DE1260286B - Electronic organ - Google Patents

Description

Electronic organ The invention relates to an electronic organ Organ with master oscillators and divider chains, each divider oscillator having one Output for the continuous tone and an output for the synchronization signal of the next Has divider stage.

The invention is based on the object of such an electronic To train the organ in such a way that simultaneously with the continuous tone or alternately with it Striking a key on a special staccato keyboard makes a staccato tone or a series of staccatos can be generated which are also equal in pitch to the or the continuous tones that are struck.

In the known electronic organs there is such a way of playing not possible.

The object is achieved in that a further Output of the divider stage is blocked by a reverse voltage that is activated by actuation a staccato key is eliminated and provides a staccato signal.

Sound effects can be achieved through this design of the electronic organ achieve that could not previously be achieved with such organs.

The particular advantage of the switching arrangement according to the invention lies in that when the staccato key is struck, the generator that produces this sound should, has already settled, so that the sound without any time delay is delivered.

It is preferably also provided that the continuous tone output each Tone generator via contacts and fixed rails to one RC filter in each group differently tuned filter is supplied, while the staccato output of the same Tone generator only after applying a positive DC control voltage via the associated Staccato key supplies vibrations to the associated filter, with preferably several staccato outputs are grouped together.

Finally, it is provided according to the invention that for each tone generator an electron tube with a single control grid, a single cathode and two identical anodes are used, one of which is the continuous tone, the other of which on the other hand, the staccato tone is removed.

The invention is explained in more detail below in an exemplary embodiment with reference to the drawing. F i g. 1 shows a schematically simplified circuit diagram of some tone generators, FIG. 1 -A is a schematic representation of some of the output connections of these tone generators, FIG. 2 is a schematic circuit diagram for the key switches and some related controls, FIG. 3 shows a schematic circuit diagram of some filters and pedal generators, FIG. 4 is a continuation of FIG. 3 at its lower edge, which schematically shows the register, and FIG. Figure 5 is a block diagram showing various stages of the electronic organ.

The organ according to the invention uses main and secondary oscillators and works according to the frequency divider principle. In particular, are for a whole Octave main oscillators provided with great stability. Four of these main oscillators stabilize several secondary or partial oscillators, each one significant may or may even have less inherent stability than the main oscillators may be incapable of independent vibrations of their own.

A brief overview of how these oscillators work, so far it is necessary for an understanding of this invention will be linked below with the F i g. 1 and 1 A. Inside is the main oscillator with the general one Reference numeral 10 is provided. A whole group of partial oscillators is attached to this main oscillator 12, 14, 16 and 18, all of which are controlled by the main oscillator. The first secondary oscillator 12 is controlled directly by the main oscillator 10, while the second sub oscillator 14 is controlled by the first sub oscillator 12 will etc.

The main oscillator has a Hartley circuit and contains a vacuum tube 20. This tube 20 is of a very special type; it comprises a single cathode 22, a single control grid 24 and two anodes 26 and 28. These anodes are not shaped and arranged like the usual baffles of a pentode as auxiliary plates, nor in any other known manner. Rather, this is a new development that has considerable advantages over the known tubes and is designated 12 FQ 8. The cathode 22 is directly grounded, while the first anode 26 is connected to a connection point 30. This point 30 is connected to the positive pole of a DC voltage supply line 34 via an external anode resistor 32. Point 30 is also connected via a coupling capacitor 36 to tuned circuit 38, which includes a fixed capacitor 40 and a tunable inductor 42. The other end of this tuned circuit is coupled to the grid 24 through a capacitor 44. In addition, the grid is connected to a vibrator connection 48 via a resistor 46.

The inductance 42 is tapped at 21% of its total number of turns and this tap is grounded. At the audio output 56 is to this with a shunt to be provided and for insulating purposes, a resistor 54 connected to his the other end is grounded. The connection 5, 6 is also via a capacitor 58 coupled to the aforementioned point 30. The resistor 54 and the capacitor 58 together form a differentiating network, which causes an the output lying on terminal 56 has a significantly higher level of harmonics, than it corresponds to the signal at the anode of the oscillator.

The main oscillator 10 operates as a class C amplifier; the capacitive Loading of the anode via the capacitor 58 and the resistor 54 to earth as well Via the capacitor 36 and the inductance 42 to ground, practically a Sawtooth shape of the anode alternating voltage.

By these measures, the terminal 56 contains the differentiating network The alternating voltage supplied to 58 to 54 has many harmonics and is therefore well suited; to produce pure musical tones through filtering.

The second anode 28 is given a negative potential via a resistor 60 from a bus 62 in order to prevent this anode 28 from responding to peaks of alternating current signals which are coupled into it via capacitors 70 and 74, as will be described below. The second anode 28 is connected via a resistor 64 to an output socket 66 through which on the one hand the desired anode potential is applied to the anode 28 and on the other hand is blocked to earth by a capacitor 68. The capacitor 68 is used in conjunction with a key resistor and key switches to suppress key clicks and other noises.

The anode 28 is further triangular by a capacitor 70 output terminal 72 shown and also coupled by a coupling capacitor 74 connected to an output manifold 76.

The oscillation of the main oscillator 10 by virtue of that described above Hartley circuit including cathode 22, control grid 24 and anode 26, generates oscillations of the same frequency at the anode 28 as soon as a positive voltage is applied to socket 66. These vibrations have a sawtooth shape. The output of this anode can be processed in a variety of ways, such as it is indicated by the connections 66 and 72 and the output manifold 76 and as will be discussed in detail below.

Let us now consider the secondary or partial oscillator 12, which is also characteristic of all other secondary oscillators. This secondary oscillator 12 comprises a tube 78 of the same type as the tube 20 discussed above, containing a cathode 80, a control grid 82 and two independent anodes 84 and 86. Preferably, two such tube systems are contained in a common bulb, which is indicated by dashed lines of the second system in each of FIG. 1 shown tube is indicated. The cathode 80 is grounded, while the anode 84 is connected to the already mentioned positive busbar 34 through an external anode resistor 88. The other anode 86 is, in the same way as the second anode of the tube 20, connected to an output circuit, namely to an output socket 91, an output connection 92 and a bus line 76. The connections are made in the same way as with the main oscillator.

The control grid 82 is connected to the anode 26 of the tube 20 via a capacitor 89 and a resistor 90 and is therefore controlled by the alternating voltage occurring at this anode. The grid is blocked from ground by a capacitor 92 and is also connected to a resistor 94. This resistance leads to a connection 96 which in turn is blocked from ground by a capacitor 98. This connection point 96 leads to a resistor 100 and is also connected via a series resistor 102 to a bus line 103 which supplies a negative bias voltage of 3 volts.

The resistor 100 in turn leads to a switching point 104 which is connected to the grid of the oscillator tube in the next divider stage 14 via a line 106 and a resistor 108. The switching point 104 also leads via a capacitor 110 to the anode 84 of the tube 78 and, on the other hand, via a capacitor 112 to an output terminal 114, shown as a square in the drawing. This output terminal 114 is connected to ground via a resistor 116.

The partial oscillator 12 works roughly like a phase shift oscillator; however, it will not be necessary to explain the exact method of operation at this point. Suffice it to say that this oscillator is at half the frequency of the main oscillator 10 works and practically also produces a sawtooth shape.

The other secondary oscillators 14, 16 and 18 each work in succession at half the frequency of the previous one and also all generate one sawtooth output voltage.

Before explaining how to switch the keys, let me briefly mention the F i g. 1 A discussed. As you can see, there are several exits to one Group summarized, for example the outputs 72 from the second anode 28 of the Main oscillator, hereinafter referred to as the staccato anode will, and led in groups of six to group exits 118. These groups are accordingly with in the numbers 1, 2 etc. to number 8. The last group, the group 8, summarizes 14 individual connections, so that a total of 61 tones are available.

In Fig. 2 the manuals are shown schematically from their rear side, with the treble on the left and the bass on the right. The top manual is also at the top in the figure, while the bottom manual is at the bottom. The uppermost manual contains a fixed stick 120 for the 4-foot register, below a fixed stick 122 for the 51/3 foot register and below that a fixed stick 124 for the 16-foot register. These bars are made of insulating material and are each provided along their upper edge with an electrically conductive insert which extends through an insulating plate 126 on the left side of the arrangement. The rod 120 has a conductive insert 128, the rod 122 has a conductive insert 130 and the rod 124 has a conductive insert 132. The connections from these conductive inserts to the register flaps will be explained in more detail below in connection with another figure of the drawing.

The rigid bars 120, 122 and 124 are each a number more flexible Associated contacts, which are represented in the drawing by the squares 134. These squares correspond to squares 56 in FIG. 1. Those represented by squares 56 Connections in FIG. 1 are namely via resistors 136 with these contacts 134 connected. These squares are numbered accordingly in the drawing the number of the tone generator whose output is connected to this movable contact is. As one can see from FIG. 2 recognizes repeat themselves in the top row of contacts the first twelve notes of the highest octave immediately to the right of it again, and the contacts corresponding to these squares are in a simple manner with the Contacts of the top octave connected by wire clips. This measure is at Organ building common, as there are only 61 tone generators, while in the manual of the four-foot register would still have space for an additional octave of keys. The same is the case with the 51 / sec foot register 122, where seven generators are repeated will.

One can also see from FIG. 2 that some tone generators are connected so that they feed more than one register at the same time. First of all, the tone generator establishes a connection to a movable contact via a resistor, and then a connection to a correspondingly designated contact of another register is established from this contact via a further resistor. For example, at the extreme left end of the 51/3 foot register there is a connection via the leftmost resistor 136 to the signal contact 56 and from this via the sixth resistor from the left in the 4 foot register there is a connection to the signal contact there Konatkt 56 made. Only a few of such connections are shown as examples, as was the case with the aforementioned wire bridges. Resistors 136 are provided to provide some isolation.

Under the three fixed rods 120, 122 and 124 there are three rotatable rods, namely a rotatable rod 138 for a further 4-foot register, a rotatable rod 140 for an 8-foot register and a rotatable rod 142 for a 16-foot register -Foot register_ The rotatable rod 138 has an electrically conductive insert 144 (as the rotatable rods are designed in the same way as the aforementioned fixed rods). This insert 144 is connected to a resistor 148 on the insulating plate 126 by a spring 146. The resistor is connected to a manifold 150 at its other end. The conductive insert 152 of the rod 140 is connected by a spring 154 to a resistor 156, which is also connected to the manifold 150. In a corresponding manner, the rotatable rod 142 also has a conductive insert 158, which is connected to the collecting line 150 via a spring 160 and a resistor 162. The rotatable rods are arranged so that they can be touched by wire or brush contacts 164 and are, according to the associated generators, placed at a certain level. Each of the aforementioned contacts 164 is connected to one of the connections 66 of a generator circuit according to FIG. 1 connected to the staccato anode of the associated oscillator. As with the fixed bars described above, the contacts with the same numbers are connected to one another and some contacts are repeated within the same register. In these cases the connections are made directly, without the use of resistors.

Each key of the manual is assigned to six movable contacts, which are shown in FIG. 2 are represented by the squares 134 and circles 164 arranged one below the other in vertical rows. When a key is depressed, all of these six movable contacts in the vertical row are depressed. The contacts arranged above the rotatable rods then either establish electrical contact with them or not, depending on the angular position of these rods.

Among the three rotatable bars mentioned above, there is one more rotatable rod 166 arranged. This also has a conductive insert 168, which is grounded here via a spring 170. This rotatable rod 166 is a larger one Number of contacts 172 associated with the rods described above; these contacts namely correspond to all individual oscillators of the organ, starting with the oscillator Number 6 to oscillator number 61. All these contacts 172 are constantly on the rotatable rod 166. They are flexible contacts, but they are are fixed in their position and are not controlled by buttons. If now the Rod 166 is rotated so that the conductive pad 168 comes up, then come all contacts 172 with this insert 168 in conductive connection, whereby they are all grounded. This grounding causes a control bias on others Place the organ and is used to hold generated notes.

As already mentioned, a lower keyboard is also provided. This comprises three rods, of which the uppermost solid rod 174 has a conductive insert 176 . The second rod 178 , on the other hand, can be rotated with its conductive insert 180 , while a further fixed rod 182 with a conductive insert 184 lies underneath. Rod 174 belongs to a 4-foot register that cannot be played staccato, rod 178 to an 8-foot register that cannot be played staccato, and rod 182 in turn belongs to an 8-foot register that cannot be played staccato.

The connection of the conductive insert 176 is made by contacts on an insulating plate 186, the connections of which are explained below with reference to another figure. The conductive insert 180 is led via a spring 188 to a resistor 190 on the insulating plate 186, from the other end of which a line 192 leads to the base of the resistor 162 via a connecting line 150. As can be seen, the resistors 148, 156 and 162 are connected to one another on one side by a wire 194. Between lines 150 and 192, a connection for a positive DC voltage of 300 volts from the amplifier is provided at 196.

The structure and arrangement of the switching contacts in the lower keyboard are similar to those of the upper keyboard. Here, too, contacts located vertically one below the other are moved at the same time when the associated button is pressed. Here, too, those contacts that do not belong to staccato tones are shown by squares with the reference numeral 198, while the contacts belonging to staccato tones are again shown by circles with the reference numeral 200. Contacts 198 are connected to resistors 202 as described above.

In Fig. 2 some parts are shown between the upper and lower keyboard in the middle, which will be described in more detail below. First there is a register flap 204 through which, as indicated by the dashed line 206, the rod 138 for the 4-foot register can be rotated. This flap 204 represents a so-called coupling between upper registers according to the usual designation of organs. Next to it there is another register flap 208 with which, as indicated by the dashed line 210, the rod 142 of the 16-foot register can be turned . This register flap also represents a coupling for upper registers. It should be noted that the rods 138 and 142 are normally in their switch-off position and are only switched on by operating the corresponding coupling flaps.

The third register flap 212 is, as indicated by the dashed line 214, mechanically connected to the rotatable rod 140 for the 8-foot register and allows its rotation. It should be noted, however, that this rod is normally in its switched-on position, ie that in the rest position of the aforementioned flap, the conductive insert 152 is on top and can touch the contacts 154. However, as soon as the register flap 212 is actuated, the rod 140 is rotated into its switched-off position. This register flap 212 is therefore designated as follows: "Upper 8-foot register off". The next register flap 216 represents a control option in order to keep the generated tones more or less long. This flap controls a movable switching contact 218, which faces a grounded contact 220 and can be brought into contact therewith through the flap. This movable contact 218 is led via a resistor 222 to a connection 224 which is blocked from ground by a capacitor 226. This connection is connected to the negative pole of a DC voltage source from the amplifier and also has an output 228 to which either -5 volts or -130 volts can be applied. Normally, as long as the switch 218, 220 is open, the output 228 is at -130 volts. As soon as the aforementioned switch is closed, however, the resistor 222 becomes part of a voltage divider (the other part of which is not shown), with the result that the voltage at the output 228 breaks down to -5 volts.

Another register flap 230 is used to switch the Holding a tone and is, as indicated by the dashed line 232, mechanically connected to the rod 166 and allows it to rotate.

Another register flap 234 is mechanically connected to the rotatable rod 178 in the lower keyboard and allows its rotation. This flap 234 thus represents a coupling between the top and the bottom for the 8-foot register.

Finally, another register flap 238 allows the overall volume to be changed. This flap 238 controls a movable switching contact 240 which is connected to the amplifier via a line 242. In the rest position of the flap, this movable contact 240 rests on a fixed, earthed contact 244. This will ground a specific point (not shown) in the amplifier. If, on the other hand, the flap 238 is brought into its "full work" position, the switch 240, 244 is opened so that the aforementioned specific point in the amplifier is no longer grounded and the amplifier consequently has a higher gain and louder volume Sounds generated.

As soon as the organ is switched on, all oscillators vibrate and the outputs of the respective left anodes (see FIG. 1) supply a constant output alternating voltage to the output connections 56, 114, etc. shown in the drawing as squares always an output voltage, without staccato effect, available. It is then only necessary to depress the corresponding key in order to bring one of these output voltages to the inserts 128, 130 and 132 of the fixed rods, which serve as busbars, so that corresponding organ tones are generated in the manner to be described. The anodes on the right in the drawing, which have been designated as staccato anodes (28, 86, etc. in FIG. 1), are normally not in operation because the required anode potential is not available, or, more precisely, because of these Anodes has a negative blocking potential of either 5 volts or 130 volts, which is fed to them from the bus line 62 via the aforementioned output 228, this bus line 62 being of course continuously connected to the said terminal 228 . As soon as one of the rotatable sticks is turned into its playing position and a key is pressed, the positive direct voltage of 300 volts occurring at 196 is applied to the corresponding connection of the associated staccato anade, for example 66 or 91, via the corresponding switching contact (see Fig .1). This high anode potential also allows an anode current to flow in this second anode and thus supplies a staccato output signal to the line 76 and the corresponding output marked with a triangle, for example 72, 92 or the like.

In the now to be described FIG. 3 of the drawing, the triangles 1.18 have the same meaning as in the already discussed FIG. 1 A. These group contacts 118 are, according to the numbering in FIG. 1 from left to right, here numbered from bottom to top. All of these group connections 118 are blocked from ground by capacitors 246 and are otherwise routed to lines 248. These lines go down in the connection diagram of FIG. 4 and lead there to a multitude of movable switching contacts 250 which are connected to an 8-foot flute register 252 and are moved by this. In addition to these movable flute contacts 250, the register flap 252 controls two outer movable contacts 254 which are connected to a ground line 257. All of these contacts 250 and 254 normally contact a solid, transverse shorting bar 256. As a result, all of the lines 248 are normally grounded. This prevents the alternating output voltages of the staccato anodes appearing at the various group connections 118 and reaching the loudspeaker - as long as the register key "flute" has not been moved to its open position; in which the grounding of lines 248 is removed.

According to this aside on the basis of FIG. 4 is the circuit according to F i g below. 3 will be explained further. Said lines 248 lead to a corresponding number of resistors 258, which in turn are led through lines 260 to the control grids of the triode parts 262 of special tubes which contain two triode systems. In the anode outlet of each of these tube systems there is a corresponding matched filter circuit 264; the outputs of all of these matched filters are connected to a common line 266, which in turn leads to a shielded cable 268 . As can be seen, each of these flute filters 264 maintains the output voltage of six staccato anodes, namely half an octave, with the exception of the connection of group 8 with filter number 8, which has 14 tones. Each filter only lets through the fundamental wave of the alternating voltage supplied to it and suppresses all higher harmonics.

As. one in FIG. 4 is located immediately to the right of leads 248 to a port 270; this connection leads to the manifold 76 in Fig. 1, which picks up the signals from the staccato anodes. The connection is over a resistor 272 grounded and via a line 274 to a fixed contact 276, which is assigned to the register flap 278 of the 8-foot trumpet register is. The associated movable contact 280 normally contacts a fixed one grounded contact 282, but can be moved away from this and with the aforementioned Contact 276 are brought into contact. This movable contact 280 is over a line 284, grounded through a resistor 286, to the control grids of the triode parts 262 associated with the second and fourth filters 264.

A line 288 also leads from the connection 270 to the fixed one Contact 290 of a flap switch, its movable contact 292 on the register flap 294 of an 8-foot oboe register and is controlled by this. This moving contact 292 normally contacts a grounded fixed contact 296, but can be removed from this and in contact with the aforementioned contact 290 when you operate the register flap 294. From the moving contact 292 leads a line 298 to the control grids of the vacuum tubes 262, which the filters Feed number 1 and 3 of filter group 264. This line 298 is through a resistor 300 derived from earth.

The lower part of FIG. 4 actually belongs next to the upper part of the circuit, but has been moved down and to the left to accommodate the whole circuit on the drawing sheet. As you can see, this part comprises three register keys that relate to the vibra, namely key 302 "Vibrato-On-Off", also key 304 "Vibrato Speed", and finally key 306 "Vibrato Depth", these three register keys connected to corresponding switches belonging to a vibrato oscillator 308 with an output line 310 . This vibrato oscillator and its connections are more or less conventional, so no detailed description is required. It should only be noted that the output 310 of this vibrato oscillator is connected directly to the vibrato manifold 48 which leads to the oscillator grids, as in FIG. 1 shown.

The following is now the in the lower left part of FIG. 3 and top left in FIG. 4 illustrated circuit part explained in more detail. At 312, an input signal is applied to a pedal amplifier 314 comprising two triode amplifier stages. There are foot switches on the organ console, and when they are pressed down, the corresponding switches switch the output sides of various main and secondary oscillators, especially in the lowest octave, to input 31.2 . As indicated at 316, the control grids of these two amplifier stages receive a negative grid bias of 22 volts from the amplifier, not shown.

The output of the two-stage amplifier 314 is coupled via a capacitor 318 and a line 320 to a frequency divider circuit 322 according to the usual design, the grid of which in turn receives blocking voltages of -134 volts, as shown at 323. The first Eccles-Jordan divider corresponds to a 16-foot pedal valve, while a second divider stage 324 divides again in the output of stage 322 and corresponds to an 8-foot pedal valve. A significant difference compared to conventional Eccles-Jordan circuits is that the second triode half of each divider circuit also has an extra anode, which is designated by 326 and 328, respectively. These triode halves provided with the additional anodes are constructed in the same way as the triodes described above for the individual oscillators and, in the practical implementation of the circuit, also represent one half of a tube of type 12 FO 8. These anodes are correspondingly with the opposite sides of a resistor -Capacitance network 330 connected, to which a positive voltage is applied at 332 as soon as a pedal is depressed to play a pedal tone. The anodes 326 and 328 are respectively connected at the filter 330 to output lines 334 and 336, which lead via appropriately sized resistors and capacitors to switches that are passed through a 16-foot pedal register flap 338 and an 8-foot pedal register flap 340 to be served. The switches are normally grounded and therefore short-circuit each output voltage of the aforementioned poppet circuits in this position. As soon as these switches, however, individually. or can be opened simultaneously, a Getting Connected from the lines 334 and 336 produced by an RC filter 342 to a switch which is controlled by a register damper 344 to turn off the pedal part. One of these two filter departments is then connected to a collecting line 346 to generate a "principal" voice or a "bass" voice, which leads to a line 348 and finally a connection 350- leading to the amplifier.

The line 346 is connected to ground via several switches and an associated resistor; These switches, which are controlled by the register flaps 352, 354 and 356, are used to influence the pedal volume and are labeled "full", "medium" and "weak" in the order mentioned above. There are also two other register keys, namely one, 358, labeled "Hold Pedal, On-Off" and another, 360, labeled "Hold Pedal, medium length". These flaps control corresponding switches, via which a line 362 which is led at 332 to the positive pole of the pedal supply voltage; either connects to ground via a resistor or disconnects from it. This has a corresponding effect on the voltage drop at this point.

The remaining register keys are connected to RC filters to shape the waveform of the various outputs of the tone generators. Thus the conductive insert of the rod of the upper manual (132 in FIG. 2) in the circuit in "FIG. 4" is led to an input terminal 364 which, via one of the aforementioned RC filters 366 : to a series of leads three switches, which are controlled accordingly from three register keys, namely a key 366 "Solo 16 feet"; -a key 368 "Bourdon 16 feet" and a key 370 "Trombone 16 feet." The switch of the key "Solo" separates just a resistor - from a voltage divider and thus increases the intensity of the 16-foot register, so that it can be used as a solo part if desired on the filter and connect directly to the connection 346 and consequently to the output 350.

Located immediately to the right of the aforementioned register flaps a register flap 372 "Solo 8 feet", which also shows the number of resistors in one part of the circuit changes and thereby causes the 8-foot register, if desired, can appear as a solo part.

The remaining 8-foot keys of the upper keyboard are supplied by the staccato signal line at 270, as already explained above with reference to the "trumpet" and "oboe" keys of the 8-foot register. These keys are labeled "Diapason" (the characteristic organ tone) and "Violin". These register flaps 374 and 376 each control switches which are switched on in an RC network 378 and either ground the signals of certain parts of this network or lead them to a connection 356 and thus to the output 350 .

A connection leads from the conductive insert 130 of the solid rod of the 51 /, foot manual in the upper part of the keyboard (FIG. 2) to the input connection 376, which in turn leads to an RC filter 378. The output of this RC filter is connected to a switch that is connected to a flap "Quint 51 /, foot" (380). A register flap 382 »Solo 51/3 feet« is also provided.

The conductive insert 128 of the solid rod of the 4-foot manual in the upper keyboard (FIG. 2) is led to a further RC filter 386 via the connection 384 (FIG. 4). This RC filter is connected to terminal 346 by a switch, the switch being connected by a register key 387 "orchestra flute." 4. "Foot" is controlled:: In addition, from input 384 via a. Switch established a corresponding connection, which is of a. Flap 388 "violin 4 feet" is controlled. Here, too, a solo key 390 with the designation "Solo 4 feet" is provided.

The conductive insert 184 of the fixed rod 182 of the 8-foot manual in the lower keyboard is connected to a further RC filter 394 via the input connection 392. Various switches are connected to this filter, namely a switch controlled by a flap 396 "Solo 8 foot" and others. Switches that - controlled by register keys 398, 400 and 402 - are labeled "Melodia 8 feet", "Cello 8 feet" and "Horn 8 feet" in the above order. In addition, a connection from the conductive liner 176 of the solid - rod. 174 of the 4-foot manual on the lower keyboard to an input connection 404 , which leads to an RC filter 406 . With -diesem RC: - switch connected by - rlter -F "three are where 4 feet" is controlled by a register of a flap 408 with the Product Name "Solo The other two switches lead to manifold 346 and - entsprechend.-. controlled by register keys 410 and 412 labeled "harmony flute" and "violin".

The output circuit of the electronic organ is described below as shown in Fig. -5. First, the alternating voltages passed by the RC filters are introduced at 350 into the first stage of a preamplifier 414 : for the sake of simplicity, reference numeral 350 is also shown in FIG. 4 has been used for the output terminal. The first stage of the preamplifier is followed by a second stage 416, at the input of which the tuned filter is connected via terminal 268 (see also FIG. 4). The input of this second preamplifier stage can be grounded via a resistor 418 and a switch 240, 244, which has already been mentioned above, whereby the overall volume of the organ can be reduced.

The output of the second stage of the preamplifier is connected to a power amplifier 422 via a potentiometer 420. This potentiometer 420 is controlled by the usual swell of the organ. Finally, a loudspeaker 424 is connected to the power amplifier or output amplifier 422. In Fig. 5, for the sake of simplicity, only one loudspeaker is shown. In practice, however, a whole group of loudspeakers will be used. With the help of the couplings described above, which rotate the various rotatable bars of the keyboard, it is possible, on the upper keyboard alone or in combination, the 16-foot pitch and the 4-foot pitch to the 8-foot voices, viz Flute, diapason, violin, trumpet and oboe, to play. You can also play the 8-foot voices of the upper keyboard on the lower keyboard in the 8-foot pitch, either alone or in combination with voices from the lower keyboard. This adds five more tones to the tones on the lower keyboard. You can also play some or all of the upper keyboard's 8-foot voices on the lower keyboard, or play a melody on the upper keyboard by using each voice in the 16-foot register, the 51 /, -ft register and / or the 4-foot register, but without using the timbres of the 8-foot register. In addition, you can operate the 8-foot solo flap in connection with the paddocks in the upper register and thus achieve increased intensity.

The coupling system provides ten additional individual timbres in different pitches to the already existing sound waves of the upper keyboard as well as five additional tones for the lower keyboard, each with two different ones Volumes. With the coupling for the upper 16-foot register you can when the melody is played on the 8-foot register of the upper keyboard, plus the one Octave lower, d. H. in the 16-foot register, tones of the same timbre produce.

With the coupling for the upper 4-foot register you can in the corresponding Way, when the melody is played on the 8-foot register, the same notes one Octave higher, d. H. play in the 4-foot register with the same timbre.

If you pull the tab "8-foot-off" in the upper keyboard, the 8-foot register of the upper keyboard is switched off. That is of use, though one of the 8-foot voices (flute, diapason, Violin, trumpet or oboe). This can be achieved by using the top paddock 16 feet is used and the upper register is turned off 8 feet, and / or by using the upper belt 4 feet used.

With the “up-down 8-foot” belt, you can switch to the 8-foot pitch of the lower keyboard link in all 8-foot registers of the upper keyboard. If you think about it In addition to turning off the upper 8-foot register, one can solo on the upper keyboard with voices of the 16-foot, 51 /, - and / or 4-foot register with accompaniment Play a voice on the lower keyboard, choosing the timbres of one of the voices of the upper 8-foot register is used.

As you can see, you can use the organ described above with Dual character create a wide variety of different effects. For every note Although only a single oscillator is provided, it has completely different ones and fully isolated outputs. The two output voltages will be then treated separately to achieve different effects, and then combined again in a common amplifier.

Claims (3)

Claims: 1. Electronic organ with master oscillators and Divider chains, with each divider oscillator having an output for the continuous tone and one Having output for the synchronization signal of the next divider stage, characterized in that that another output of the divider stage is blocked by a reverse voltage, which is eliminated by pressing a staccato key and delivers a staccato signal. 2. Electronic organ according to claim 1, characterized in that the continuous tone output (56, 114) of each oscillator via contacts (134) and busbars to one of a group of differently tuned RC filter supplies vibrations, while the staccato output (28, 86) of the same Only after a positive DC control voltage has been applied (at 66 and 91) the oscillator delivers oscillations to the associated filter via the associated staccato key, several staccato outputs preferably being grouped together. 3. Electronic organ according to claim 1 and 2, characterized by the use of an electron tube with a single control grid, a single cathode and two identical anodes for the oscillators, the one anode for the continuous tone, the other for the staccato tone. Into consideration drawn pamphlets: U.S. Patent Nos. 2,916,958, 2,918,576, 2,924,137; Alan D o u g 1 a s, "The Electronic Musical Instrument", London, 1957, 3rd edition; Publisher Sir Isaac Pitman and Sons, p. 65, Fig. 61, 62, p. 66, Fig. 63 and p. 67, Fig. 66.