DE1226631B - Device for generating pulse trains, the pulses of which occur in an optionally adjustable phase position and polarity - Google Patents

Description

Device for generating pulse trains, the pulses of which occur in an optionally adjustable phase position and polarity . The invention relates to a device for generating pulses' the-en pulses in selectively adjustable phase angle and polarity occur with generation of pulses by sinusoidal voltages magnetically saturated transformers are supplied.

It is known to generate pulses of a predetermined frequency in that the primary winding is magnetically saturated. Transformer, a sinusoidal voltage corresponding frequency zugefüh, rt # wi rd, - are derived pulses - of whose amplitudes -begrenzt by the transformer and i at a secondary winding in shape. It is also known to generate a pulse sequence, the individual pulses of which are not,, equidistant, by alternating voltages of different frequencies, which are superimposed and limited. With devices of this type there is the disadvantage that the time intervals of individual pulses can only be changed within a pulse train in a numerical ratio that is given by the frequencies of the individual sinusoidal voltages. Any change in the time sequence of individual pulses could only be achieved with these devices by providing a sufficient number of signal voltages of different frequencies.

Pulse generator of the known type of the invention are in accordance improved by sinusoidal voltages of different phase position are derived to secondary windings of a multiphase transformer, and that a respective sine-wave voltage is connected to the primary winding of a transformer, the two secondary windings with opposite Ausgangsspannirngen Phas-enlage- having, each of which optionally can be connected via a directional conductor to an output line which is commonly assigned to all secondary windings of the transformers.

The measure mentioned has the advantage that it is made in a simple manner Sinusoidal voltages of the same frequency pulse trains are generated with their individual pulses can be set in any time sequence.

Embodiments of the invention are explained in more detail with reference to the figures explained.

The F i g. Figure 1 shows the six transformers 4, 5, 6, 7, 8 and 9, each of which has one primary winding and two secondary windings. The generated pulses are derived from the secondary windings of the transformers and fed to a common output line with terminals 100 and 102 via diodes. The pulses of an optionally adjustable time sequence are derived from these terminals. The primary windings of the six transformers are fed via lines A, B, C, D, E and F by a control generator, from which sinusoidal voltages of adjustable phase positions can be derived. A suitable control generator of this type is shown in FIG. 1. It consists of a polyphase transformer, on whose cores 10, 20 and 30 are in star. switched primary windings 11, 21 and 31 are arranged. These windings are fed by a three-phase voltage, the components of which have a mutual phase shift of 1201 '. The secondary windings 12, 22 and 32 of the transformer are connected in delta. The in F i g. Lines A to F shown in 1 are connected to the secondary windings of the transformer at six different end points, at which a six-phase voltage is derived. The voltages derived from lines A, C and E have a rigid phase position, while the phases of lines B, D and F can be adjusted using a sliding contact. The phase position of the six voltage components is determined by the vectors CA, EB, EC, AD, AE and. CF illustrates. . The transformers 4, 5, 6, 7, 8 and 9 are used as pulse generators, 'which are operated by the sinusoidal control voltages. The transformer 4 comprises a primary winding 41 and secondary windings 42 and 4 #, - which are arranged on a common core 40th The transformer 5 includes a primary winding 51 and secondary windings 52 and 53 which are arranged on the common core 50. The transformer 6 contains a primary winding 61 and secondary winding 62 and 63, which are arranged on the common core 60. The transformer 7 contains. the primary winding 71 and the secondary windings 72 and 73 arranged on the common core 70. The transformer 8 includes the primary winding 81 and the secondary windings 82 and 83, which are arranged on the common core 80. The transformer 9 contains the primary winding 91 and the secondary windings 92 and 93, which are arranged on the common none 90.

The none '40 , 50, 60, 70, 80 and 90, are magnetic - - saturated, - d ;. H.,. the primary windings of these transformers are excited by the sinusoidal control voltages in such a way that the amplitude values of the excited voltages extend far into the area of magnetic saturation. This control of the transformers has the consequence that pulses are generated in the secondary windings, which occur when the sinusoidal control voltages have a zero crossing. The polarity of these impulses depends on the winding direction, according to -dem .. the secondary windings are arranged on the cores of the transformers.

The primary winding 41 of the transformer 4 is connected to points A and E. The primary winding 51 of the transformer 5 is connected to the Puükt-A and 1-an adjustable contact D, the -. is arranged on the winding 32 of the control transformer. The primary winding 61 is connected to the points I and C. The primary winding 71 of the transformer 7. Is connected to the point I and the adjustable contact B, which is arranged on the winding 12 of the control transformer. The primary winding 81 of the transformer 8 is connected to points C and A. The primary winding 91 of the transformer 9 is connected to the point C and the adjustable contact F, which is arranged outside the winding 22 of the control generator ish springs of the transformers 4, 5, 6, 7, 8 and contains two secondary windings, which are connected to the core of one Transformer have opposite winding sense. It is assumed that the adjustable contacts B, D and F are set at the center points of the lugs 12, 22 and 32 of the control generator. The F i g. 3 shows the time course of these voltages under the assumption that the points: B, C and F are set at the midpoints of the corresponding windings.

From fig. 3 shows that the voltages in the direction of their time axis each have a zero crossing after 300 , and that two polarity changes of the voltages from negative to positive are followed by two polarity changes of the voltages from positive to negative. The voltage AE shows the control voltage which is fed to the primary winding 51 of the transformer 5. The voltage EC is the control voltage which is supplied to the primary winding 61 of the transformer 6. The tension. IB is the control voltage which is fed to the primary winding 71 of the transformer 7. The voltage CA is the control voltage applied to the primary winding 81 of the transformer g. is supplied. The voltage CF is the control voltage which is fed to the primary winding 91 of the transformer 9.

It is assumed that there is a change in the control voltages in the primary windings of the transformers from negative to positive in the. corresponding secondary windings 42, 52, 62, 72, 82 and 92 generated pulses of positive amplitude and that in these primary windings a change in the voltages from positive to negative in said secondary windings generates pulses of negative polarity. In contrast, the aforementioned control voltages of the primary windings in the secondary windings 43, 53, 63, 73, 83 and 93, which have opposite winding directions, produce pulses of opposite polarity.

The F i g. 4 shows a representation of the pulse sequences which arise in all secondary windings of the transformer 4, 5, 6, 7, 8 and 9 , and which are applied to the corresponding terminals 42-1, 43-1, 52-1, 53-1, 62-1, 63-1, 72-1, 73-1, 82-1, 83-1, 92-1 and 93-1 can be derived. From FIG. 4 it can be seen that a positive pulse is generated in winding 42 and a negative pulse is generated in winding 43 when the in FIG. 3 , the control voltage A Z7 shown at time 0 ' changes the polarity from negative to positive #. Likewise, the control voltage generated at the time-AD 301 in the winding 52 a positive pulse and a pulse in the winding negafiven 53rd In contrast, the control voltage CA generates at the time 60 ', when it undergoes a change in polarity from positive to negative, in the - ± orderly. Secondary winding 83 a positive and -in the associated secondary winding 82 a negative pulse. In this way, the in FIG. 3 generator voltages b; at their zero crossings, the pulse trains shown in FIG. 4 are shown. - The secondary windings of the transformers illustrated in Fig..1 can with the common output line 100, 102 wahIweise connected so that a desired time sequence is formed of pulses. According to the representation according to FIG . 1 , the diodes 104 are arranged in the output lines of the secondary windings 42, 43, 52, 53, 62, 63, etc. The forward direction of the diode 104 is selected so that the pulses of negative polarity are blocked, as a result of which positive pulses appear in the output line at time intervals of 30 'each. If these pulses are to have a negative polarity, it is only necessary to reverse the polarity of the diodes 104.

By switching the secondary windings of the transformers on and off, it is possible to create pulse trains of any type in the common output line. If z. B. a sequence of positive pulses with the time intervals of 60 'is desired, so every second secondary winding can be separated from the common output line for this purpose, so that only the windings 42, 83, 62, 43, 82 and 63 for the generation of the pulses are effective.

The apparatus has been described with the assumption that adjustable contacts B, D and F at - the centers of windings 12, 22 and 32 have been adjusted. This resulted in a pulse train with individual pulses that were 301 apart in time. By having points B, D and F on the windings. of the control generator are arranged to be adjustable, there is also the possibility of generating pulse trains that have any time sequence.

Let it be B. suppose that the part DE of the winding 32 is three times as large as the part * DC. It is also assumed that the part BC of the winding, 12 makes up one third of the length of the part BA, and that the part FE of the winding 22 is twice larger than the part FA. With this arrangement, voltages with phase positions as shown in FIG. 1 arise in the primary windings of the pulse generators . 5 are shown. This illustration shows that the zero crossings of the individual control voltages occur at times 0, 45, 60, 80, 120, 135, 180, 225, 240, 260, 300, 315 and 3601. The pulses generated by these control voltages in the corresponding secondary windings are generated are shown in FIG. 6 . These pulse series have different time sequences than those shown in FIG . 4 are shown. In this case, too, by connecting and disconnecting the secondary windings of the transformers in the common output line, pulse sequences of the desired type can be put together. From this it can be seen that a large number of pulse trains of the desired time sequence can be formed by predetermined settings of the points B, D and F.

In the present exemplary embodiments, the transformers 4, 5, 6, 7, 8 and 9 are operated by six control voltages with different phase positions. These six control voltages were derived from a three-phase system. However, there is also the possibility of operating such a device in such a way that any n-phase voltage is converted into an m-phase control voltage in order to operate the pulse generators according to the principles of the exemplary embodiments described.

Claims (2)

Claims: 1. Device for generating pulse trains, the pulses of which occur in an optionally adjustable phase position and polarity, with generation of the pulses by sinusoidal voltages which are fed to magnetically saturated transformers, characterized in that secondary windings (12, 22, 32) of a polyphase transformer sinusoidal voltages of different phase position are derived and that a respective sine-wave voltage is connected to the primary winding of a transformer (4 to 9), the two secondary windings (42, 43 ... 92, 93) having opposite output voltages phase position, each of which optionally via a Directional conductor (104) can be connected to an output line (100, 102) assigned to all secondary windings of the transformers. 2. Device according to claim 1, characterized in that the sinusoidal voltages of triangular-connected secondary windings of a three-phase transformer are derived, from which three sinusoidal voltages of rigid phase position at the triangle points of the circuit and three sinusoidal voltages of variable phase position are derived at adjustable tapping points of the windings.