DE1224826B - Tension adjusting device - Google Patents

Description

Tension Adjustment Device The invention is directed to a tension adjustment device with a single coil or autotransformer winding and a switching device, which is adjustably connected to the autotransformer winding to connect to a circuit between one end of the autotransformer winding and the switching device to apply a variable voltage, and with an adjustable one with the autotransformer winding connected second switching device.

Comparison circuits with the aid of autotransformers, in which the resulting secondary voltage is opposed to two primary voltages, are already known without, however, being able to be adjusted on the primary side.

In contrast, the voltage adjusting device according to the invention is distinguished characterized in that between the other end of the autotransformer winding and the second switching device, a second circuit is arranged that the two The two variable voltages applied to electrical circuits are constantly equal to one another and that in the two circuits the same of the variable voltages dependent currents flow.

According to another feature of the invention, there is the first circuit from a first primary winding and the second circuit from a second primary winding a multi-winding transformer, with the primary windings. have the same number of turns and in-phase voltages in the secondary winding induce.

If necessary, a pole reversing switch can be used to reverse the connection serve the autotransformer winding with a power source.

A particularly advantageous embodiment of the invention is characterized is characterized in that the autotransformer winding is annular and has diametrically opposite ends which are used for connection Serve to a power source that the two switching devices each from over the annular winding consists of moving contacts while two more over the annular winding movable contacts are provided to the other two Contacts are diametrically opposite, that further the transformer two more the same number of turns as the other two primary windings having primary windings has one between one end of the autotransformer winding and the one of the other two movable contacts and the other between the other End of the autotransformer winding and the other of the other two movable ones Contacts is connected, with the further primary windings in the secondary winding Induce voltages that are in phase with those in it through the other two primary windings induced voltages are.

The invention opens up another possibility through a further, Transformer having several windings with two further primary windings of the same number of turns as the other primary windings and one more Secondary winding with the same number of turns as the other secondary winding, one primary winding between one end of the autotransformer winding and the second switching device and its other primary winding between the other The end of the autotransformer winding and the first switching device is connected, these primary windings have in-phase voltages in the further secondary winding induce and the two secondary windings are in series with a power source and the voltages generated in the two secondary windings are in phase.

It is within the scope of the invention to have a main booster transformer winding for connection to a Main power source with a number of tapping points as well as through switching elements to the connection. of the secondary windings connected in series to a first pair of these adjacent tapping points and to switch one end of the secondary windings from the first pair to the one tapping point of the., second, pair to use, -. with the respective other tapping point of the two Pairs both have in common when the voltage in the secondary winding is in the range of the common tapping points is zero.

The first switching device can have a first number of tapping points between a central tapping point and the other end and a switching arrangement for the optional connection of these tapping points to a first terminal, while the second switching device also has a number of tapping points between the central tapping point and one end and likewise a switching arrangement for optional connection. This tapping point has a second terminal, and a polarity reversal switch, which of the first to switch - terminal of one;. ptr other primary winding - and the second terminal of the other "for a primary winding is used, when both terminals are connected to the central tapping point .

In a further advantageous embodiment of the invention, the voltage setting device provides an autotransformer winding for connection to a power source and a transformer, - whose - a primary winding is connected between the egg: ae end of the autotransformer winding and a contact movable via this and its secondary winding between the other end of the autotransformer winding. -and -.- one .. second -over -. the. Autotransformer winding. Movable contact is connected in series with a load, whereby the primary and secondary windings have the same number of turns, the voltages between each end of the autotransformer winding and the respective contact are the same and the primary and secondary windings are connected, that the power transferred by means of conductive connections # from the power transformer winding to the load # -transferred power der.-inductively between the primary and secondary windings on the -load-transmitted-power, .., - : -i # It is further within the scope of the Invention of an autotransformer winding zum.iAnschlüß.: - to, -a current source and a transformer, one of which is a primary winding-between the-rine end-of the autotransformer winding and a. is turned & over this movable contact and its secondary winding connected between the other end of the Spartransforniatorwicklung and a second z - on the autotransformer winding, movable contact -with a load connected in parallel with the actual, - wherein the primary and- have the same number of turns Sekundürwicklungen , the voltages between each end of the autotransformer winding and the respective contact equal - and the -primary and secondary windings- are connected in such a way that the% -of by means of a conductive connection. - the autotransformer winding transferred to the load. Power of the inductive between - the - primary - and secondary windings - - on the. - burden '. transferred power equals.-In connection with this- # measure, a balancing autotransformer winding can be used between the- secondary winding- second, contact, wAb # -, j - \ «ie load with-a middle tap point on * the balancing autotransformer winding and the other end of the autotransformer, gate winding is connected.

Further features, details and components of the invention emerge from the following description of several preferred embodiments as well as from the drawing. Here, FIG . 1 shows a simple embodiment of a transformer with double winding, FIG. 2 shows an autotransformer. F i g 3 shows a modified embodiment according to Fig 2, F i g 4 shows the arrangement according to F i g 1 for multiphase operation, -.... -, - JF 4 # gz, -5ie ine zandere> Austü li rungsfQrm nachFzi-.! g 1, insbesondere- for Anzgpftransformatoren, -. F i g. 6 - which, application of the arrangement --After F ig 1 at Ringre-gler and F i g a, 7 a further embodiment der--.... Invent # duxig, the. - both- - of :, ginem tapping transformer as well as of a-. R # egl (#r Gebraueli, macht .- "- # In -the individual - figures. Are- -.the same parts - with the same reference symbols, # - - - # -, 11 , The circuit of Fig. 1 comprises an autotransformer winding VCD -, and a pair of contacts: ar Cf-.l .. and C 2, where every contact with a - bare - rail on the - winding VC »can be moved ;, -. still one. Transformer ST with several windings with #two primary windings P 1 and P 2 and a secondary winding S.

- - The winding 17CD is: connected to - terminals! ": And N, which - are connected to voltage,., The primary winding P # 1,; # is connected between, the terminal N - and the contact C1, -. The Primary winding-P, 2 between the core Li. And # the contacts-t # C., 2.- The desired voltage is tapped between the terminals Q # 1.-and-02 of the secondary winding S. - - The Primary windings P-1, -and P-2- have the same number of turns, the contacts Cl- and. C2 are always arranged in such a way that the. to the primary windings P 1 and Rp 2 applied voltages are the same and #: these two primary winding so yorbunden, -that-in "of the secondary winding S induce additional stresses. - - - - - # # j - II - . It is known to apply a voltage to a load which is connected to the secondary winding of a two-coil transformer, the primary winding of which is between one end of one of the windings VCD of FIG . 1 and a winding similar to the contact C1 of FIG . 1 similar contact is switched. - - A simple investigation shows that. Advantage. the arrangement according to F i G.- 1 gegenüberAieser known arrangement, for a Iyei - given maximalen-, supplied to the load -Leistung is in the winding VCD ffießende maximum current half as large as #, DER, which in the winding. of the conventional type transformer Hera flows. The winding-YCD z can then be designed for Deng lower - maximal current - and it weighs more in different applications. profitability achieved for the second contact C2 and. the second primary winding P2 -. required expenses. - - For example, assuming a 400 V supply voltage, a z Spar 'or - single coil transformer, which can withstand a maximum current of 100, -Ampere, would be necessary to enable changes from 0 to 40 kVA, while with the circuit according to FIG. 1 the same change can be carried out by means of an autotransformer VCD, which draws a maximum current of 50 amperes.

The circuit according to FIG. 2 comprises an autotransformer winding, VCD and a pair of contacts C 1 and C 2, similar to the components of the circuit according to FIG. 1, as well as a transformer ST with a single . Primary winding P and a secondary winding S.

The winding VCD is connected to the terminals L and N , which are connected to voltage. The primary winding P is closed between the terminal L and the contact C 2, while the secondary winding S is connected to the terminal N and the contact C 1 . The output voltage is between terminals N and 0.

When the contacts C 1 and C 2 are arranged so that the output current component applied to the output terminal 0 via the contact C 1 is equal to the output current component transmitted to the output terminal 0 by induction between the primary winding P and the secondary winding S and the windings P and S continue to have the same number of turns, the maximum current flowing in the winding YCD for a given maximum power is again half as large as the current flowing in a conventional autotransformer winding. If the contacts C 1 and C 2 are always left in this position, the winding VCD can consequently be designed for this reduced current, and the same economy as that of the arrangement according to FIG. 1 reached.

In order to obtain in two approximately equal to the output terminal 0 scale output current components, a compensation coil is connected in an autotransformer having an average tapping point between a primary winding P and a contact C 1, wherein the middle tapping point with the output CD terminal 0 is connected.

The circuit according to FIG. 3 comprises an economy or single coil transformer, a winding VCD and a pair of contacts C 1 and C 2, which correspond to the corresponding components of the circuit according to FIG. 1 , and a transformer ST with a single primary winding P and a secondary winding S.

The winding YCD is connected to the voltage terminals L and N. The primary winding P is connected between the terminal L and the contact C2 , the secondary winding between the contact C 1 and the output terminal 0. The output voltage is applied to the terminals N and 0.

When the contact Cl is at the lower end of the winding VCD, the voltage generated between the contact C 1 and the terminal N is zero. The contact C 2 is at the top of the winding VCD ,. so the voltage applied to the primary winding P is also zero. If the primary winding P and the secondary winding S have the same number of turns and if the contacts C 1 and C 2 are each equidistant from the upper and lower end of the winding YCD, a voltage is generated between the contact C 1 and the terminal N that corresponds to that of that one which is applied to the primary winding P, and consequently is the same as that which is induced in the secondary winding S.

The secondary winding S is connected so that the voltage generated between the terminals N and 0 is twice that applied to the winding VCD.

It can be seen that the current flowing in the coil current at VCD same number of turns of the primary winding P and the secondary winding S is equal to that in a flowing N and 0-connected load between the terminals. Consequently, the winding VCD only needs to be designed for half the consumer load, and the same economy as that in the arrangement according to FIG. 2 scored.

The circuits of FIG. 2 and 3 have compared to the circle of FIG. 1 another benefit. When the circuits of FIG. 2 and 3 are arranged and operate as described above, the total power of the windings of each resting transformer ST corresponds to the maximum power applied to the load. The circuit according to FIG. 1 , however, requires a translormator ST with multiple windings, the total winding capacity of which must be twice as large as the maximum power applied to the load. On the other hand, the circuit according to FIG. 1 more adaptable than the circuits of FIG. 2 and 3, because the economy is independent of the number of turns of the secondary winding S, the primary windings Pl and P2 having the same number of turns.

F i g. 4 is the circuit diagram of a modification of the circuit according to FIG. 1 to generate an adjustable three-phase voltage. L # a, Lb, U and N are the input terminals and Oa. Oh, Oc and N are the output terminals of the three phases and the neutral wire. An autotransformer winding VCDa with the contacts C 1 a and C 2 a is connected between the terminals La and N via the pole reversing switch STf%. A primary winding Plig of a multi-winding transformer STa is connected to the contact CIA and one end of the winding VC & a, and a second primary winding P 2 a is connected to the contact C2a and the other end of the winding VCDa. The secondary winding S # a of the transformer STa is connected to the terminals La and Og. Moving contacts C1-a and C2a changes the induced voltage in secondary winding S # a- and thus regulates the voltage appearing between output terminals Oa and N.

The switch SW # a- is provided to connect the winding VCDa in either direction to the input terminals La and N in order to increase or decrease the output voltage appearing between the output terminals 0a and N by the same amount as the voltage induced in the secondary winding S # a.

The arrangement according to FIG. 4 is equipped with two additional autotransformer windings similar to winding VCDg, two additional transformers similar to transformer S7 # with multiple windings and two additional switches, the latter forming a three-phase switch SW with switch SWä.

The primary windings of the multi-turn transformers have the same number of turns over the associated primary windings will creates additional voltages in each secondary winding, and those on each autotransformer winding Slidable contacts are always arranged so that the on all primary windings applied voltages are the same.

The three-phase voltages occurring between the terminal N and the terminals 0a and Ob and Oc are changed by the same amount and in the same direction by actuating the movable contacts on the autotransformer windings or the three-phase pole reversing switch SW. It is evident that the achievable with this arrangement, efficiency is comparable to that obtained with the arrangement of FIG. 1 is achieved.

The circuit according to FIG. 5 is similar to the circuit according to FIG. 1, but differs from this in that it has a number of fixed tapping points on the autotransformer winding YCD. The taps A 4 and B 1 are arranged in the middle of the winding YCD, the taps A 3 and B 2 are equidistant from the center, the taps A 2 and B 3 are even further with the same distance and the taps A. 1 and B 4 are arranged furthest and also at the same distance from the center.

Contactors connect the tapping points to the primary windings P 1 and P 2 or P 2 and Pl of the transformer ST, which has several turns, when they are closed before the switch SW disconnects. The primary windings P1 and P2 have the same number of turns.

When the contactors connected to the tapping points A 4 and B 1 are closed, actuation of the corresponding contactors and the switch SW causes the same voltages to be applied to the primary windings P1 and P2. These voltages are changed by equal amounts between the minimum and the maximum. If the terminals L and N are connected to a current source, the desired voltage induced in the secondary winding S of the transformer at rest results at the output terminals 0 1 and 0 2.

Since the primary windings P1 and P2 have the same number of turns, each primary winding induces additional voltages in the secondary windings and the contactors are operated in such a way that the same voltages are always applied to the primary windings PI and P2, economic efficiency is achieved which is similar to that of the arrangement according to FIG . 1 corresponds. , The circuit of FIG. 6 is also that of FIG. 1 similar, but differs from the latter through the annular winding VCD. In essence, it comprises between the closed and KlemmenL N autotransformer windings two, wherein the winding comprises ycd respectively connected to the terminals L and N, opposing Abgreifvorrichtungen. The winding YCD is equipped with a first pair of diametrically opposite contacts C 1 and C 2 and a second pair of contacts C 3 and C 4 which are also opposite. The two pairs of contacts can be moved simultaneously in bare rails on the winding VCD in the opposite direction from the position in which the contacts Cl and C4 are connected to the part of the winding VCD that is connected to the terminal L, and the contacts C 2 and C 3 with the part of the winding VCD which is connected to the N terminal.

The circuit of FIG. 1 differs in the second place. 6 of which the FIG. 1 in that the stationary transformer ST is provided with four primary windings P1, a P2, P3 and P4, the winding P1 between the contact C1 and the terminalN, the winding P2 between the contact C2 and the terminalL, the winding P3 between the contact C3 and the terminalL and the winding P 4 between the contact C 4 and the terminal N is closed.

If the contacts C 1, C 2, C 3 and C 4 are brought into the position shown in the drawing, each of the voltages applied to the primary windings is half the voltage applied to the terminals L and N. Counterclockwise movement of contacts Cl and C2 and corresponding clockwise movement of contacts C 3 and C4 cause the voltages applied to the primary windings to grow steadily to a maximum, then steadily decrease to zero and then again evenly to one Grow maximum. This change in voltages continues as the contacts are rotated.

The primary windings again have the same number of turns, additional voltages are induced in the secondary winding by each primary winding, and the contacts C 1 to C 4 only need to be moved in the manner described above. It is one of the F i g. 1 equivalent economy achieved.

The arrangement shown in FIG. 7 comprises in principle two circuits according to FIG. 1 arranged in push-pull, the secondary windings being able to be connected in series via an electrical power source.

Upon closer inspection, the arrangement according to FIG. 7 a main tapping transformer winding TT with several tapping or tapping points and contacts, four of which are provided with the reference numerals A 1 to A 4 and by means of which tapping points * are alternately connected to the busbar CSA, while the remaining tapping points are connected to the busbar CSB. The arrangement further includes a pair of multi-turn transformers STA and STB, the secondary windings SA and SB of which are each connected in series with the busbars CSA and CSB. The connection between the two secondary windings is connected to output terminal 0 .

The transformers STA and STB each have a pair of primary windings PlA, P2A and PlB, P2B, each with the same number of turns. The first primary winding PlA of the transformer STA is connected to a first tap point at the upper end (as shown in FIG . 7 ) of the autotransformer winding VCD and a second tap point designed as a contact C1 movable via the winding VCD. The second primary winding P 2 A of the transformer STA is connected to a third tap, which is designed as a contact C2 movable via the winding VCD, and a fourth tap at the lower end of the autotransformer winding YCD. The primary windings of each multi-turn transformer STA and STB are connected in such a way that they induce additional voltages in the associated secondary winding.

The winding TT is connected to the terminals L and N , which are connected to a source of electrical power.

The operation of the circuit is as follows: When the winding TT is energized and the contacts A 1 and A 2 are closed, the voltage occurring in the lowest tap pair of the winding TT is transferred to the busbars CSA and CSB and consequently also to the two series-connected secondary windings SA and SB. A voltage proportional to the voltage of the busbars CSA and CSB is therefore induced in the two series-connected primary windings P1A and PIB, this voltage being transmitted to the autotransformer winding YCD.

If the contacts C 1 and C 2 are originally located at the lower and upper ends, respectively, of the winding VCD, the primary windings P 1 B and P 2 B are short-circuited and the primary windings P1A and P2A are connected to one another over the entire winding YCD. The voltage generated in winding SB is then equal to zero, and the potential of terminal 0 is the same as that of terminal N.

Then the contacts Cl and C2 are evenly shifted from the lower and upper ends of the winding VCD, respectively, to increase the voltages applied to the primary windings PIB and P2B evenly and to make the voltages applied to the primary windings P1A and P2A decrease evenly. Therefore, the voltage of the secondary winding SB increases and the voltage of the winding SA decreases by the same amount, the potential of the terminal 0 shifting from that of the terminal N to the tapping point of the winding TT to which the contact A 2 is connected.

A further movement of the contacts C 1 and C 2 brings about a further approximation of the potential of the terminal 0 to that of the tap connected to the contact A2, until the contacts C1 and C2 are respectively at the upper and lower end of the winding VCD are located, the potential of terminal 0 is equal to that of the tap connected to contact A 2.

Contact A 1 is now open and contact A 3 is closed. The contacts C 1 and C 2 are now shifted against their original direction of movement by equal amounts such that the voltages applied to the primary windings P1B and P2B decrease evenly and those applied to the primary windings P 1 A and P 2 A increase evenly. The potential of the terminal 0 thus gradually shifts from that of the tap connected to the contact A 2 to that of the tap connected to the contact A 3 .

When the potential of terminal 0 is equal to that of the tap connected to contact A 3 , contact A 2 is open and contact A 4 is closed. The contacts Cl and C2 are then moved in the original manner to the potential of the terminal of the gradually to the change connected to the contact A 4 0 A 3 connected to the contact of the tapping point.

From this it can be seen that the working sequence can be reversed in order to change the potential of the terminal 0- from that of the tap connected to the contact A 4 to that of the tap connected to the contact A 1. - - It can also be inferred from this that the arrangement according to FIG. 7 brings about an economy that is comparable to that of the arrangement according to FIG. 1 is comparable.

In this description. is the reference to a multiple windings having transformer with two primary windings and one secondary winding to understand that not only an arrangement with a single magnetic circuit, to which the three windings are connected, but also an equivalent electrical arrangement with two magnetic circuits, each magnetic circuit with one Primary and a secondary winding is equipped and in which the two secondary windings connected in series to be the equivalent for a single secondary winding form.

Claims (2)

Claims: 1. Voltage setting device with a single coil or autotransformer winding and a switching device that is adjustably connected to the autotransformer winding in order to apply a variable voltage to a circuit between one end of the autotransformer winding and the switching device, and with an adjustable voltage connected to the autotransformer winding Second switching device, characterized in that a second circuit is arranged between the other end of the autotransformer winding and the second switching device, that the two variable voltages applied to the two circuits are always the same and that the same currents depending on the variable voltages in the two circuits flow. 2. Voltage setting device according to claim 1, characterized in that the first circuit consists of a first primary winding and the second circuit consists of a second primary winding of a transformer having several windings, the primary windings having the same number of turns and inducing in-phase voltages in the secondary winding (F i g . 1). 3. Voltage setting device according to claim 2, characterized by a pole reversing switch (SWg) for reversing the connection of the autotransformer winding to a power source (F i g. 4). 4. Voltage setting device according to claim 2, characterized in that the autotransformer winding is annular and has diametrically opposite ends which are used for connection to a power source, that the two switching devices each consist of movable contacts over the annular winding, while two more over the annular winding are provided with movable contacts which are diametrically opposite the other two contacts, so that the transformer has two further primary windings with the same number of turns as the other two primary windings, one of which is between one end of the autotransformer winding and one of the two further movable contacts and the other of which is connected between the other end of the autotransformer winding and the other of the two further movable contacts, the further primary windings inducing voltages in the secondary winding which are in phase g to the voltages also induced therein in the other two primary windings (F i g. 6). 5. Voltage setting device according to claim 2, characterized by a further, several windings having transformer with two further primary windings of the same number of turns as the other primary windings and a further secondary winding of the same number of turns as the other secondary winding, one primary winding between the one End of the autotransformer winding and the second switching device and its other primary winding between the other end of the autotransformer winding and - * the 'first switching device is connected, these primary windings induce in-phase voltages in the further secondary winding and the two secondary windings are in series with a power source and the in the voltages generated by the two secondary windings are in phase (Fig . 7). 6. Voltage setting device according to claim 5, characterized by a Ha-äptspartransformatorwicklung for connection to - a main power source with a number of tapping points and by switching elements for connecting the series-connected secondary winding to a first pair of these adjacent tapping points and for switching one end of the secondary windings from the first pair to one tap point of a second pair, with the other. ' Tapping point of the two pairs is common to both when the voltage in the secondary winding in the area of the common tapping points: is zero '(FIG . 7). 7. Voltage adjusting device according to claim 1 or 2, characterized in that the first switching device has a first number of tapping points between a central tapping point and the other end and a Schaltanordnuna for optionally connecting these tapping points to a first terminal, while the second switching device also has a number of tapping points between the middle tapping point and one end and also a switching arrangement for the optional connection of these tapping points with a second terminal as well as a pole reversing switch, which is used to switch the first terminal from one to the other primary winding and the second . No. 598,454; German interpretative document No. 1025 062; French Patent Specification No. 832,467. USA. Patent No. 1,684,397. ETZ-A (1953), 18, p. 546. Terminal from the other to one primary winding is used when both terminals are connected to the central tapping point (Fig . 5). 8. Voltage setting device according to claim 1, characterized by an autotransformer winding for connection to a power source, a transformer, one primary winding of which is connected between one end of the autotransformer winding and a contact movable via this, and its secondary winding between the other end of the autotransformer winding and a second movable via the autotransformer winding contact is connected in series with a load, wherein the primary and secondary windings have the same number of turns, the voltages between each end of the autotransformer winding and the respective contact are the same and the primary and secondary windings are connected so that the means conductive connection from savings; transformer winding on the load transferred to the power inductively transferred between the primary and secondary windings on the load ( Fig. 3). 9. Voltage setting device according to claim 1, characterized by an autotransformer winding for connection to a power source, a transformer, one primary winding of which between one end of the autotransformer winding and a cone movable via this. clock is switched and the secondary winding between the other end of the autotransformer winding and a second movable via the autotransformer winding contact with a load is connected in parallel, the primary and secondary windings have the same number of turns, the voltages between. shy of each end of the autotransformer winding and the respective contact and the same. Primary and secondary windings are connected in such a way that the by means of a conductive connection of. the autotransformer winding on the load is the same as the inductively transferred between the primary and secondary windings on the load power ( Fig. 2), 10. Voltage setting device according to claim 9, characterized by a balancing autotransformer winding between the secondary winding and the second contact , the load being connected to a central tap point on the trimming autotransformer winding and the other end of the autotransformer winding (FIG . 2).