CA1120542A - Ferroresonant voltage regulator incorporating auxiliary winding for large current magnitudes of short duration - Google Patents
Ferroresonant voltage regulator incorporating auxiliary winding for large current magnitudes of short durationInfo
- Publication number
- CA1120542A CA1120542A CA000307210A CA307210A CA1120542A CA 1120542 A CA1120542 A CA 1120542A CA 000307210 A CA000307210 A CA 000307210A CA 307210 A CA307210 A CA 307210A CA 1120542 A CA1120542 A CA 1120542A
- Authority
- CA
- Canada
- Prior art keywords
- load
- state
- switch means
- winding
- voltage regulator
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
Landscapes
- Control Of Electrical Variables (AREA)
Abstract
FERRORESONANT VOLTAGE REGULATOR INCORPORATING AUXILIARY
WINDING FOR LARGE CURRENT MAGNITUDES OF SHORT DURATION
Abstract of the Disclosure The present invention incorporates an auxiliary winding in a ferroresonant voltage regulating transformer. The transformer is controlled in such a manner that, during start-up of a load connected to the transformer, the auxiliary winding provides all the current for the load, and after the initial start-up period of the load, the auxiliary winding is disconnected from the load and the normal secondary winding of the ferroresonant transformer supplies all the current to the load. It should be noted that the auxiliary winding is constructed so that (in theory) all the flux from the auxiliary winding is linked with the primary winding, and all the flux from the primary winding is linked with the auxiliary winding.
- i -
WINDING FOR LARGE CURRENT MAGNITUDES OF SHORT DURATION
Abstract of the Disclosure The present invention incorporates an auxiliary winding in a ferroresonant voltage regulating transformer. The transformer is controlled in such a manner that, during start-up of a load connected to the transformer, the auxiliary winding provides all the current for the load, and after the initial start-up period of the load, the auxiliary winding is disconnected from the load and the normal secondary winding of the ferroresonant transformer supplies all the current to the load. It should be noted that the auxiliary winding is constructed so that (in theory) all the flux from the auxiliary winding is linked with the primary winding, and all the flux from the primary winding is linked with the auxiliary winding.
- i -
Description
~2~*~
This invention relates generally to ferroresonant voltage regulating circuits and more particularly to a ferroresonant ~(~X/ /~ .~ ry voltage regulator having an auxilliary winding which is employed to provide short-term, unregulated current, of greater magnitude than that normally provided by the ferroresonant regulator.
Ferroresonant constant-voltage transformers are well known in the prior art, as evidenced by the following United States patents: United States patent no. 2,143,745 dated January 10, 1939 to Joseph G. Sola, United States patent no. 2,694,177 dated November 9, 1954 to Joseph G. Sola, United States patent no. 3,315,151 dated April 18, 1967 to F.A. Wentworth; United States patent 3,293,~37 dated December 20, 19~6 to Joseph G. Solaj United States patent no.
3,573,605 dated April 6, 1971 to H.P. Hart and R.J. Kakalec; and United States patent no. 4,088,942 dated May 9, 1978 to S. Miko. The preceding patents depict various core and winding configurations found in the prior art for ferroresonant transformers or regulators. In addition to the precediny patents, a good explanation of the operation of ferroresonance is given in a brochure entitled: "A Practical Approach to Understanding Ferroresonance" by H.C. Gerdes and W.E. Lucarz and distributed as Bulletin No. L-550 by Thomas and Skinner, Inc., Indianapolis, Indiana, U.S.A. This brochure was reprinted from the April 1966 issue of EEE The magazine of Circuit Design Engineering.
One inherent characteristic of ferroresonant constant-voltage transformers is that the output current is limited by the leakage inductance between the primary and`secondary windings. At times this current limiting characteristic can be an advantage~ making further over-current protection unnecessary. At other times, this current limiting characteristic can be a distinct disadvantage; For exam~le, when starting an electric motor much more current is required for the start-up of the motor than is required during the steady-state ~.~;2a5~2 operat;on of the motor and the inherent current limiting character;stic of a ferroresonant transformer means that some method must be employed to provide the required starting current.
Prior art solutions to the problem of providing adequate starting current for loads such as electric motors have been to design a ferroresonant transformer having an ou~put current capacity in excess of the maximum starting current required For the load. This results in a ferroresonant transformer that has an output current handling capability that is very much greater than that required for the steady-state operation of the load. For an electric motor the start-up (or surge) current may be up to eight times the magnitude of the steady-state current. To make a ferroresonant transformer of sufficient capacity to handle the start-up current means a transformer larger in physical size than one designed to handle only the steady-state load and it also means that the inherent current limiting property of ferroresonant transformers cannot be taken advantage of~ except in cases oF extreme overload.
The present invention overcomes the problems o~ the prior art by providing an auxlliary winding on the ferroresonant transformer and controlling the transformer in such a manner that, during start-up of a load connected to the transformer, the auxiliary winding provides all the current for the load, and after the initial start-up period of the load, the auxiliary winding is disconnected from the load and the normal secondary winding of the ferroresonant transformer supplies all the current to the load.
Stated in other terms, the present invention is a voltage regulator for an alternating current (AC) load, the voltage regulator comprising:
a ~erroresonant transformer having a primary winding for connection to a source of AC power, a secondary winding for '~ ,,~
selective connectlon to the AC load, and an auxiliary winding for selective connection to the AC load whereby the auxiliary winding is closely coupled to the primary winding; a switch means for selectively connecting the auxiliary winding to the AC load for providing power to the load when the switch means is in a first state, and the switch means selectively connecting the secondary winding -to the AC load for providing power to the load when the switch means is in a second state, the switch means being responsive to the state of the load such that when the load is unenergized, and for a predetermined time period after the load is energized, the switch means is in its first state, and after the predetermined time period and for as long as the load remains continuously energized, the switch means is in its second state.
Stated in yet other terms, the present invention is a voltage regulator comprising a ferroresonant transformer for supplying regulated AC voltage to a load7 wherein the ferroresonant transformer comprises a primary winding, a secondary winding, and a capacitance means connected across the secondary winding, the regulator characterized by: an auxiliary winding wound on the ferroresonant transformer such that, ideally, all the flux linking the primary winding of the transformer also links the auxiliary winding, and vice-versa, a switch means for selectively connecting either the auxiliary winding or the secondary winding of the transformer across the load, a control means controlling the switch means in such a manner that when no current is being supplied to the load, and for a predetermined time period after power is applied to the load, the switch means connects the auxiliary winding to the load, and after the predetermined time period the switch means is activated to disconnect the auxiliary winding from the load, and to connect the secondary winding to the load.
Stated in still another manner, the present invention is a voltage regulator for an AC load, the voltage regulator comprising:
5~
a ferroresonant transformer having a primary windiny For connection to a source of ~C power, a secondary wind;ng for selective connection to the AC load, and an auxiliary winding for selective connection to the AC load, whereby the auxiliary winding is closely coupled to the primary winding, a control means being responsive to the state of the load such that when the load is unenergized, and for a predetermined time period after the load is energized, the control means being in a first state, and after the predetermined time period, and for as long as the load continues to be energized, the control means being in a second state; a switch means for selectively connecting only the auxiliary winding to the AC load to provide power to the load when the switch means is in a first state, and the switch means selectively connecting only the secondary winding to the ~C load to provide power to the load when the switch means is in a second state; the switch means being responsive to an output of the control means such that when the control means is in its first state the swi-tch means is in its first state and when the control means is in its second state the switch means is in its second state.
The invention will now be described in more detail wikh reference to the accompany;ng clrawings, wherein l;ke parts in each of the several figures are identified by the same reference character, and wherein:
Figure 1 is a simplified block-schematic diagram of the preferred embodiment of the invention;
Figure 2 is a simplified schematic diagram of a portion of Figure 1, and Figure 3 ~appearing on the same sheet as Figure 1) is a simplified block diagram of an alternative embodiment of the invention.
Figure 1 depicts a simplified block-schematic diagram of the preferred embodiment of the invention. The interconnection of the various components is as shown in Figure 1 and atten~ion is directed ~21~S~2 to that Figure.
In Figure 1 ferroresonant transFormer 10 comprises a primary winding 11, a secondary winding 12 and an auxilliary winding 13 all wound on a ferromagnetic core 14. A magnetic shunt, a portion of core 1~, is indicated at 15. It should be noted that, ideally, all the cr ~ r,~
flux linking primary winding 11 also links-}~*~r~ winding 13, and vice-versa. Because of magnetic shunt 15, the flux from secondary winding 12 is not completely linked with windings 11 and 13, but rather, some of the flux from winding 12 is shunted via magnetic shunt 15; similarly some of the flux from windings 11 and 13 is shunted by magnetic shunt 15 and consequently not all of the flux from windings 11 and 13 links with winding 12. Since winding 13 is employed for only a short time period it can be constructed of a smaller gauge wire than would otherwise be possible. In one embodiment constructed by the applicant, winding 13 (designed to carry 20 amperes~
was made of No. 17 AWG (American Wire Gauge) wire rather than the No. 11 or 12 AWG wire that would be required for a continuous duty wlndiny.
Wln(iing 11 has a centre tap 16 and the winding 11 is supplied with AC power by inverter 22 from battery 17 via Silicon Controlled Rectifiers (SCRs) 18 and 19. SCRs 18 and 19 are operated as a standard push-pull square wave inverter with an output frequency of 60Hz. Capacitor 20 and inductor 21 are used to commutate the SCRs 18 and 19 of inverter 22. The firing of SCRs 18 and 19 is achieved by means no~ shown, in a conventional manner. As inverter 22 is of a type well known in the art, and as it is ancillary to the actual invention being described herein, it is not deemed necessary to describe it in more detail. In the embodiment being described battery 17 has a potential of approximately 48 volts DC and the output of inverter 22 (between tap 16 and one of the ends of winding Il) is approximately ~z~
120 volts AC at 60 Hz~
Secondary winding 12 has a tap 23 and ends 2~ and 25.
The series combination of inductor 26 and capacitor 27 is connected across the ends 24 and 25. The series combination of capacitor 27 and inductor 26 is resonant at 240 Hz and is therefore capacitive at the frequency of operation i.e. 60 ~Iz. A capacitance such as this across the secondary winding of a ferroresonant transformer is wel1 known. In the embodiment of Figure l a voltage of approximately 600 volts is developed between the ends 24 and 25. The voltage between tap 23 and end 25 (which is the voltage to be applied to load 28) is approximately 120 volts.
As can be seen from Figure 1, when switch 29 is in the position shown ~terminal A connected to terminal B), ~
winding 13 is connected across the load 28, and is therfore supplying power to load 28, assuming on-off switch 30 is c1Osed. When switch 29 is in its alternate position (i.e. terminal A connected to terminal C) a portion of secondary winding 12 is connected across the load 28, and is therefore supplying power to load 28, assuming on-off switch 30 is closed.
Transformer 31 is employed as a current transformer which develops a signal on its secondary winding (to which control circuitry 32 is responsive) indicative of the magnitude of the current flowing through load 28. When no current is flowing through load 28, and for a predetermined time period after current starts to flow through load 28~ control circuitry 32 is in a first state. A-fter the predetermined time period control circuitry 32 is in a second state.
Switch 29 likewise has two states and is responsive to control circuitry 32 as indicated symbolically via the dashed line interconnection 33.
When control circuitry 32 is in its first state, switch 29 is likewise in its first state which is as shown in Figure l, i.e. terminal A
~z~
connected to terminal B. When control circuitry 32 is in its second state, switch 29 is likewise in its second state wh;ch is terminal A
connected to terminal C.
In actual fact, the preferred embodiment employs a solid-state switch for switch 29j but in order to make the swi-tch 29 and its operation easier to visualize it has been shown in Figure 1 as a simplified mechanical switch 29 with its control link from control circuitry 32 indicated as a dashed line interconnection 33. The simplified circuitry of the preferred switch 29 along with the preferred control circuitry 32 and preferred interconnection 33 is depicted in Figure 2 to be discussed later.
The operation of Figure 1 will now be described briefly. Inverter 22 is assumed to be already functioning. When on-off switch 30 is in its open position, as showng no current Flows through load 28 and consequently both control circuitry 32 and switch 29 are in their first states and switch 29 is in the positior shown in Figure 1. When on-off switch 30 is closed current (from q ,,"" /, ~ ~ ~f h~ winding 13) Plows through load 28 and is sensed by control circuitry 32 via transformer 31. Once current begins to flow through load 28 control circuitry 32 remains in its first state for a pre-determined time period. Consequently switch 29 remains in its first ry state, as is depicted in Figure 1 and ~UHH~ P~ winding 13 remains connected across load 28 and is supplying power thereto. After this predetermined time period (e.g. 0.8 seconds~ has elapsed, control circuitry 32 changes to its second state thereby causing switch 29 to change to its second state which results in terminal A being connected to terminal C. The effect of this is that now a portion of secondary winding 12 is connected across load 28 to supply power thereto.
The preferred embodiment of Figure 1 was designed to 5~
power a load 28 which ;s an electric motor. For this part;cular application the predetermined delay time in -the change of states of control circuitry 32 is approximately 0.8 seconds. The actual delay in the implementation of Figure l will depend upon the start;ng characteristics of the load 28. According to the spirit of this invention the idea is to employ the ~*~ y' winding 13 to supply power to load 28 during starting thereof when larger than steady~state currents are required~ and then to employ the normal secondary winding 12 of the ferroresonant transformer lO when the current drawn is approx-imately that of the steady-state condition.
Figure 2, depicting the preferred embodiment of switch 29, control circuitry 32, and interconnection 33 ;n simplified form will now be discussed. The interconnection of the various components is as shown in Figure 2 and attent;on is directed to that Figure.
Diodes 36, 37, 38 and 39 are connected to terminals 34 and 35 in the form oF a standard bridge rectifier. When there is current flowing through load 28 (Figure l) a voltage is developed across capacitor 40 v;a transFormer 31 and diodes 36, 37, 38 and 39.
When the current in the secondary winding of transformer 31 reaches approximately 175 milliamperes (mA), the voltage across capacitor 4 is o-f sufficient magnitude to turn off transistor 46. Diodes 42 and 43 protec~ the base of transistor 46 from excessive voltage magnitude on capacitor 40 due to large currents sensed by transformer 31.
Once transistor 46 is turned off, the voltage across capacitor 49 begins to increase in magnitude as it becomes charged via resistor 47. After a delay of approximately 0.8 seconds (since capacitor 49 began to charge), the voltage applied to the inverting (-) input of operational amplifier 54 is of sufficient magnitude to cause the output of amplifier 54 to change to a low (i.e. approximately -l volt) voltage value From its previous high value (near -12 volts).
This results in capacitor 59 being immediately discharged by diode 58, and the output of operational amplifier 61 is switched to a low voltage level (approximately -1 volt). The fact that the output of amplifier 61 is low means that light emitting diode (LED) 73 is not emitting light and consequently TRIAC (bidirectional triode thyristor) 75 is turned off. Additionally, diode 6g is no longer supplying bias to capacitor 67, and consequently capacitor 67 discharges via resistor 66.
After a short delay (until capacitor 67 has discharged sufficiently), of sufficient length to prevent any possibility of both TRIAC 75 and TRIAC 76 being on simultaneously, the output of operational amplifier 69 switches high (i.e. approximately -12 volts).
This turns on LED 78 causing it to emit light and thereby cause TRIAC 76 to be turned on and conducting.
When the magnitude of the current in the secondary winding of transFormer 31 falls below approximately 175 ~A., transistor ~6 turns on and consequen~ly capacitor ~9 discharges. The output of operational amplifier 5~ switches to a high voltage level (approximately ~12 volts) causing capacitor 67 to become charged via diode 68, and the output of operational amplifier 69 switches to a low voltage level (approximately -1 volt) ultimately causing TRIAC 76 to be non-conducting. After a short delay (caused by capacitor 67 charging to a sufficient voltage level) capacitor 59 becomes charged via resistor 55, and the output of operational amplifier 61 switches to a high voltage level, causing LED 73 to turn on and emit light, and ultimately cause TRIAC 75 to be in the conducting mode. The delay in turning on LED 73, caused by the fact that capacitor 67 must first become charged, ensures that both TRIAC 75 and TRiAC 76 are not both conducting at the same time.
It should be noted that operational amplifiers 54, 61 and 69 are of the type manufactured by Texas Instruments and referred Z~5~
to by the manufacturer as ~A747.
The preceding description of Figures 1 and 2 has been a description of the preferred embodiment of the invention, as envisioned by the inventor for one particular application. Various and sundry modifications can be made to the preferred embodiment described herein. Some of these modifications which are deemed to be within the scope of the invention, are described in the following section.
Figure 3 is a variation of the circuit shown in Figure 1.
In Figure 39 the voltage across load 28 is sensed rather than the current through load 28 (as is depicted in Figure 1). In Figure 3, the switch 29 and load 28 are interconnected in the same fashion as shown in Figure 1. The difference in Figure 3 is that the control circuitry 32 is in series with resistor 80 and the combination of circuitry 32 and resistor 80 is connected across load 2~ as shown in Figure 3. The purpose of resistor ~0 is to act as a voltage dropping resistance so that the range of voltages (and consequently currents) appearing between terminals 34 and 35 in the Figure 3 configuration is approximately the same as the range oF voltages (and currents) appearing between terminals 34 and 35 in the Figure 1 configuration. Control circuitry 32, interconnection 33 and switch 29 ~ :
are the same and operate the same in the Figure 3 configuration as they did in the Figure 1 configuration.
Additionally, instead of the electronic control circuitry 32 of Figure 3, a standard relay could be employed. The coil of the relay would be connected across the load 28 and the contacts of the relay would be connected so as to duplicate the switching function performed by switch 29 of Figure 3.
In essence3 in Figure 1, control circuitry 32 is designed to begin timing once switch 30 is closed, and after a predetermined time period, switch 29 is caused to change its state )5~Z
from that shown in Figure 1 to its alternate state, via interconnection 33. An alternative to this would be to monitor the magnitude of the current and when the current reaches approximately its steady-state magnitude (or any other desired magnitude), switch 29 is caused to operate.
This invention relates generally to ferroresonant voltage regulating circuits and more particularly to a ferroresonant ~(~X/ /~ .~ ry voltage regulator having an auxilliary winding which is employed to provide short-term, unregulated current, of greater magnitude than that normally provided by the ferroresonant regulator.
Ferroresonant constant-voltage transformers are well known in the prior art, as evidenced by the following United States patents: United States patent no. 2,143,745 dated January 10, 1939 to Joseph G. Sola, United States patent no. 2,694,177 dated November 9, 1954 to Joseph G. Sola, United States patent no. 3,315,151 dated April 18, 1967 to F.A. Wentworth; United States patent 3,293,~37 dated December 20, 19~6 to Joseph G. Solaj United States patent no.
3,573,605 dated April 6, 1971 to H.P. Hart and R.J. Kakalec; and United States patent no. 4,088,942 dated May 9, 1978 to S. Miko. The preceding patents depict various core and winding configurations found in the prior art for ferroresonant transformers or regulators. In addition to the precediny patents, a good explanation of the operation of ferroresonance is given in a brochure entitled: "A Practical Approach to Understanding Ferroresonance" by H.C. Gerdes and W.E. Lucarz and distributed as Bulletin No. L-550 by Thomas and Skinner, Inc., Indianapolis, Indiana, U.S.A. This brochure was reprinted from the April 1966 issue of EEE The magazine of Circuit Design Engineering.
One inherent characteristic of ferroresonant constant-voltage transformers is that the output current is limited by the leakage inductance between the primary and`secondary windings. At times this current limiting characteristic can be an advantage~ making further over-current protection unnecessary. At other times, this current limiting characteristic can be a distinct disadvantage; For exam~le, when starting an electric motor much more current is required for the start-up of the motor than is required during the steady-state ~.~;2a5~2 operat;on of the motor and the inherent current limiting character;stic of a ferroresonant transformer means that some method must be employed to provide the required starting current.
Prior art solutions to the problem of providing adequate starting current for loads such as electric motors have been to design a ferroresonant transformer having an ou~put current capacity in excess of the maximum starting current required For the load. This results in a ferroresonant transformer that has an output current handling capability that is very much greater than that required for the steady-state operation of the load. For an electric motor the start-up (or surge) current may be up to eight times the magnitude of the steady-state current. To make a ferroresonant transformer of sufficient capacity to handle the start-up current means a transformer larger in physical size than one designed to handle only the steady-state load and it also means that the inherent current limiting property of ferroresonant transformers cannot be taken advantage of~ except in cases oF extreme overload.
The present invention overcomes the problems o~ the prior art by providing an auxlliary winding on the ferroresonant transformer and controlling the transformer in such a manner that, during start-up of a load connected to the transformer, the auxiliary winding provides all the current for the load, and after the initial start-up period of the load, the auxiliary winding is disconnected from the load and the normal secondary winding of the ferroresonant transformer supplies all the current to the load.
Stated in other terms, the present invention is a voltage regulator for an alternating current (AC) load, the voltage regulator comprising:
a ~erroresonant transformer having a primary winding for connection to a source of AC power, a secondary winding for '~ ,,~
selective connectlon to the AC load, and an auxiliary winding for selective connection to the AC load whereby the auxiliary winding is closely coupled to the primary winding; a switch means for selectively connecting the auxiliary winding to the AC load for providing power to the load when the switch means is in a first state, and the switch means selectively connecting the secondary winding -to the AC load for providing power to the load when the switch means is in a second state, the switch means being responsive to the state of the load such that when the load is unenergized, and for a predetermined time period after the load is energized, the switch means is in its first state, and after the predetermined time period and for as long as the load remains continuously energized, the switch means is in its second state.
Stated in yet other terms, the present invention is a voltage regulator comprising a ferroresonant transformer for supplying regulated AC voltage to a load7 wherein the ferroresonant transformer comprises a primary winding, a secondary winding, and a capacitance means connected across the secondary winding, the regulator characterized by: an auxiliary winding wound on the ferroresonant transformer such that, ideally, all the flux linking the primary winding of the transformer also links the auxiliary winding, and vice-versa, a switch means for selectively connecting either the auxiliary winding or the secondary winding of the transformer across the load, a control means controlling the switch means in such a manner that when no current is being supplied to the load, and for a predetermined time period after power is applied to the load, the switch means connects the auxiliary winding to the load, and after the predetermined time period the switch means is activated to disconnect the auxiliary winding from the load, and to connect the secondary winding to the load.
Stated in still another manner, the present invention is a voltage regulator for an AC load, the voltage regulator comprising:
5~
a ferroresonant transformer having a primary windiny For connection to a source of ~C power, a secondary wind;ng for selective connection to the AC load, and an auxiliary winding for selective connection to the AC load, whereby the auxiliary winding is closely coupled to the primary winding, a control means being responsive to the state of the load such that when the load is unenergized, and for a predetermined time period after the load is energized, the control means being in a first state, and after the predetermined time period, and for as long as the load continues to be energized, the control means being in a second state; a switch means for selectively connecting only the auxiliary winding to the AC load to provide power to the load when the switch means is in a first state, and the switch means selectively connecting only the secondary winding to the ~C load to provide power to the load when the switch means is in a second state; the switch means being responsive to an output of the control means such that when the control means is in its first state the swi-tch means is in its first state and when the control means is in its second state the switch means is in its second state.
The invention will now be described in more detail wikh reference to the accompany;ng clrawings, wherein l;ke parts in each of the several figures are identified by the same reference character, and wherein:
Figure 1 is a simplified block-schematic diagram of the preferred embodiment of the invention;
Figure 2 is a simplified schematic diagram of a portion of Figure 1, and Figure 3 ~appearing on the same sheet as Figure 1) is a simplified block diagram of an alternative embodiment of the invention.
Figure 1 depicts a simplified block-schematic diagram of the preferred embodiment of the invention. The interconnection of the various components is as shown in Figure 1 and atten~ion is directed ~21~S~2 to that Figure.
In Figure 1 ferroresonant transFormer 10 comprises a primary winding 11, a secondary winding 12 and an auxilliary winding 13 all wound on a ferromagnetic core 14. A magnetic shunt, a portion of core 1~, is indicated at 15. It should be noted that, ideally, all the cr ~ r,~
flux linking primary winding 11 also links-}~*~r~ winding 13, and vice-versa. Because of magnetic shunt 15, the flux from secondary winding 12 is not completely linked with windings 11 and 13, but rather, some of the flux from winding 12 is shunted via magnetic shunt 15; similarly some of the flux from windings 11 and 13 is shunted by magnetic shunt 15 and consequently not all of the flux from windings 11 and 13 links with winding 12. Since winding 13 is employed for only a short time period it can be constructed of a smaller gauge wire than would otherwise be possible. In one embodiment constructed by the applicant, winding 13 (designed to carry 20 amperes~
was made of No. 17 AWG (American Wire Gauge) wire rather than the No. 11 or 12 AWG wire that would be required for a continuous duty wlndiny.
Wln(iing 11 has a centre tap 16 and the winding 11 is supplied with AC power by inverter 22 from battery 17 via Silicon Controlled Rectifiers (SCRs) 18 and 19. SCRs 18 and 19 are operated as a standard push-pull square wave inverter with an output frequency of 60Hz. Capacitor 20 and inductor 21 are used to commutate the SCRs 18 and 19 of inverter 22. The firing of SCRs 18 and 19 is achieved by means no~ shown, in a conventional manner. As inverter 22 is of a type well known in the art, and as it is ancillary to the actual invention being described herein, it is not deemed necessary to describe it in more detail. In the embodiment being described battery 17 has a potential of approximately 48 volts DC and the output of inverter 22 (between tap 16 and one of the ends of winding Il) is approximately ~z~
120 volts AC at 60 Hz~
Secondary winding 12 has a tap 23 and ends 2~ and 25.
The series combination of inductor 26 and capacitor 27 is connected across the ends 24 and 25. The series combination of capacitor 27 and inductor 26 is resonant at 240 Hz and is therefore capacitive at the frequency of operation i.e. 60 ~Iz. A capacitance such as this across the secondary winding of a ferroresonant transformer is wel1 known. In the embodiment of Figure l a voltage of approximately 600 volts is developed between the ends 24 and 25. The voltage between tap 23 and end 25 (which is the voltage to be applied to load 28) is approximately 120 volts.
As can be seen from Figure 1, when switch 29 is in the position shown ~terminal A connected to terminal B), ~
winding 13 is connected across the load 28, and is therfore supplying power to load 28, assuming on-off switch 30 is c1Osed. When switch 29 is in its alternate position (i.e. terminal A connected to terminal C) a portion of secondary winding 12 is connected across the load 28, and is therefore supplying power to load 28, assuming on-off switch 30 is closed.
Transformer 31 is employed as a current transformer which develops a signal on its secondary winding (to which control circuitry 32 is responsive) indicative of the magnitude of the current flowing through load 28. When no current is flowing through load 28, and for a predetermined time period after current starts to flow through load 28~ control circuitry 32 is in a first state. A-fter the predetermined time period control circuitry 32 is in a second state.
Switch 29 likewise has two states and is responsive to control circuitry 32 as indicated symbolically via the dashed line interconnection 33.
When control circuitry 32 is in its first state, switch 29 is likewise in its first state which is as shown in Figure l, i.e. terminal A
~z~
connected to terminal B. When control circuitry 32 is in its second state, switch 29 is likewise in its second state wh;ch is terminal A
connected to terminal C.
In actual fact, the preferred embodiment employs a solid-state switch for switch 29j but in order to make the swi-tch 29 and its operation easier to visualize it has been shown in Figure 1 as a simplified mechanical switch 29 with its control link from control circuitry 32 indicated as a dashed line interconnection 33. The simplified circuitry of the preferred switch 29 along with the preferred control circuitry 32 and preferred interconnection 33 is depicted in Figure 2 to be discussed later.
The operation of Figure 1 will now be described briefly. Inverter 22 is assumed to be already functioning. When on-off switch 30 is in its open position, as showng no current Flows through load 28 and consequently both control circuitry 32 and switch 29 are in their first states and switch 29 is in the positior shown in Figure 1. When on-off switch 30 is closed current (from q ,,"" /, ~ ~ ~f h~ winding 13) Plows through load 28 and is sensed by control circuitry 32 via transformer 31. Once current begins to flow through load 28 control circuitry 32 remains in its first state for a pre-determined time period. Consequently switch 29 remains in its first ry state, as is depicted in Figure 1 and ~UHH~ P~ winding 13 remains connected across load 28 and is supplying power thereto. After this predetermined time period (e.g. 0.8 seconds~ has elapsed, control circuitry 32 changes to its second state thereby causing switch 29 to change to its second state which results in terminal A being connected to terminal C. The effect of this is that now a portion of secondary winding 12 is connected across load 28 to supply power thereto.
The preferred embodiment of Figure 1 was designed to 5~
power a load 28 which ;s an electric motor. For this part;cular application the predetermined delay time in -the change of states of control circuitry 32 is approximately 0.8 seconds. The actual delay in the implementation of Figure l will depend upon the start;ng characteristics of the load 28. According to the spirit of this invention the idea is to employ the ~*~ y' winding 13 to supply power to load 28 during starting thereof when larger than steady~state currents are required~ and then to employ the normal secondary winding 12 of the ferroresonant transformer lO when the current drawn is approx-imately that of the steady-state condition.
Figure 2, depicting the preferred embodiment of switch 29, control circuitry 32, and interconnection 33 ;n simplified form will now be discussed. The interconnection of the various components is as shown in Figure 2 and attent;on is directed to that Figure.
Diodes 36, 37, 38 and 39 are connected to terminals 34 and 35 in the form oF a standard bridge rectifier. When there is current flowing through load 28 (Figure l) a voltage is developed across capacitor 40 v;a transFormer 31 and diodes 36, 37, 38 and 39.
When the current in the secondary winding of transformer 31 reaches approximately 175 milliamperes (mA), the voltage across capacitor 4 is o-f sufficient magnitude to turn off transistor 46. Diodes 42 and 43 protec~ the base of transistor 46 from excessive voltage magnitude on capacitor 40 due to large currents sensed by transformer 31.
Once transistor 46 is turned off, the voltage across capacitor 49 begins to increase in magnitude as it becomes charged via resistor 47. After a delay of approximately 0.8 seconds (since capacitor 49 began to charge), the voltage applied to the inverting (-) input of operational amplifier 54 is of sufficient magnitude to cause the output of amplifier 54 to change to a low (i.e. approximately -l volt) voltage value From its previous high value (near -12 volts).
This results in capacitor 59 being immediately discharged by diode 58, and the output of operational amplifier 61 is switched to a low voltage level (approximately -1 volt). The fact that the output of amplifier 61 is low means that light emitting diode (LED) 73 is not emitting light and consequently TRIAC (bidirectional triode thyristor) 75 is turned off. Additionally, diode 6g is no longer supplying bias to capacitor 67, and consequently capacitor 67 discharges via resistor 66.
After a short delay (until capacitor 67 has discharged sufficiently), of sufficient length to prevent any possibility of both TRIAC 75 and TRIAC 76 being on simultaneously, the output of operational amplifier 69 switches high (i.e. approximately -12 volts).
This turns on LED 78 causing it to emit light and thereby cause TRIAC 76 to be turned on and conducting.
When the magnitude of the current in the secondary winding of transFormer 31 falls below approximately 175 ~A., transistor ~6 turns on and consequen~ly capacitor ~9 discharges. The output of operational amplifier 5~ switches to a high voltage level (approximately ~12 volts) causing capacitor 67 to become charged via diode 68, and the output of operational amplifier 69 switches to a low voltage level (approximately -1 volt) ultimately causing TRIAC 76 to be non-conducting. After a short delay (caused by capacitor 67 charging to a sufficient voltage level) capacitor 59 becomes charged via resistor 55, and the output of operational amplifier 61 switches to a high voltage level, causing LED 73 to turn on and emit light, and ultimately cause TRIAC 75 to be in the conducting mode. The delay in turning on LED 73, caused by the fact that capacitor 67 must first become charged, ensures that both TRIAC 75 and TRiAC 76 are not both conducting at the same time.
It should be noted that operational amplifiers 54, 61 and 69 are of the type manufactured by Texas Instruments and referred Z~5~
to by the manufacturer as ~A747.
The preceding description of Figures 1 and 2 has been a description of the preferred embodiment of the invention, as envisioned by the inventor for one particular application. Various and sundry modifications can be made to the preferred embodiment described herein. Some of these modifications which are deemed to be within the scope of the invention, are described in the following section.
Figure 3 is a variation of the circuit shown in Figure 1.
In Figure 39 the voltage across load 28 is sensed rather than the current through load 28 (as is depicted in Figure 1). In Figure 3, the switch 29 and load 28 are interconnected in the same fashion as shown in Figure 1. The difference in Figure 3 is that the control circuitry 32 is in series with resistor 80 and the combination of circuitry 32 and resistor 80 is connected across load 2~ as shown in Figure 3. The purpose of resistor ~0 is to act as a voltage dropping resistance so that the range of voltages (and consequently currents) appearing between terminals 34 and 35 in the Figure 3 configuration is approximately the same as the range oF voltages (and currents) appearing between terminals 34 and 35 in the Figure 1 configuration. Control circuitry 32, interconnection 33 and switch 29 ~ :
are the same and operate the same in the Figure 3 configuration as they did in the Figure 1 configuration.
Additionally, instead of the electronic control circuitry 32 of Figure 3, a standard relay could be employed. The coil of the relay would be connected across the load 28 and the contacts of the relay would be connected so as to duplicate the switching function performed by switch 29 of Figure 3.
In essence3 in Figure 1, control circuitry 32 is designed to begin timing once switch 30 is closed, and after a predetermined time period, switch 29 is caused to change its state )5~Z
from that shown in Figure 1 to its alternate state, via interconnection 33. An alternative to this would be to monitor the magnitude of the current and when the current reaches approximately its steady-state magnitude (or any other desired magnitude), switch 29 is caused to operate.
Claims (11)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A voltage regulator for an alternating current (AC) load, said voltage regulator comprising:
a ferroresonant transformer having a primary winding for connection to a source of AC power, a secondary winding for selective connection to said AC load, and an auxiliary winding for selective connection to said AC load whereby said auxiliary winding is closely coupled to said primary winding;
a switch means for selectively connecting said auxiliary winding to said AC load for providing power to said load when said switch means is in a first state, and said switch means selectively connecting said secondary winding to said AC load for providing power to said load when said switch means is in a second state;
said switch means being responsive to the state of said load such that when said load is unenergized, and for a predetermined time period after said load is energized, said switch means is in its first state, and after said predetermined time period and for as long as said load remains continuously energized, said switch means is in its second state.
a ferroresonant transformer having a primary winding for connection to a source of AC power, a secondary winding for selective connection to said AC load, and an auxiliary winding for selective connection to said AC load whereby said auxiliary winding is closely coupled to said primary winding;
a switch means for selectively connecting said auxiliary winding to said AC load for providing power to said load when said switch means is in a first state, and said switch means selectively connecting said secondary winding to said AC load for providing power to said load when said switch means is in a second state;
said switch means being responsive to the state of said load such that when said load is unenergized, and for a predetermined time period after said load is energized, said switch means is in its first state, and after said predetermined time period and for as long as said load remains continuously energized, said switch means is in its second state.
2. The voltage regulator of claim 1 wherein said switch means is an electromechanical relay having its coil connected in parallel to said load.
3. The voltage regulator of claim 1 further including a control means responsive to the current through said load such that when no current is flowing through said load, and for a predetermined time period after current begins to flow through said load, said control means being in a first state, and after said predetermined time period, and for as long as current continues to flow through said load, said control means being in a second state;
said switch means being responsive to an output of said control means such that when said control means is in its first state said switch means is in its first state and when said control means is in its second state said switch means is in its second state.
said switch means being responsive to an output of said control means such that when said control means is in its first state said switch means is in its first state and when said control means is in its second state said switch means is in its second state.
4. The voltage regulator of claim 3 wherein said switch means is a solid-state device.
5. The voltage regulator of claim 3 wherein said switch means comprises two TRIACS; a first TRIAC is connected intermediate said auxiliary winding and said load, and a second TRIAC is connected intermediate said secondary winding and said load; said first TRIAC responsive to a first signal from said control means and said second TRIAC responsive to a second signal from said control means.
6. The voltage regulator of claim 3, 4 or 5 wherein said predetermined time period is 0.8 seconds.
7. A voltage regulator comprising a ferroresonant transformer for supplying regulated AC voltage to a load, wherein said ferroresonant transformer comprises a primary winding, a secondary winding, and a capacitance means connected across said secondary winding, said regulator characterized by:
an auxiliary winding wound on said ferroresonant transformer such that, ideally, all the flux linking the primary winding of said transformer also links said auxiliary winding, and vice versa;
a switch means for selectively connecting either said auxiliary winding or the secondary winding of said transformer across said load;
a control means controlling said switch means in such a manner that when no current is being supplied to said load, and for a predetermined time period after power is applied to said load, said switch means connects said auxiliary winding to said load, and after said predetermined time period said switch means is activated to disconnect said auxiliary winding from said load, and to connect said secondary winding to said load.
an auxiliary winding wound on said ferroresonant transformer such that, ideally, all the flux linking the primary winding of said transformer also links said auxiliary winding, and vice versa;
a switch means for selectively connecting either said auxiliary winding or the secondary winding of said transformer across said load;
a control means controlling said switch means in such a manner that when no current is being supplied to said load, and for a predetermined time period after power is applied to said load, said switch means connects said auxiliary winding to said load, and after said predetermined time period said switch means is activated to disconnect said auxiliary winding from said load, and to connect said secondary winding to said load.
8. The voltage regulator of claim 7 wherein said switch means is a solid-state device and wherein said predetermined time period is 0.8 seconds.
9. A voltage regulator for an AC load, said voltage regulator comprising:
a ferroresonant transformer having a primary winding for connection to a source of AC power, a secondary winding for selective connection to said AC load, and an auxiliary winding for selective connection to said AC load, whereby said auxiliary winding is closely coupled to said primary winding;
a control means being responsive to the state of said load such that when said load is unenergized, and for a predetermined time period after said load is energized, said control means being in a first state, and after said predetermined time period, and for as long as said load continues to be energized, said control means being in a second state;
a switch means for selectively connecting only said auxiliary winding to said AC load to provide power to said load when said switch means is in a first state, and said switch means selectively connecting only said secondary winding to said AC load to provide power to said load when said switch means is in a second state;
said switch means being responsive to an output of said control means such that when said control means is in its first state said switch means is in its first state and when said control means is in its second state said switch means is in its second state.
a ferroresonant transformer having a primary winding for connection to a source of AC power, a secondary winding for selective connection to said AC load, and an auxiliary winding for selective connection to said AC load, whereby said auxiliary winding is closely coupled to said primary winding;
a control means being responsive to the state of said load such that when said load is unenergized, and for a predetermined time period after said load is energized, said control means being in a first state, and after said predetermined time period, and for as long as said load continues to be energized, said control means being in a second state;
a switch means for selectively connecting only said auxiliary winding to said AC load to provide power to said load when said switch means is in a first state, and said switch means selectively connecting only said secondary winding to said AC load to provide power to said load when said switch means is in a second state;
said switch means being responsive to an output of said control means such that when said control means is in its first state said switch means is in its first state and when said control means is in its second state said switch means is in its second state.
10. The voltage regulator of claim 9 wherein said control means is responsive to the flow of current through said load.
11. The voltage regulator of claim 9 wherein said control means is responsive to the voltage applied across said load.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000307210A CA1120542A (en) | 1978-07-12 | 1978-07-12 | Ferroresonant voltage regulator incorporating auxiliary winding for large current magnitudes of short duration |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000307210A CA1120542A (en) | 1978-07-12 | 1978-07-12 | Ferroresonant voltage regulator incorporating auxiliary winding for large current magnitudes of short duration |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1120542A true CA1120542A (en) | 1982-03-23 |
Family
ID=4111884
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000307210A Expired CA1120542A (en) | 1978-07-12 | 1978-07-12 | Ferroresonant voltage regulator incorporating auxiliary winding for large current magnitudes of short duration |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1120542A (en) |
-
1978
- 1978-07-12 CA CA000307210A patent/CA1120542A/en not_active Expired
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| US5119013A (en) | Switching regulator with multiple isolated outputs | |
| US4242630A (en) | Ferroresonant voltage regulator incorporating auxiliary winding for large current magnitudes of short duration | |
| US5671115A (en) | Circuit arrangement for driving a contactor | |
| JP2013226047A (en) | Circuit and method for responding to current derived from voltage across input of energy transfer element | |
| US5304781A (en) | Two terminal line voltage thermostat | |
| US5014176A (en) | Switching converter with spike limiting circuit | |
| US4713740A (en) | Switch-mode power supply | |
| US4899270A (en) | DC-to-DC power supply including an energy transferring snubber circuit | |
| US9124087B2 (en) | Arc suppression circuit | |
| US3921197A (en) | Direct current power converter | |
| CA1120542A (en) | Ferroresonant voltage regulator incorporating auxiliary winding for large current magnitudes of short duration | |
| JP2004140994A (en) | Electronic circuit | |
| JPH01318549A (en) | Multiple output type switching regulator | |
| US4744020A (en) | Switching mode power supply | |
| JPS6319846Y2 (en) | ||
| KR100487390B1 (en) | Switched-mode power supply device with a starting circuit | |
| JPH09266667A (en) | Overcurrent/overload protection circuit, power supply apparatus, electric machine and duplicator | |
| JPH0465633B2 (en) | ||
| SU1598073A1 (en) | Pulsed d.c. voltage controller | |
| SU1573451A1 (en) | Device for stabilization of alternating voltage | |
| RU2100837C1 (en) | Alternating voltage stabilizer | |
| RU1788530C (en) | Device for control over a c electric magnet | |
| JPH01318550A (en) | Multiple output type switching regulator | |
| KR870001301Y1 (en) | Power circuit | |
| SU1654907A1 (en) | Device for non-stop feeding of dc users |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| MKEX | Expiry |