SU907699A1 - Power supply system - Google Patents

Description

load by means of keys, and always one of the energy sources is connected to the load, and the second is disconnected. Connecting a disconnected power source to a load of pro-cysts while reducing the voltage on an operating power source to a certain value, while the operating power source is disconnected from the load 5 and 6.

The disadvantages of these power supply systems include increased weight-dimensional indicators, the increase in which occurred due to the use of two energy sources, calculated on the maximum power load.

Power systems are known that contain parallel switched switched main power sources and a battery, and a current sensor is installed in the circuit of each power source that controls the switching of other power sources according to a given law 7.

The disadvantage of such power supply systems is the increased weight-dimensional indicators, the increase in which has occurred as a result of the use of a -battery battery, designed for the entire duration of the power supply system operation for maximum load power.

A known power system comprising a primary power source of limited power, a battery connected to the primary power source via a transistor switch, a measuring element connected between the connection point of the transistor switch and the primary power source and a load, and the measuring element connected to the transistor switch 8.

The disadvantages of this power system include the possibility of recharging the buffer battery with an increased current, as well as the fact that the battery is connected to the load when the primary power source is overloaded by current rather than power, which requires the use of a primary source power, calculated on the maximum power load and, consequently, to increase the weight and overall performance of the power system.

Power systems are known in which the primary power source BKJBO is parallel to the battery, the battery being connected to the primary source through a charging or discharge current regulator 9.

The disadvantage of such power supply systems is that the energy flowing from the primary power source to the load through the battery.

is converted twice, as a result of which the efficiency of the power supply system is underestimated, and the weight and dimensions of the primary power and the precision of power

 Nutrition systems are enhanced.

A power system is also known in which the common connection point of the primary power source and the charge-discharge regulator is connected to the load through a voltage regulator, and the primary power source is a source of limited power 10.

The disadvantage of such a power system is the triple-conversion of energy passing from the primary power source to the load, as a result of which the weight and dimensions of the power system are increased.

A known power supply system comprising a primary unregulated source of direct voltage, connected via a voltage regulator to the load, a buffer battery connected through a second voltage regulator to the load, two control systems connected to the voltage regulators, the system control of the first voltage regulator provides a selection mode from the primary power source of maximum or nominal power or nominal current, the control system of the second voltage regulator echivaet mode charge battery

 load voltage stabilization, and in battery charge mode - the necessary power extraction from the battery 11.

The disadvantages of this food system are the constant selection from

a primary power supply of maximum or but 5 rated power or rated current at various power levels of the load, which leads

5 to increase the weight and dimensions of the power supply system due to the use of a primary power source of increased energy intensity, the possibility of overcharging the battery with increased current, because at low power load the excess power supplied by the primary source enters the battery, as well as reduced efficiency due to the triple conversion of energy passing from the primary source of power to the load through the buffer battery.

Hc1 And the closest to. The technical essence of the present invention is a power supply system containing a primary power source, a secondary electro-chemical generator, a memory device, and the secondary electrochemical generator is charged in the first mode during

time dependent on the previous discharge of the generator recorded in the memory. The primary current source is capable of providing a constant current, and the establishment of the first mode is caused by the discharge of the electrochemical generator 12.

 The drawbacks of the proposed TANI system are increased weight-dimensional indicators, the increase of which is due to the use of a primary power source calculated for the sum of the maximum load power and maximum power given to the electrochemical generator (buffer battery) when it is charged. The charge of the buffer battery is performed without taking into account the phenomenon of self-discharge, which can lead to premature failure of the power system.

The purpose of the invention is to improve the weight and size indicators of the nutrition system, increasing its service life.

The goal is achieved by the introduction of a Power Stabilizer, a current sensor, an integrator, a sign detection circuit, three comparators, a voltage source, a voltage divider, an OR circuit, a primary power source, a buffer battery, a memory device in the power supply system. a decoder, a trigger, a control key, the power regulator being connected to the primary power source and the output to the power system output, a current sensor connected between the buffer battery and the output of the station. power transmitter and its output connected to the inputs of the integrator, the sign definition circuit and the first input of the first comparator, the integrator output is connected to the first inputs of the second and third comparators, the outputs of which are connected to the inputs of the OR circuit, the source of the reference line, the second output the inputs of the first and third comparators and with the inputs of a voltage divider and a controllable key, and the output of the voltage divider is connected to the second input of the second comparator, a memory device outputted in the form of a reversible counter ka, is connected by a counting input to an output of an OR circuit, as well as to an integrator zeroing input, a controlled input — to the output of a sign detection circuit, an output — to a decoder input, which is connected by its two outputs to two trigger inputs, the first comparator is connected to the output the second output of the decoder, and the control key is connected by a control input with a trigger output, and the output 8 - with a control output of a power stabilizer.

The drawing shows a block diagram of a system power supply.

The power supply system contains a primary power supply source I connected to the input of a power stabilizer 2, the output of which is connected to the power supply system output, a current sensor 3 connected between the buffer battery 4 and the output of the power regulator 2 and connected to the integrator 5 inputs via its input , schemes for determining the sign of 6.11 the first input of the comparator 7, the output of the integrator 5 is connected to the first inputs of the comparators 8 and 9, the outputs of which are connected to the inputs of the circuit OR 10, the source

5 11 of the first voltage, connected by the input with the second inputs of the comparators 7 and 8 and the inputs, divider 12 eg. and controlled key 13, and the output of the voltage divider 12 is connected

0 with the second input of the comparator 8, and the output of the controlled key 13 with the control input of the power regulator 2, the memory 14, made in the form of a reversible counter, is connected with a counting input with the output of the circuit

5 OR 10 and the zeroing input of the integrator 5, the controlled input with the output of the sign detection circuit b, and the output with the input of the decoder 15, which is connected by its two outputs with two

0 inputs of the trigger 16, with the second output of the decoder 15 also connected to the output of the comparator 7, and the output of the trigger 16 is connected to the control input of the control key 13, on the first

5, the output of the decoder 15, the signal appears at the zeroed state of the reversible counter 14, and at the second output at the state of the reversible counter 14, corresponding to a predetermined length 0 of the buffer battery 4.

In the proposed power supply system, a pulse width regulator can be used as a power regulator 2 with a control system that provides negative feedback on the deviation of the input power from the reference voltage, which is applied to the power stabilizer control input. As a current sensor 3, a resistive current sensor can be used; as an integrator 5, an integrator on an operational amplifier with zeroing can be used;

5 when applying a high voltage zeroing to its input, as a sign definition circuit. 6 — Schmidt trigger, as comparators 7–9 operational amplifiers with positive feedback, as an equalized switch 13 — controlled voltage divider , the output voltage of which is equal to the input voltage when a control voltage comes to its input, is of a low voltage level, and is equal to

5 when a low-level voltage control arrives at its input (for implementing such a voltage divider, for example, a relay circuit can be used), as a decoder 15 is a combinational circuit with a bottom m output, and at the first output voltage with the zeroed state of the reversible counter 14, and at the second output, a high voltage appears when the revolving counter is in a state corresponding to a certain discharge of the buffer battery 4 as a trigger 16. o-use tJ-K trigger. The power system works as follows. At the start of operation, the buffer battery 4 is fully charged. In the initial state, the reversible counter 14. and the trigger 16 are zeroed at the outputs of all comparators, at the output of the trigger 16, at the second output of the decoder 15, at the output of the OR circuit 10, at the output of the determination circuit b is known for low voltage levels, on the first the output of the decoder 15 is high level, voltage. The control key 13 is in a state with a zero output voltage level because its control input from the trigger output 16 is energized at a low level. As a result, power stabilizer 2 is disconnected, since the value of the reference voltage is zero, and therefore the amount of stabilized power is also zero. At the beginning of operation, energy is fed to the output of the power supply system only on the backup battery 4. The output current, The flow through the current sensor 3 causes a voltage at its output, which, acting on the sign detection circuit b, translates it to the state q by a high level of the output voltage. The voltage from current sensor 3 also goes to comparator 7, however, it does not change its state at a low value of the output current of the power supply system. The integrator 5 integrates the voltage taken from the sensor: ik 3 current. When the output voltage of the integrator 5 is reached, the voltage level specified by the voltage source 11, the comparator 9 changes its state, and a high voltage appears at its output. As a result, the output of the OR 10 circuit also produces a high voltage ypoBHff, which acts on the control input of the integrator 5, wrapped it in. As a result, the comparator E and the OR circuit translate to initial states with low output levels. ., A counter pulse is generated at the output of the reversing counter 14. Due to the fact that a high level voltage is applied to the control input of the reversible counter 14, the reversible counter 14 is in the summation mode and generated at its (Counting input counter pulse is kept in the summation mode of the reversible counter 14. This operation mode of the power system continues until , while the number of 14 pulses recorded in the reversible counter in the summation mode does not coincide with the number of pulses necessary .-, so that the second output of the decoder 15 has a high voltage In this case, the trigger 16 enters a state with a high output voltage level, as a result of which the output of the controlled key 13 appears a level of the reference voltage, and the power regulator 2 begins to stabilize the power taken from the primary source 1 at a certain the level specified by the source AND the reference voltage The energy from the primary source 1 through the power regulator 2 is fed to the output of the power supply system. Establishing the last mode — connecting to the output of the power supply system of the primary power source through the power regulator 2 — may also be caused by a large current draw from the buffer battery 4. In this case, the voltage removed from the output of current sensor 3 affects the comparator 7, converts it a state with a high level of output voltage, as a result of which the trigger 16 also goes into a state with a high level of output voltage, and at the output of the controlled key 13 a level of the reference voltage appears and The power biliser 2 connects to the output of the power supply system the primary source 1. The buffer battery of the battery 4 will be charged if the power supplied by the power supply system is less than the output power stabilized at the output of the stabilizer 2. Otherwise, the power output will come from the primary power source 1 and the buffer battery 4. In the charge mode of the buffer battery 4, the voltage at the output of current sensor 3 will change polarity, with the result that a low voltage level is established, and the reversible counter 14 goes into subtraction mode. When the level of the output voltage of the integrator 5 reaches the value of the threshold voltage supplied to the comparator 8 from the source 11 of the reference voltage through the voltage divider 12, the comparator 8 will enter the state with

high output voltage

As a result, a high level of the output voltage is generated at the output of the OR circuit, which leads to zeroing of the integrator 5, which in turn causes the comparator 8 to return to its original state — with a low level of the output voltage. A counting pulse is generated at the counting input of the reversible counter 14, which is recorded in the subtraction mode of the reversible counter 14. The power supply system will be in charge mode of the back-up battery 4 until the reversing counter 14 is cleared. At the same time on the first output of the decoder

15, a high voltage level is established, and the trigger 16 goes into a state of low output voltage, as a result of which the output of the control key 13 is set to zero voltage, and the power regulator 2 goes off, which will cause a shutdown from the output of the power supply system of the primary power source 1. The operation of the comparator 8 in the charge mode of the buffer battery 4 is due to the fact that when integrating the voltage coming from the output of current sensor 3 to the input of integrator 5, the output of integrator 5 also decreases when the voltage reaches the threshold level, the value which is less than the voltage level of the zeroed integrator 5, the comparator 8 changes its state, the threshold voltage of the comparator 6 being set by the voltage divider 12 and the reference voltage source 11. -Comparator 9 works only when the buffer battery 4 is discharged, because when integrating the voltage coming from the output of current sensor 3 to the input of integrator 5, the output of integrator 5 also increases when the value of this voltage reaches the threshold voltage the value of which is greater than the level of the output voltage of the integrator 5 in its zeroed state, the comparator

9 changes its state. The threshold voltage of the comparator 8 is set by means of voltage divider 12 so that the counting pulse arrives at the input of the revolving counter 14 in charge mode of the buffer battery 4 with the passage of energy greater than the energy corresponding to the formation of the counting pulse at the output of the comparator 9, in the mode of discharge of the buffer battery 4 - by the amount of self-discharge energy of the buffer battery

four..

The power supply system differs from the known ones with improved weight-dimensional indicators, the improvement of which occurred as a result of selection from the primary power source of average power, which was achieved due to the power supply system operation in three J modes: the discharge of the buffer battery, its recovery power and load power from the primary power source,

Q joint operation of the buffer battery and the primary power source of limited power. Improvement in the weight and dimensions of the power system also occurred following. A single conversion of the energy supplied to the power system load. The advantages of the power supply system include the impossibility of recharging the buffer battery batteries due to accurate accounting of the amount of energy given and received and setting the recoverable mode of the battery backup battery after its full or partial recovery. The advantage of such a power system is to take into account the appearance of the self-discharge of the buffer battery during its recovery, and this phenomenon is taken into account by setting different QpaTopoB computer thresholds, each of which is triggered either by charging or by discharging the buffer battery.

Such a power supply system can work for a long time in the composition of the auto HOMHfclx devices without human control, and the duration of its operation is determined by the power consumption of the primary power source and the lifetime of the elements.

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Claims (11)

1. For the application of the Federal Republic of Germany No. 1790095, cl. H 02 3 9/06, 1975. 2, USSR Author's Certificate 12537, cl. H 02 J37 / 14, 1976., 3. For the UK 9 1424383,, cl. H 02 P 7/00, 1976. 4. Author's certificate of the USSR 417871, cl. H 02 o 7/34, 1974. 5. For the UK of UK number 1306748 Cl. H 02 and 9/00, 1973. 6. For France of France No. 2152693, cl. H 02 3 9/00, 1973. 7. Author's certificate of the USSR 511534, cl. H 02 3 7/34, 1976. 8. Author's certificate of the USSR 473243, cl. H 02 3 7/34, 1975. 9. For the UK of Great Britain No. 134,079 kl N 02 O 7/04, 1974. 10. The copyright certificate of the USSR 562801, CL H 02 3 7/34. 11. Author's certificate of the USSR 491183, cl. H 02 3 7/34, 1974. 12.3a VC France 2386176 ,, class. H 02 3 7/10, 1979.