrictions is subsequently still memory 134 of the local total pressure, which is caused by described in detail. generates the current entering the opening 116

Three pairs of constrictions are in the two wills. As a result, the pressure in the border

Feedback paths 99 and 100 available. This 60 area of the wall 15 ″ to, and finally

Constrictions form flow resistances, since the control jet from the nozzle 130 does not dominate them

more restrict the flow through the feedback pipes, so that the main jet from the wall 15a

zen and cause a pressure drop. The first is lifted off and no longer into the opening 116

The pair of flow resistances are the narrowed ones. This distraction lowers the pressure in the

openings 116 and 116 ', the second pair is opened 65 opening 116 under the pressure in the container 134'.

forms through the narrowed openings 130 and 131. Medium therefore emerges from the opening 116 and

and the third pair are the constrictions 133 reaching into the interface between the main ray

or 133 '. Between two flow resistances and the chamber wall 15 ″. That so special

The emerging medium modifies the boundary layer along the wall 15 α in such a way that the main jet is kept from the wall 15 α and is pressed against the dividing wall 21a and the wall ISb , to an extent that depends on the pressure of the opening 116 escaping medium depends. This effect reduces the flow through outlet pipe 95.

The deflection of the flow from the wall

16 shows another possibility of use the vibrations of the device according to the invention.

A roller 140 provided with a central recess and carrying a perforated belt 141; can in the direction of arrows DD by the oscillating flow, which is against two disks 142 and attached to the drive shaft 144 of the roller 140

Storage tanks and tanks, the medium used, the length and diameter of the pipes and the desired Vibration frequency.

If memories are used as the only energy storage device, they can be used in conjunction with resistors in the form of constrictions or porous plugs used to adjust the phase of the feedback path to the amplifier in the

it is possible to control the flow from one of the outlet pipes 121 'or 122' according to the original Ensure commands of the output signal of the vibration generator 106. Every common one 5 flow flip-flop (not shown further), can be activated by the output signal from the tubes 121 ', 122 'of the multistable signal storage system 110 are driven. Porous plugs 113 and 113 'are attached to the tubes 121, 122 in order to

15 a against the wall 15 b and from the pipe 95 in io load to adapt to the vibration output to pipe 96, 97 or 98 leads to the fact that the divider 118 'can,
diverts an enlarged portion of the medium into the opening 116 '. This medium causes you
Pressure increase in accumulators 135, 135 'and 137,
whereupon the mouth 131 medium to the border layer 15
tengebiet between the main beam and the chamber wall 15 a supplies, so that a deflection
of the beam against the wall 15 b occurs. This in turn increases the proportion of the

Divider 118 'in the container 135' meets the diverted 20 143, to be moved back and forth. The tape 141 diums too. can be used, for example, to sieve sand or other

The opening 116 'is larger than the constriction whose granulated material is used. 133 ', which is formed by the pipe walls, and in general depends on the optimal feed pressure

is also larger than the opening of the mouth 131. For the devices described, the opening 116 has practically the same size as the size and shape of the chamber 15, the size of the opening 116 '. The mode of operation described above for the feedback resistances, the volume and the shape of the tube 99 also applies to the
of the feedback pipe 100. In this way, an oscillation of the medium in the outlet pipes 121 and i22 as well as in the pipes 95 and 30 results

96 and the tubes 97 and 98. The tubes 95 and 96,

97 and 98 or 121, 122 can therefore be used as a push-pull output for controlling a beam amplifier to be used. If the respective memory is around

have the same volume and if the inputs 35 correct way to effect. When inertia constrictions and constrictions in the feedback function alone as energy storage, they can together have about the same size, one in the men with flow resistances to adjust the essential symmetrical square waveform of the correct phase relationship to maintain Flow serve as the exit of the outlet pipes 121 and 122 of the oscillation. When using or 97 and 98 or 95 and 96 as in Fig. 13- 40 Storage and inertia depends on the frequency shows received. The other factors affecting each vibration from the resonance frequency of this particular vibration properties are a combination of, or of the time delay the pressure at the main jet, the relative limit in the feedback loop. Stratification effects due to the currents from The feedback path through which the stored

the openings 116 and 116 'and from the openings 45 energy to control the energy in the Schwin-130 and 131 as well as the control jets of the nozzles 17 generation generator is returned, can from a and 18, if any. If the vibration is simple pipe or from numerous combinations generator 106 has started to oscillate, needs to consist of memories and resistors, which so none of the control nozzles are to be used unless one of the stored energy is arranged because, as mentioned above, no optimal 50 are delivered to the amplifier with the correct timing Working conditions are in place. is used to cause the oscillation. the

Fig. 14 shows the square wave form of the output feedback path can be made from a series circuit, output signal generated by one of the parallel circuit or series-parallel devices according to the invention can be obtained if a circuit of carry masses, memories and cons-beam amplifiers of the boundary layer type exist as flip 55 stands. He can also flop out of himself again using the vibrator-generating ladder-like connections of these elements The output is operated as a push-pull control signal, as shown in FIG. The oscillation frequency can be specified in the

FIG. 15 shows the oscillation generator 106 of the exemplary embodiments through modification along with a multistable latch 60 of size, shape and feedback path system 110 ', which has control nozzles 17' and 18 ', and the energy storage devices are changed the output tubes 121 and 122 of the vibratory. For example, the oscillation frequency is generator 106 are connected. As the storage decreases due to increasing volume of the flow system has the property of releasing the flow into the feedback system. The Vorin that of the openings 19 'or 20' to maintain 65 directions of the invention can be used to generate th against which the main ray is ultimately caused by one of the oscillations in the considerable frequency range Control nozzles 17 'or 18' was directed. even if from ultra-low frequencies to supersonic frequencies Control jet as such is no longer available. ze η are formed, specifically as a function of

109 * 13/78

on the relative dimensions of the numerous elements that determine the frequency of oscillation.

Since the devices described also watch sound vibrations they can also be used, for example, to generate vibrations Use in a detergent solution to soak the surfaces of steel, porcelain or other in the solution to clean immersed materials.

Claims (8)

Claims: 10 1. A device for generating mechanical, technical work performing vibrations by means of a medium flowing through the beam amplifier and energy storage devices, characterized in that from collecting openings (19, 20) of the main beam of a beam amplifier (A) feedback paths (26, 27, 29; 33 to 36) lead to one or more feedback nozzles (17 α, 18 α; 172, 182 ) lying on the side of the main jet nozzle (16), and that the feedback paths (26, 27, 29; 33 to 36) are energy stores or such (22, 23 , 24; 33, 34, 35, 36) included. 2. Device according to claim 1, characterized in that the energy store is an at least partially filled with fluid cavity (22, 23, 24) "., 3. Device according to claims 1 and 2, characterized in that in the feedback paths (26, 27, 29; 33 to 36) resistors are included that shift the phase position of the feedback signal. '.' ■ 4. Apparatus according to claim 3, characterized in that the resistors are pipe constrictions or porous plugs (31a, 316, 31c). ·; 5. Device according to one of claims 1 to 4, characterized in that two walls (15 a, 15 b) behind the main nozzle (16a) approach the main jet so that an artificial boundary layer effect between the main jet and one of the walls (15 a or 15 &), over which the main jet flows, forms, each wall (15a, 156) being assigned a feedback tube (29, 29 '). 6. Apparatus according to claim 5, characterized in that in each case the feedback tube (29, 29 ') equipped with two constrictions is, between which a cavity (22, 22 ', 23, 23', 24, 24 ') is formed. 7. Device according to one of the preceding claims, characterized in that the portion of the medium not absorbed by the feedback path enters in an oscillating manner into one or more of a system of outlet openings (121, 122) to which loads are connected. 8. Device according to one of the preceding claims, characterized in that a multistable signal memory (HO ') is connected between the downstream load and the two outlet lines (121, 122) (Fig. 15). In addition 5 sheets of drawings