DE1597012A1 - Supersonic generator, particularly suitable for non-stop bottling for gaseous (fizzy) drinks - Google Patents

Description

¢ Supersonic generator, particularly suitable for bottling at Moving belt for gaseous (effervescent) beverages The present invention relates to a generator of supersonic vibrations of medium strength, based on the exclusive Use of semiconductors is based and to interact with magnetostrictive Converters and for remote control and remote regulation. The one in question For example, but by no means exclusively, Generator is for use in Bottling systems for gaseous effervescent beverages *) (i.e. natural or added Containing C02) stipulates the areas in which its technical characteristics, its practical suitability, the fulfillment of the requirements in terms of safety and Protection for the operating personnel can be demonstrated in the best possible way. On this one In a particular area of application, the supersonic waves are used to displace the in the Bottles (or containers) were left with air before sealing or corking he follows. The work processes are as follows: a converter (i.e. a per se Well-known device that converts electrical vibrations with supersonic frequencies into mechanical ones Vibrations of the same frequency) touches due to its influence the signal transmitter only briefly before the bottle (or container) she is closed, whereby the CO2 in the liquid is released and the space previously occupied by the air in the bottle between the liquid level and fills the neck rim of the bottle.

Shortly after the bottle was exposed to this contact with the transducer it is locked. This displacement of air prevents that the air residues remaining in the bottle trigger an oxidation of the liquid, which is often favored by the catalytic effect of light. In some Cases, especially when the bottled liquid is beer the excretion of CO2 triggers foam formation.

The supersonic generator based exclusively on the use of semiconductors, which is provided in cooperation with magnetically strict transducers and also is provided with a power level, is characterized according to the invention, that the power stage works with an at least approximately right-angled shaft and is supplied by a snare-adjustable voltage.

Needless to say, there is no need to describe the converter in more detail is a known and common device. The together with uem invention Generator used converter is magnetostrictive training.

The invention will now be described below with reference to the accompanying drawing for example, and therefore not restrictive, described in more detail, namely show: FIG. 1 the flowchart for illustrating the mode of operation of the invention Generator, Fig. 2 shows the electrical circuit diagram of individual parts of the subject matter of Figure 1, Fig. 3 the circuit diagram of the stabilized feeder, in block form is shown in Figure 1, Figure -4 shows the electrical circuit diagram of the power feeder, which supplies the power required for the output stage.

Figure 1 of the accompanying drawings is the flow chart showing highlights the functions of the subject matter of the invention.

The aack A is an oscillator that generates a signal that is transmitted by means of B can be regulated in its frequency.

Signal A is amplified at C. A and C are replaced by a common stabilized feeder D supplied so that the frequency stability of the Oscillator is guaranteed. The amplifier C is operated by the device E, which represents the remote switch for the signal given by the oscillator. This Signal amplified by C goes on to a power stage F; this latter stage F. is supplied by another feeder o, which has a built-in voltage control H as well as a further remote regulation I for the voltage itself; these regulations are switchable in the sense that either one or the other others can be brought into effect. Block K is a simple mixed circuit for the signal coming from power stage F with a direct current component, which is supplied by the feeder L and regulated by M. The component in question is required to premagnetize the converter N. The latter is educational magnetostrictive and its description in detail is unnecessary, since it is not for Area of invention belongs.

FIG. 2 shows the electrical diagram of the Bbcs A, C, E, F, K of Figure 1. The block A consists of the parts 9-10-11-12-13-14-15-16-17, which are connected to each other in such a way that a multiple vibrator is created, on the one hand Via point 18 and, on the other hand, via one of parts 5- (feed point) -6-7-8 existing voltage divider is supplied. The potentiometer 6 (measuring bridge) enables a semi-stable regulation of the frequency, while the potentiometer 7 the fixed Frequency regulation itself permitted; the latter is at an easily accessible location Place of the device and is operated so that the frequency of the oscillator the natural resonance frequency of the transducer N is adapted. The multiple vibrator is to generate a symmetrical right angle shaft with pretty steep climbs: this measure is necessary for the correct function of the subordinate Steps required.

The capacitors 19 and 20 transmit the signal to a symmetrical one Amplifier (block C of Figure 1) consisting of parts 21-22-23-24-25-26-27-28-29-30-31 -41 exists. This amplifier has the task of keeping the rise times short monitor the signal; for this purpose the feedback loops 28-29 -and 30-31 planned. Point 32 is the center connection of the primary winding a two-wire wound transformer.

The resistor 21 actually belongs to the remote switch X, to which parts 33-34-35-36-37-38-39-40 also count. This resistor 21 interrupts, if switched on, the gain level and thus blocks the signal. Located on the other hand, if this stage is in operation, then 21 is through the relay contacts 33-35 des Relay 36 short-circuited, the latter being energized by contacts 39-40, which, for example, from the auxiliary contacts for switching the motors for the Drive the bottling machine serving remote switch can consist of about the one consisting of the primary winding 41 of the ferrite core 42 and the secondary winding 43 Transformer, the amplified signal is used to control the power level (Fig. 1) passed on.

The power stage F consists primarily of the transistors 53 and 54 and the winding 58, the latter lying on the ferrite core. The condenser 44 has the task of correcting the signal and can also be used in the event of failure. on the drawing in FIG. 2 shows further transistors (51-52-55-56), which are parallel to the other two 53 and 54. Such an arrangement can Prove to be advantageous when several transistors of cheaper design and connected in parallel instead of just two, expensive ones should be used.

The resistors 45-46-47-48-49-50 on the bases of the transistors are used the current limitation and to compensate for the inevitably occurring with the same Differences in the characteristics. About overheating and the destruction of the transistors To avoid the output stage, the latter must be used under conditions with right-angled Waves work and with a fairly steep climb. The power transistors are preferably arranged on cooling fins, which are not shown in the scheme. That Element 67 of FIG. 3 is a small fan for better cooling.

The coil winding 58 lying on the ferrite core is supplied via the middle terminal 57 the transistors of the indstage. So it does not represent the Load on the stage, which, however, is given by the converter, which on the points 63 and 64 is connected, to which via 61 and 62 also a constant component which is supplied by a feeder, which is shown in FIG. 1 by the block L is shown. The capacitor 59 is used to transmit the signal to the converter, while he blocks the DC component.

Figure 3 shows the electrical scheme of the stabilized Iinspeisers, which is shown in Figure 1 by the block D and the electrical scheme of the bin feeder for the premagnetization, which is shown in FIG. 1 by the block L is pictured. The stabilized feeder is traditionally trained. the Positions 65 and 66 indicate the input of the power line into the transformer, the consists of the primary winding 68, the core 70 and the secondary winding 71. the electrostatic, grounded shield 69 has the important role of the primary current (Mains) to be separated from the rest of the device for reasons of protection. The bridge 77 supplies the Stalilisierungsstromkreis, which consists of the transistor 83, which in turn through the transistor 84 is controlled, to which a Zener diode 85 the reference voltage supplies; the other components 73-78-81-82-88-89-90-91-92 the other accessories of the feeder, who, after it is a Herculean training, is not to be regarded as falling within the scope of the invention. The one together with Point 94, which is connected to earth, is the output and is connected to points 5, 18 and 32 of Figure 2 connected. Points 93 and 94 can also be attached to points 38 and 37 of Figure 2 be connected and thus to supply the relay for serve the remote control.

Furthermore, according to FIG. 3, the secondary winding 72 of the transformer takes care of it by means of the directional diodes 74 and 76 and the inductance 80 the power supply for the bias of the transducer. The capacitor 79 is provided for large power. The variable resistor 75 (which corresponds to the organ M in FIG. 1) finally serves to adapt the current to the characteristics of the pre-magnetization of the converter. the Arrangement of this resistor is very important after having the same to the corresponding one Compensation in the event of a voltage drop is used, which is along the the converter with the generator connecting cable occurs, the length of this cable varying from case to case can change and can be 10 and more meters. Positions 86 and 87 are on the points 61 and 62 of Figure 2 are connected.

Figure 4 shows a power supply line (blocks G and I of Figure 1) which supplies the current required for the output stage F. The same belongs to present. Invention after, among other things, in a simple and convenient way remote control of the output stage F allows. This regulation can actually only by changing the supply voltage when using transistors of the output stage itself after a change in the control signal is not allowed.

The feeder, which is shown in FIG. 1 by the block G and the remote control I consists of a transformer whose primary winding at 96 is displayed. The digits 98 and 99 are the connections to the network and 100 is a two pole switch. Dit is applied to the primary winding 96 Primary development of the transformer of Figure 3 (points 65 and 66) placed in parallel so that the switch 100 can operate both transformers. The gas-filled lamp 102 in series with the resistor 101 is the signal lamp, which indicates that the device is working. The other lamp 10o, also with gas filling, connected in series with the resistor 105 is switched, on the other hand, is the warning sign for the interruption of the fuse LOT: it usually stays erased and only lights up when the fuse blows. This precaution is important in companies where technical maintenance is not very strict and looking for the interruption of a backup is time consuming. The primary development The transformer is powered by the secondary winding by means of an electrostatic Shield 95 causes which is grounded, as in the case of the transformer according to FIG Figure 3.

The secondary winding 104 spdst one of two normal diodes 119 and 120 and two controlled diodes 132 and 133 existing bridge. This arrangement a straightening bridge, which is controlled by the circuit described below supplies a directed voltage whose half-waves are divided (partialization) are. This enables the output voltage at the grommets 154 and 155 to be changed.

Such a feed-in method is the most suitable power circuit, where the use of transistors in voltage regulation circuits is considerable Brings trouble as a result of the heat to be dissipated by it.

The diode bridge becomes conductive when connected to the control electrodes of the controlled Diodes 132 and 133 have a positive voltage. This tension becomes intermittent supplied by the oscillator, which consists of a single-faced transistor 149, which acts together with the resistors 151 and 146 as a loosening circuit, its Time constant through the capacitor 145 and the resistor 150 is given. the The feed voltage of this oscillator is supplied by the secondary winding 103 and is directed by the diode bridge 97: it is then made by Zener diodes 147 and 148 stabilized (with the appropriate voltage, only one would be sufficient here) which have the limiting resistor 152. The tension must be stabilized so that, in turn, the oscillator also remains stable. That by the parts 145 and 150 for controlling the transistor 149 emitted signal is superimposed on a signal with DC component, originating from the circuit of transistor 130 to which the parts 137-143-138 are connected as well as the St: abilisierungsnetz 144-122 and 115. The DC component emitted by transistor 130 is applied to the base of the transistor Tension determines which of the elements 142-129-121-117-134 will gel is as well as from the diode 114. With 129 is the determining the level of this voltage Called potentiometer. The same thing is in parallel with another potentlometer, its runner by means of the switch 128 together with the runner of the potentiometer 129 is switchable.

The use of the otentlometer 134 (block I) i.e. the switchover Adjustment on this potentiometer enables the output voltage to be set remotely of the feeder and the corresponding regulation of the current with (Jsound frequency that is transmitted to the transducer N.

Since the potentiometer 134 of the control I also remain disconnected can, be it due to the carelessness of the installer or the operating personnel or as a result of an interruption in the connection cable, and there that Lack of a connection of this potentiometer 134 when changing the voltage divider 121 an increase in the output voltage of the feeder, destroying the transistors the output stage, a fuse arrangement according to the invention is provided, consisting of the transistor 118 of the base, whose polarization network 136-123-116 and the resistor 131. When the output voltage of the feeder is exceeded beyond a level determined by the voltage divider and the Zener diode 136, a DC component is fed to the emitter of the single-surface transistor 149, which further reduces the division (partition) of the half-waves.

The capacitor 125 has a fairly large capacitance, so that it can act as a good complement to the shared tension, given the sizeable Value of the consumed current. This current consumption is determined by the ammeter 153 displayed. The inductance 113 provides another filter element for this current represent.

Part 110 is a small incandescent lamp; it lights up when the switch 128 for remote control is set to "remote control, parts 108-109 and 110 are part of the switch 128 in question.

The resistor 111 is used to trigger a small voltage drop, so that point 112 can be supplied from point 93 in FIG.

Claims (11)

A n s t e c h e 1. Supersonic generator, which is exclusively based on the use of semiconductors, intended to be used in conjunction with magnetostrictive transducers (N), characterized in that the power stage (F) works with a right-angled shaft and by means of a controllable voltage (via I) is supplied. 2. supersonic generator according to claim 1, characterized in that the regulation of the power of the output stage (F) by regulating the supplying this stage Voltage happens with the waveform remaining the same as the power changes. 3. supersonic generator according to claim 1 and 2, characterized in that that the signal output is interrupted by simply opening and closing the contact (E) without interrupting the supply voltage of the stages, but only one of them (C) is excluded. 4. Supersonic generator according to claim 3, characterized in that the excluded level (C) is the tax level of the performance level (F) and thereby the stability of the vibration level is not impaired. 5. supersonic generator according to claims 1 to 4, characterized in that that the stage (A) of the signal generation is a multiple vibrator with a frequency regulator (B) is provided, whereby the regulation in question means changing the supplying him stabilized tension happens. 6. Supersonic generator according to claims 1 to 5, characterized in that that the signal generated by the multiple vibrator is amplified by a symmetrical Sture (c) is, which has a symmetrical feedback loop, so that the steep Rise times of the signal are maintained. 7. Supersonic generator according to claims 1 to 6, characterized in that that the output stage (F) is supplied by a feeder (G), using a Bridge made of controlled diodes, so that the voltage can be regulated remotely is possible and through this voltage regulation the output power of the supersonic signal can be regulated. 3. Supersonic generator according to claims 1 to 7, characterized in that that the feeder (G) of the power stage (F) has a double, switchable Regulation (H, I) has and a regulator (H) is assigned to the apparatus while the other (I) can be arranged at a distance from this. 9. Supersonic generator according to claims 7 and 8, characterized in that that it has a fuse arrangement (118, 13, 11, and, which intervenes, if the potentiometer (134) of the remote control (I) should be disconnected. 10. supersonic generator according to claims 1 to 9, characterized in that that the same with a feeder (L) for Bias of the Converter (N) is provided, -whose output current (M) can be regulated and thus can be set to the best performance of the converter, taking into account also the length of the connecting cables. 11. Supersonic generator according to claims 1 to 10, characterized in that that the same is especially suitable for use in systems for bottling gaseous products Beverage is suitable as a displacer of the air residue jammed in the bottle neck before the bottles are closed,