Technical Field

This invention relates to a control circuit for an uninterruptible power supply adapted to supply an A.C. signal to a load and including a main source adapted to provide a main A.C. signal, and inverter means adapted to supply an auxiliary A.C. signal to said load.

Background Art In today's wide use of computers, data processors, controllers, etc. in data processing systems, it is extremely critical that the system be supplied with continuous power during its operation. Due to inadequate capacity and increasing load demands, commercially-supplied power is often subject to complete failure of the power signal or a reduction in the magnitude of the available voltage during peak demand periods. In cases where various customers subject the power system to sudden electrical loads, transients are generated in the system affecting the magnitude and phase of the supplied power signal. Since the storage of data in a computer system is predicated of the continuous operation of the computer, power interruptions can adversely affect the integrity of the stored data. When the power drops abruptly, the computer will terminate operation probably with a high possibility of component damage. In order to overcome this situation*, computers operating in a data processing system environment have been supplied with uninterruptible power supplies. An uninterruptible power supply is known from U.S. Patent No. 4,241,261. In this known power supply a control circuit monitors the state of the main A.C. signal and the output power signal applied to the output load, applying synchronizing signals to

a phase shift control circuit which additionally monitors the current flow from the battery supplying the inverter means. The inverter means is controlled to minimize the power drain thereon during normal operation of the power supply.

Disclosure of the Invention

According to the present invention, there is provided a control circuit for an uninterruptible power supply adapted to supply an A.C. signal to a load and including a main source adapted to provide a main A.C. signal, and inverter means adapted to supply an auxiliary A.C. signal to said load, characterized by: transfer control means adapted to control the operation of said inverter means in dependence on the condition of said main A.C. signal; A.C. sensing means adapted to provide a sensed signal dependent on the main A.C. signal _? comparison means adapted to compare said sensed signal with a predetermined voltage level to provide a first control signal in. response to a predetermined comparison state; clock signal generating means responsive to said first control signal to provide clock pulse signals applied in operation to counting means; data storage means coupled to counting means and adapted to provide output data signals in response to the counting states of said counting means; and conversion means adapted to convert said output signals to a reference waveform for detecting a failure in said main A.C. signal. It will be appreciated that a control circuit according to the invention has the capability of synchronizing the transfer of power signals to a load between a main A.C. source and an inverter. A further advantage is that a very fast response time can be achieved for switching the inverter means in • and out of effective operation, within one half-cycle of operation. Further advantages are that the circuit is simple in construction and hence low in cost.

In brief summary, a preferred embodiment of a circuit for controlling the switching of an inverter in an uninterruptible power supply into an A.C. input line includes a comparator for establishing the time the input A.C. sine wave goes positive through zero voltage, and for generating a reference sine wave for use in detecting the occurrence of a power failure in the A.C. input line. The circuit further includes a programmable read-only memory for outputting binary data which is converted into a reference sine wave by a digital-to-analog converter in response to receiving binary data from a counter whose output is locked into a system frequency by a phase lock loop circuit. The output frequency of the phase lock loop circuit is used to synchronize the operation of the inverter.

Brief Description of the Drawings

One embodiment of the invention will now be described by way of example with reference to the accompanying drawings, in which:- Fig. 1 is a block diagram of the uninterruptible power supply in which the synchronizing circuit of the present invention is utilized;

Figs. 2A-2D inclusive, taken together, form a schematic representation of the synchronizing circuit of the present invention;

Fig. 3 is a diagram showing the manner in which Figs. 2A-2D inclusive are arranged with respect to each other to form the synchronizing circuit; Figs. 4A-4D inclusive disclose the waveforms of the output signals occurring during the operation of the synchronizing circuit.

Best Mode for Carrying out the Invention

Referring now to Fig. 1, there is shown a block diagram of the uninterruptible power supply in

which the phase synchronizing control circuit of the present invention is found. Included in the power supply is the A.C. line input circuit 20 over which appears the A.C. power signal supplied from a commercial power source and which is transmitted through an A.C. circuit breaker 22 and over lines 24, 26 to a line transfer logic circuit 28 which controls the connection of the A.C. line input circuit 20 to a load 34. The line transfer logic circuit 28 will output over lines 30, 32 to the load 34 an A.C. signal received over lines 24, 26 from the A.C. line input circuit 20. The load 34 also receives an A.C. signal transmitted over lines 36, 38 from a D.C. to A.C. inverter logic circuit 40 which, when enabled, will convert the D.C. signal output of a 60 volt battery 42 received over the common ground line 44 and line 46 to an A.C. signal. The inverter logic circuit 40 is enabled by signals appearing on bus 48 when generated by a transfer logic circuit 50 which receives signals over lines 52, 54 from an A.C. sensing circuit 56 representing the signal level of the A.C. signals being outputted from the A.C. circuit breaker 22. The inverter logic circuit 40 is more fully described in copending international application No. , in the name of the present Applicants, entitled "Inverter for Uninterruptible Power Supply." The transfer logic circuit 50, in which is located the synchronizing circuit of the present invention, upon sensing a drop in the signal level of the line A.C. signal, will output control signals over bus 48 (which includes a plurality of lines carrying signals in respective directions) to the inverter logic circuit 40 and bus 58 to the line transfer logic circuit 28 enabling the inverter logic circuit 40 to output A.C. power signals over lines 36, 38 to the load 34 through lines 30 and 32 and disconnecting the A.C. line input circuit 20 from the load 34. When the A.C. line input 20 returns

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to its normal power level, the transfer logic circuit 50 will enable the line transfer logic circuit 28 to switch back to the input lines 24, 26 allowing the A.C. line input circuit 20 to supply the power over lines 30 and 32 to the load 34. This switching of the line input circuit 20 occurs in phase with the original line frequency of the signal appearing at the line input circuit 20. The transfer logic circuit 50 outputs over lines 51, 53 signals for disabling the A.C. circuit breaker circuit 22 when a system overload occurs. The circuit 50 also outputs signals over line 96 to an interface circuit 98 indicating the operating condition of the power supply.

Further included in the power supply is a 12 volt D.C. power supply 60 which receives the A.C. power signals over lines 62 and 64 and converts them to a 12 volt D.C. signal which is supplied over line 66 to power the various logic circuits in the power supply. Also included in the power supply is the snubber logic circuit 68 which eliminates any abnormal current spikes which occur during the switching of the transfer logic circuit 28 between the A.C. line input circuit 20 and the inverter logic circuit 40. The circuit 68 receives control signals over bus 58 from the transfer logic circuit 50 and from the inverter logic circuit 40. Associated with the 60 volt battery . 42 is a D.C. circuit breaker 70 connected to the battery 42 over line 71 and providing a current overload protection for the battery, a battery charging circuit 72 which converts the A.C. line signals appearing on lines 74, 76 to a charging current which is then supplied to the battery 42 over line 78 during the time the A.C. line power signals are available and a 12 volt auxiliary down switch 80 which supplies a 12 volt D.C. signal to power the logic circuits upon the failure of the A.C. line input. The switch 80 drops the 60 volt signal

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supplied over line 82 from the battery 42 through the circuit breaker 70 and outputs the 12 volt D.C. signal over lines 84 and 66 to the required logic circuits of the power supply. Associated with the inverter logic circuit

40 is an A.C. sensing circuit 86 receiving over lines 88, 90 the A.C. signal output of the inverter logic circuit 40, the amplitude of such signals being used to regulate the amplitude and shape of the A.C. signals being outputted by the inverter logic circuit 40. The sensing circuit 86 drops the A.C. output signal level appearing on lines 92, 94 to 5 volts, allowing the signal to be compared with the signals being outputted by the logic circuit 40. Referring now to Figs. 2A-2D inclusive, there is shown the circuit for generating the control signals used in the operation of the uninterruptible power supply for supplying an A.C. power signal to the load 34. Included in the circuit is a line transformer generally indicated by the numeral 100 (Fig. 2A) in which the primary windings 102 are connected over lines 52, 54 to the A.C. sensing circuit 56 (Fig. 1) for receiving the line A.C. power signals being outputted by the A.C. line input circuit 20. The transformer 100 steps down the 120 volt A.C. signals appearing on lines 52, 54 to 12 volts and couples the A.C. signal 104 (Fig. 4A) through the secondary windings 106 over lines 108, 110 to a pair of rectifying diodes 112, 114 which rectify the sine wave signal to produce the rectified sine wave signal 116 (Fig. 4B) offset from ground by 1 volt. This rectified sine wave signal is transmitted over line 118 through the dropping resistor 120 and the variable resistor 122 from where it is picked off by the slider 124 and transmitted over line 126 to the positive input of a comparator 128 which is part of an LM339 quad comparator circuit 130. The negative input of

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comparator 128 receives a reference rectified sine wave signal 132 (Fig. 4C) over line 134 through the dropping resistor 135 from a ZN 429 digital-to-analog converter circuit 136 (Fig. 2) which generates the signal 132 in a manner to be described more fully hereinafter. The adjustable resistor 122 adjusts the amplitude of the rectified sine wave, signal 116 (Fig. 4B) while the adjustable resistor 138 establishes the off-set of the signal 116 to ground which is required to enable the signal to be used by the inverter logic circuit 40 (Fig. 1).

The comparator 128 comparing the amplitude of the rectified sine wave signal 116 (Fig. 4B) with the amplitude of the reference sine wave signal 132 (Fig. 4C) will output a low signal over line 140 when the amplitude of the signal 116 falls below the amplitude of the reference signal 132 indicating a failure of the line A. C. power source. The output signal appearing on line 140 is inputted into the positive input of a second comparator 1.42 which compares the level of the inputted signal to ground. The comparator 142 outputs a low signal over line 144 which discharges a capacitor 146 to the ground line

147 and is transmitted through the dropping resistor

148 over line 149 to the positive input of a second comparator 150 which compares the signal to a voltage level of 3 volts. The comparator 150 will output the low control signal POWER FAIL over line 152 (Fig. 2B) indicating the occurrence of a power failure and which controls the operation of the snubber logic circuit 68, the inverter logic circuit 40 and the line transfer logic circuit 28.

The A.C. power line signals 104 (Fig. 4A) appearing on the output line 108 of the secondary windings 106 of the transformer 100 are also transmitted over line 108, 154 through the resistor 156 and the diodes 158, 160 producing a signal 162

(Fig. 4D) which varies between plus or minus .7 volts. This signal is transmitted over line 164 to the positive input of the comparator 166 which compares the signal 162 to ground. When the positive portion of the signal 162 appears, the comparator 166 will output ^" a high signal over lines 168 and 170 as the signal ZERO CROSSING representing the time the signal 104 (Fig. 4A) is going positive through the zero voltage line. This signal on line 170 is used by the line transfer logic circuit 28 in synchronizing the return of the line A.C. power signals to the system. When the A.C. line is returning to normal operation, the capacitor 146 (Fig. 2A) is charged through resistor 176 providing a time delay during which the comparator 128 outputs a high signal indicating the return of the A.C. input power source in addition to ensuring that the timing will occur at the zero crossing point of the sine wave 104. Further included in the circuit are the resistors 180, 182 (Fig. 2A) which form a voltage divider circuit for developing a 3 volt signal which is applied over line 184 to the negative input of the comparator 150. The pull-up resistor 186 pulls up the level of the output signal of comparator 150 appearing on line 132 to 12 volts, while diode 188 and resistor 190 provide a feedback signal to the positive input of the comparator 150. Resistor 148 isolates the output signal of comparator 142 from the input signal to the comparator 150 appearing on line 149 while the resistor 177 isolates the output signal of comparator 166 from the input signal appearing on line 164. The comparator circuit 130 is powered by a 12 volt power supply over line 192 (Figs. 2A and 2B inclusive) through the dropping resistor 169 and a 5 volt power supply appearing on line 194 and transmitted through the dropping resistor 195.

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The signal ZERO CROSSING appearing on line 170 (Fig. 2B) is transmitted through the capacitor 196 to the input of a 555 timing circuit 198. A resistor 193 holds the input line 170 at a 12 volt level except when the signal ZERO CROSSING occurs which pulls the signal on the input line down to zero. When the signal ZERO CROSSING is removed, a diode 195 holds the signal appearing on line 170 at 12 volts. The width of the signal outputted by the timing circuit 198 is controlled by the resistor 197 and capacitor 199. The timing circuit 198 will output the ZERO CROSSING signal over line 200, through the inverter 202 and over line 204, the dropping resistor 212 (Fig. 2C) and the zener diode 206 to an 8650 oscillator 208 which is reset by the signal to output 60 Hz. square wave clock signals representing the line frequency over line 210 to a CD 4046 phase lock loop circuit 214 which operates to lock in on the clock output of the oscillator 208. The phase lock loop circuit 214 includes a voltage controlled oscillator (not shown) generating a plurality of clock pulses at a nominal frequency 128 times not of the 60 Hz. pulses the generated dock pulses being outputted over line 220 to a CD 4024 seven-stage counter 218 (Fig. 2D). The counter 218 divides down the input frequency of the clock signals and outputs over line 216 a 60 Hz. square wave clock signal to the phase lock loop circuit 214 enabling the circuit to lock onto the 60 Hz. clock output of the oscillator 208. It will be appreciated that the frequency of the clock pulses on the line 220 increases or decreases to maintain the output of the counter 218 on the line 216 in synchronism with the 60 Hz. signal provided by the oscillator 208. The 60 Hz. clock pulses appearing on line 216 are also transmitted over line 217 (Fig. 2D) which is part of bus 48 (Fig. 1) to the inverter logic circuit 40 for synchronizing the operation of the circuit.

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The counter 218 outputs over lines 221 seven binary signals representing the output count of the counter 218 in which are inputted into a 2716 EPROM 222 which has been programmed to output eight binary signals over lines 224 which have been weighted so that when they are inputted into a ZN429 digital-to- analog converter 136, the rectified sine wave signal 132 (Fig. 4C) will appear on the output line 134 of the converter 136. This signal which is generated in phase with the line frequency is transmitted as a reference signal to the negative input of comparator 128 (Fig. 2A) for use in determining the time the A.C. line input falls below the reference signal in the manner described previously. The reference signal 132 (Fig. 4C) is also transmitted through a 2902 operational amplifier 226 and out over line 228 as the signal REF which is part of the bus 48 (Fig. 1) to the inverter logic circuit 40 where it is used in synchronizing the transfer of the inverter power signals to the load 34 and for the removal of the inverter power signals when the A.C. power line returns. The signal REF is also used in the operation of the snubber logic circuit 68 (Fig. 1).

The 60 Hz. time constant for the oscillator 208 (Fig. 2C) is controlled by an internal crystal oscillator. Resistors 238-244 inclusive and capacitor 246 control the response time and the frequency of the phase lock loop circuit 214 in locking the clock output of the oscillator 208 to the A.C. line frequency. The resistors 248-252 inclusive, and the variable resistor 254 (Fig. 2D) control the amplitude and the off-set of the sine wave signal 132 (Fig. 4C) outputted by the converter circuit 136 while the resistors 256 and 258 provide a gain of 3.16 for the amplifier 236.

In the operation of the circuit, the amplitude of the sine wave signal 104 (Fig. 4A)

appearing on the A.C. line input circuit 20 (Fig. 1) and outputted by the transformer 100 (Fig. 2A) is limited by the diodes 158, 160 and compared by the comparator 166 to ground, conditioning the comparator 166 to output a pulse every time the A.C. line signal goes positive through the zero voltage. This pulse, identified as the signal ZERO CROSSING, resets the square wave oscillator 208 (Fig. 2C) whose 60 Hz output clock signals representing the system frequency are inputted into the phase lock loop circuit 214 which also receives clock signals over line 216 from the counter 218 generated at the system frequency, enabling the phase lock loop circuit to lock the system clock signals to the oscillator output frequency. The counter 218 initially receives clock signals from the phase lock loop circuit 214 set at a frequency 128 times that of the system frequency. The counter 218 comprising a seven-stage counter, downcounts the receive clock signals so that the clock signals outputted to the circuit 214 are at the 60 Hz. system frequency.. During the operation of the counter 214, the counter also outputs a series of six binary signals to the programmable read-only memory 222 which outputs a series of 8 bit words to the digital-to- analog converter 136 which in turn outputs the rectified sine wave signal 132 (Fig. 4C) at the system frequency. This rectified sine wave signal output is used as a reference signal in switching between the line input circuit 20 (Fig. 1) and the inverter logic circuit 40 as the source of power for the load 34

(Fig. 1) . The rectified sine wave signal 132 is also inputted into the comparator 128 (Fig. 2A) which compares the signal 132 with the rectified sine wave signal 116 (Fig. 4B) received from the transformer 100 to sense the occurrence of a power failure. Upon such an occurrence, the low signal POWER FAIL is generated which is used by the line transfer logic circuit 28

(Fig. 1) to disable the A.C. line input circuit as a source of power to the load 34 while enabling the inverter logic circuit 40 to supply power to the load. This occurs instantaneously upon the generation of the signal POWER FAIL. It will thus be seen that the power supply is operated synchronously with the line frequency, enabling the inverter to be switched in and out of the A.C. input line without disrupting the power supplied to the load. In addition, the use of the programmable read-only memory 222 (Fig. 2D) provides the system with the versatility of being able to program whatever wave shape is required, thereby enabling the inverter to be inserted at the instant the power failure occurs. The following is the program listing for the

2716 EPROM 222 (Fig. 2D) in generating the rectified sine wave signal 132 (Fig. 4C) .

Address Data Word

Binary Hexadecimal Binary Hexadecimal

00000000 00 00011010 1A

00000001 01 00100111 27

00000010 02 00110010 32

00000011 03 01000000 40

00000100 04 01001100 4C

00000101 05 01011001 59

00000110 06 01100101 65

00000111 07 01110000 70

00001000 08 01111010 7A

00001001 09 10000111 87

00001010 OA 10010010 92

00001011 OB 10011100 9C

00001100 OC 10100110 A6

00001101 OD 10110000 BO

00001110 OE 10111001 B9

00001111 OF 11000010 C2

00010000 10 11001010 CA

00010001 11 11010001 Dl

00010010 12 11011000 D8

00010011 13 11011111 DF

00010100 14 11100101 E5

00010101 15 11101010 EA

00010110 16 11101111 EF

00010111 17 11110011 F3

00011000 18 11110111 F7

00011001 19 11111010 FA

00011010 1A 11111100 FC

00011011 IB 11111101 FD

00011100 1C 11111110 FE

00011101 ID 11111111 FF

00011110 IE 11111111 FF

00011111 IF 11111111 FF

00100000 20 11111110 FE

00100001 21 11111101 FD

00100010 22 11111100 FC

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00100011 23 11111010 FA

00100100 24 11110111 F7

00100101 25 11110011 F3

00100110 26 11101111 EF

00100111 27 11101010 EA

00101000 28 11100101 E5

00101001 29 11011111 DF

00101010 2A 11011000 D8

00101011 2B 11010001 Dl

00101100 2C 11001010 CA

00101101 2D 11000010 C2

00101110 2E 10111001 B9

00101111 2F 10110000 B0

00110000 30 10100110 A6

00110001 31 10011100 9C

00110010 32 10010010 92

00110011 33 10000111 87

00110100 34 01111010 7A

00110101 35 01110000 70

00110110 36 01100101 65

00110111 37 01011001 59

00111000 38 01001100 4C

00111001 39 01000000 40

00111010 3A 00110010 32

00111011 3B 00100111 27

00111100 3C 00011010 1A

00111101 3D 00001101 0D

00111110 3E oooooooo 00

00111111 3F 00001101 0D

The oscillator 208 is commercially available from Epson America, Inc. of Torranee, California.

The digital-to-analog converter 136 is commercially available from the Ferrarati Corporation, of Commack, New York. The remaining integrated circuits are commercially available from National Semiconductor Corporation of Mountain View, California.