RU24577U1 - MULTI-POWER SUPPLY - Google Patents

Abstract

A multimode power source containing an autonomous power source made in the form of a battery, a stabilizer, a filter, a voltage converter, consisting of two field-effect transistors with internal integrated diodes, and a transformer, characterized in that a switching unit, a bus driver, network sensors are inserted into it voltage and temperature, an additional field effect transistor with an internal integrated diode, a microcontroller, an input signal receiving unit and an amplifier, while the output of an autonomous source the power supply is connected to the first input of the microcontroller and connected through the stabilizer to the power input of the microcontroller, the second and third inputs of which are connected respectively to the outputs of the amplifier and temperature sensor, the outputs of the microcontroller are connected to a bus driver connected to the control input of the switching unit and to the gates of the first and second field transistors of the voltage converter and to the gate of the additional field-effect transistor, the drain of the first field-effect transistor of the voltage converter is connected to the output terminal of the transformer primary winding, the middle terminal of which is connected to the output of the autonomous power source, and the second terminal is connected to the drain of the second field-effect transistor of the voltage converter, the sources of the first and second field-effect transistors of the voltage converter are connected to the source of the additional field-effect transistor and to the first input of the amplifier, and the drain additional transistor is connected to the bus of zero potential and to the second input of the amplifier, the source and drain of each field-effect transistor of the voltage converter is connected

Description

The utility model relates to the field of energy, and more specifically to the field of small energy - autonomous power sources, which can be widely used in various sectors of human activity, and numerous and diverse electrical appliances of household appliances, for example, can be used as power supplies for monitors, computers, televisions, audio, video systems, as charging and discharging devices for vehicle batteries, in power supplies, in navigation radio and light beacons, at weather stations, in welding units, for builders in the field, residents of regions with frequent power outages and owners of outlets without electricity, for rescuers and firefighters when working in smoky rooms, in heating systems in the form of gas boilers, for wind turbines, in devices control and protection of territories and premises protection systems, in microclimate devices and in other objects of various purposes.

A wide range of possible uses of the claimed utility model is due to its operation in numerous modes, convenience and ease of use and high reliability and stability when used in devices in residential, industrial, medical, etc. the premises.

The main task of power sources is the ability to adjust the output parameters of the energy that feeds numerous devices, characterized by stable current and voltage parameters. The inventive power source can also be used as a secondary power source, providing a predetermined current value.

One of the well-known power sources is the device described in US patent No. 4536696, publ. 08.20.85, based on the use of a voltage Converter. However, this device is characterized by insufficient reliability and low speed.

The known device is also unnecessarily high cost.

A known power source for field-effect transistors, presented in the description of the patent of the Russian Federation No. 2097897, oc.27.11.97g., Containing converters, filter, limiters and transformer.

A disadvantage of the known device is the low specific weight and size characteristics of the auxiliary power unit, which lead to low weight and size indicators of the device, especially with a low output power

Also known is a secondary power source according to the patent of the Russian Federation No. 2138113, published on September 20, 1999, containing a trigger, a filter, transistors,

stabilizer and logic block.

A disadvantage of the known power supply is the inability to work in a wide range of input power supply upon receipt of the required output power.

their autonomous power sources, which makes the design more expensive, but at the same time the output voltage can only be approximately called sinusoidal. Another disadvantage of the known device should be attributed to the fact that the recharge of an autonomous source in this device is not controlled and regulated in any way, and does not provide large moshes.

The technical result in the above patents is the elimination of all the above disadvantages. In addition, the patents described above provide, multi-mode operation of the device, reliable protection against inrush currents, high noise immunity, protection against switching on the wrong polarity of an autonomous power source, from overheating and overcurrent of current transistors, from short circuit on the output side and autonomous power source, as well as from overcharging and full discharge of the battery and low consumption at idle. In addition, in the inventive utility model for ease of operation, it is possible to connect a remote control, as a unit for receiving an input signal, to which communication can be performed both wired and wireless. The advantage of the claimed utility model is also low cost. In addition, it can be used as a charger for batteries and as a reducing agent for the latter, as well as a starting and charging device for car engines.

Another advantage of this power source through the use of a microcontroller is the ability to correct and modify the program and initial data, as well as output information to a computer to monitor the operation of the device. It can also be used to provide communication with a computer (or other input device, such as, for example, a programmer) for inputting initial data into memory.

This goal is achieved by the fact that in a multi-mode power source containing an autonomous power source, made in the form of a battery, a stabilizer, a filter, a voltage converter, consisting of two field-effect transistors with internal integrated diodes and a transformer, a switching unit, a bus driver, network sensors are introduced voltage and temperature, an additional field effect transistor with an internal integrated diode, a microcontroller, an input signal receiving unit and an amplifier, while the output is autonomous A power source is connected to the first input of the microcontroller and connected through a stabilizer to the power input of the microcontroller, the second and third inputs of which are connected respectively to the outputs of the amplifier and temperature sensor, the outputs of the microcontroller are connected to a bus driver connected to the control input of the switching unit and to the gates of the first and second field-effect transistors of the voltage converter and to the gate of the additional field-effect transistor, the drain of the first field-effect transistor of the voltage converter with dinene with the first terminal of the transformer primary winding, the middle terminal of which is connected to the output of the autonomous power source, and the second terminal is connected to the drain of the second field-effect transistor of the voltage converter, the sources of the first and second field-effect transistors of the voltage converter are connected to the source of the additional field-effect transistor, and the drain of the additional transistor is connected with a zero potential bus, the source and drain of each field-effect transistor of the voltage converter are connected to the anode and cathode of the corresponding internal of the integrated diode, the drain and source of the additional field effect transistor is connected to the first and second inputs of the amplifier, the terminals of the secondary winding of the transformer are connected to the inputs of the filter, the outputs of which are connected to the first group of information inputs of the switching unit, the output of which is the output of the power source, and the second group of information inputs connected to the terminals of the supply network and to the inputs of the network voltage sensor, the output of which is connected to the fourth input

a microcontroller, the fifth input of which is connected to an input signal receiving unit, while the microcontroller is configured to function in accordance with a program stored in its memory and is designed in response to signals received from an amplifier, a temperature sensor, an input signal receiving unit, an autonomous power source, and the network voltage sensor to generate pulses of a given duty cycle to control transistors, and is also configured to process and store signals received from the input unit of these signals and is designed to control changes in the parameters of the supply network and the value of the output voltage and control the charge of the autonomous power source, control the operating mode and temperature of field-effect transistors, in addition, the microcontroller is designed to set the time intervals of permissible excesses of the boundary parameters of the supply network and select the mode of autonomous or network power supply to control switching of the switching unit.

The utility model is illustrated by drawings.

In FIG. 1 presents a diagram of the inventive multi-mode power source,

in FIG. 2 is a diagram of a line voltage sensor.

The multi-mode power source contains an autonomous power source 1, made in the form of a battery, a stabilizer 2, a filter 4, a switching unit 9, voltage sensors 6 and temperature 5, a voltage converter consisting of two field-effect transistors 13 and 14 with internal integrated diodes, an additional a field-effect transistor 15 with an internal integrated diode and a transformer 12, a microcontroller 3, a bus driver 27, an input signal receiving unit 11, and an amplifier 10.

The microcontroller 3 controls the operation of the power supply circuit in accordance with the program located in its program memory. As a result, the microcontroller 3 itself has a block structure, which is shown in Fig. 1 and can perform the functions of measuring and comparing signals using Measurement and Comparison Units 16-19 and, based on these data, generate pulse sequences of different duty cycle using Pulse Shapers 20-22 and other control signals all components of the circuit through the Control Port 23 and the Communication Port with External Devices 24. In this case, the output of the autonomous power supply 1 is connected to the first input of the microcontroller 3 and through the stabilizer the mash 2 is connected to the power input of the microcontroller 3, the second and third inputs of which are connected respectively to the outputs of the amplifier 10 and the temperature sensor 5, the outputs of the microcontroller 3 are connected to the bus driver 29 connected to the control input of the switching unit 9 and to the gates of the field effect transistors 13 and 14 of the converter voltage and to the gate of the additional field-effect transistor 15, the drain of the field-effect transistor 13 of the voltage converter is connected to the first terminal of the primary winding of the transformer 12, the middle terminal of which is connected n to the output of the autonomous power source 1, and the second output to the drain of the field-effect transistor 14 of the voltage converter, the sources of the field-effect transistors 13 and 14 of the voltage converter are connected to the source of the additional field-effect transistor 15 and to the first input of the amplifier 10, and the drain of the additional transistor 15 is connected to the bus zero potential and the second input of the amplifier 10, the source and drain of each field-effect transistor of the voltage converter are connected to the anode and cathode of the corresponding internal integrated diode, the terminals of the secondary bmotki transformer 12 are connected to inputs of the filter 4, the outputs of which are connected to the first group of information inputs of switching 9, the output unit of which is the output of the power supply 8 and the second group of information inputs is connected to the supply terminals 7 and input line voltage sensor 6, the output

which is connected to the fourth input of the microcontroller 3, the fifth input of which is connected to the input signal receiving unit 11.

Microcontroller 3 which can be used as a microchip controller PIC16F870, contains an internal periphery which includes a multi-channel ADC, an internal reference voltage, a timer, a PWM generator and a control interface, it is also possible to implement microcontrollers without an internal periphery with corresponding external components. Transistors 13-15, for example, IRF3710 company International Rectifier. Filter 4 in its simplest form consists of smoothing, its capacitor. The input signal receiving unit 11 may consist of a buffer for a toggle switch or circuit, for example, on a photodiode with an amplifier for receiving a signal from a remote control.

The functioning of the claimed utility model when operating in various modes is as follows.

When the receiving unit receives input signals AND from outside the control action, whether it is a control toggle switch, a remote control or a signal from a computer, the device enters one of the modes of its functioning: Voltage converter. Charger (as well as submode, battery recovery). Uninterruptible power supply, with

appropriate display of modes on display devices, whether it be LEDs, LCDs, etc.

When the inventive power source is operating in the DC-DC converter mode, it provides the conversion of the direct voltage of an autonomous power source 1 of 12-24 V or more into an alternating voltage of 220 V, with a frequency of 50-60 Hz. In this case, when the microcontroller 3 receives the corresponding signals from the network voltage sensor 6, the amplifier 10, or from an autonomous power source 1, the microcontroller 3 generates pulse sequences with a controlled duty cycle from the corresponding output, which pass through the bus former 29 to the gates of the transistors 13 and 14 and through the transformer 12 filter 4 and switching unit 9 provides at the output 8 both a sinusoidal (at low loads) and a rectangular (at high loads) waveform, as well as their compilation and medium loads. Also, if there is an additional low-voltage secondary winding on the transformer 12, the output of this winding together with the electrodes can be used as a welding machine.

In this mode, the device operates as follows:

A typical circuit of a single-phase converter on field-effect transistors 13 and 14 with internal integrated diodes with a transformer 12 is used (another type of a two-phase converter with a transformer without a middle tap on the primary winding using four transistors with internal integrated diodes can be used).

The additional transistor 15 in this mode is opened by the microcontroller 3 through the bus driver 29 and forms a small resistance, as a result, a voltage proportional to the current flowing through this transistor arises between the drain and the source, after amplification on the amplifier 10, it is supplied to the Measurement and Comparison block 17 of the microcontroller 3, which compares with the reference voltage inside the microcontroller and the difference value is supplied to the pulse former 20 of the microcontroller 3. As a result, the microcontroller 3 generates pulses of duty cycle which depends on the value of the difference between the reference voltage and the output of the amplifier and gives them through the bus driver 29 to the gates of the transistors 13 and 14 which switch the current in the primary winding of the transformer 12, and a voltage of 220 V is generated on the secondary winding of this transformer using the output filter 4. Similarly

the microcontroller 3, by means of the Measurement and Comparison unit 16, determines the voltage at the autonomous power supply 1, through the Measurement and Comparison unit 18 and the temperature sensor 5 determines the temperature on the transistors 13-15 and through the Measurement and Compare unit 17 determines the current flowing through the transistor 15 and using this data is corrected by the duty cycle of the pulse shaper 20 so as to maintain the voltage at the output of the transformer 12 - 220 V as sinusoidal as possible (a variant of more accurately maintaining the output voltage is possible using an additional sensor of the mains voltage connected to the outputs of the secondary winding of the transformer) and, if necessary, turns off the converter if the parameters are outside the limits, be it a full discharge of an autonomous power supply 1, the maximum allowable current flowing through transistors 13-15, in case of a short circuit or unacceptable load at the output 8, or the excess of the operating temperature of the transistors 13-15.

Also, the microcontroller 3 through the control port 23 and the bus driver 29 commutates using the switching unit 9, the converter network to the output 8.

When the inventive power supply is operating in the charger mode, it provides the conversion of the alternating voltage of the input of the supply network 7 (usually an industrial network 220 V) through the switching unit 9, filter 4, transformer 12 and internal integrated diodes of transistors 13 and 14 into a constant voltage 12- 24 V and more formed at the outputs of power source 1, for recharging it. At the same time, when the microcontroller 3 receives the corresponding signals from the network voltage sensor 6, amplifier 10, or from an autonomous power source, the microcontroller 3 generates pulse sequences with a controlled duty cycle from the corresponding output, which are supplied to the gates of transistors 13-14 and ensures the optimal value of the flowing current to the autonomous power source 1.

In this mode, the device operates as follows:

The charge mode of the autonomous power source 1 is carried out in the presence of voltage in the supply network 7, which is supplied to the secondary winding of the transformer 12 and an alternating voltage of 1224 V or more is obtained on its primary winding.

In this mode, the transistors 13 and 14 are closed by the microcontroller 3 by means of a bus driver 29. The internal integrated diodes of these transistors form a half-wave single-phase rectifier (in the case of using a push-pull converter circuit with four transistors, their internal diodes form a half-wave bridge rectifier circuit).

To increase the flowing current, diodes can be shunted by the low resistance of the transistor itself at the moment when the charging voltage generated on the primary winding of the transformer 12 exceeds the voltage on the autonomous power source 1. For this, the microcontroller 3, through its Measurement and Comparison 19 unit and the voltage sensor 6, monitors value and polarity of the supply network 7 and, through its pulse shaper 21, organizes the inclusion of transistors 13-14 so that they work on the principle of a diode bridge.

That is, with a positive half-wave of network 7 and an excess of voltage on the autonomous power supply 1, the microcontroller 3 turns off the transistor 13 and turns on the transistor 14 (corresponding to the flow of current into the autonomous power source 1), and with a negative half-wave of the network 7 and excess voltage on the autonomous the power source 1 - turns off the transistor 13 and turns on the transistor 14, which again corresponds to the flow of current into an autonomous power source. At the same time, due to the practical lack of resistance of transistors sharply

the heat release on them decreases and makes it possible to flow large charging currents.

Also, the microcontroller 3, using the Measurement and Comparison unit 18, measures the flowing current in the primary circuit of the transformer 12 and outputs to the transistor 15, by means of a pulse shaper 22 and a bus shaper 29, a pulse sequence of a certain duty cycle that limits the average current flowing to charge an autonomous power source 1.

Using the Measurement and Comparison Units 16 and 17, the microcontroller 3 controls the voltage at the stand-alone power source 1 and the temperature at the transistors 13-15 and turns off the pulse shaper 21 if the parameters are outside the acceptable range, be it the full charge of the stand-alone power source 1, the maximum allowable current caused by a short circuit on an autonomous power source 1, or an excess of the operating temperature of transistors 13-15.

Also, the microcontroller 3 through the control port 23, the bus driver 29, and the switching unit 9 switches the network 7 to the output 8.

Through the input signal receiving unit 11, it is possible to instruct the microcontroller 3 to execute several charge attempts with different charge currents providing a sub-mode of battery recovery.

When the inventive power source is operating in the uninterrupted power supply mode, provided there are no or unstable voltage parameters at the input of the network 7, it provides the conversion of the direct voltage of an autonomous power source 1 of 12-24 V or more into an alternating voltage of 220 V, with a frequency of 50-60 Hz , in accordance with the mode of the Voltage Converter and through the switching unit 9 transmits it to the output 8. It is possible when a diesel-gas generator is connected to the switching unit 9, then when the voltage gets into ode network 7 first switched voltage converter mode, and after exhaustion of the resource independent source 1, launched dizelbenzinovy voltage generator and connected to the output 8.

If the microcontroller 3 detects, through the sensor of the mains voltage 6, a voltage at the input of the network 7, the microcontroller 3 switches this voltage to output 8 using its control port 23, the SHAFT shaper 29 and the switching unit 9. Moreover, when the microcontroller 3 receives it via its Measurement and Comparison Unit 16 conditions of incomplete charging of an autonomous power source 1 device includes the Charger mode.

The transistor 15 also provides protection against switching on an autonomous power source 1 of the wrong polarity, for this it is turned on so that the internal integrated diode is turned on to meet the internal integrated diodes of transistors 13 and 14, i.e. runoff to the bus of zero potential. With all transistors closed, the current in the circuit does not pass regardless of what polarity the autonomous power source is connected to, in the case of an incorrect polarity, the circuit does not work, the transistors are closed and the current in the primary winding of the transformer does not pass.

The voltage sensor 6 according to one of the possible embodiments shown in figure 2, contains a transformer 26, a voltage divider made on resistors 27 and 28, and the ADC 25, while the sensor inputs are the terminals of the primary winding of the transformer 26, the terminals of the secondary winding of which the divider is connected to the ADC 25, the output of which is the output of the network voltage sensor 6.

Measurements and Comparisons 19 of the microcontroller 3, in which it is compared with the value recorded in the microcontroller program.

The analysis of patent and literary sources showed that the totality of the characteristics indicated in the claimed power source is not previously described and is not known, and it is this combination that provides functional completeness, completeness of the technical solution and achievement of the goal.

It is obvious that the proposed preferred implementation of the inventive power source of the invention is one of the possible, various modifications of which, without changing the nature of the described power source, can find application in various fields of production and human life.

Claims (1)

A multimode power source containing an autonomous power source made in the form of a battery, a stabilizer, a filter, a voltage converter, consisting of two field-effect transistors with internal integrated diodes, and a transformer, characterized in that a switching unit, a bus driver, network sensors are inserted into it voltage and temperature, an additional field effect transistor with an internal integrated diode, a microcontroller, an input signal receiving unit and an amplifier, while the output of an autonomous source the power supply is connected to the first input of the microcontroller and connected through the stabilizer to the power input of the microcontroller, the second and third inputs of which are connected respectively to the outputs of the amplifier and temperature sensor, the outputs of the microcontroller are connected to a bus driver connected to the control input of the switching unit and to the gates of the first and second field transistors of the voltage converter and to the gate of the additional field-effect transistor, the drain of the first field-effect transistor of the voltage converter is connected to the output terminal of the transformer primary winding, the middle terminal of which is connected to the output of an autonomous power source, and the second terminal is connected to the drain of the second field-effect transistor of the voltage converter, the sources of the first and second field-effect transistors of the voltage converter are connected to the source of the additional field-effect transistor and to the first input of the amplifier, and the drain additional transistor is connected to the bus of zero potential and to the second input of the amplifier, the source and drain of each field-effect transistor of the voltage converter is connected s with the anode and cathode of the corresponding internal integrated diode, the terminals of the secondary winding of the transformer are connected to the inputs of the filter, the outputs of which are connected to the first group of information inputs of the switching unit, the output of which is the output of the power source, and the second group of information inputs is connected to the terminals of the mains and to the inputs a network voltage sensor, the output of which is connected to the fourth input of the microcontroller, the fifth input of which is connected to the input signal receiving unit, while the microcontroller made with the possibility of functioning in accordance with the program recorded in its memory and designed to generate pulses of a given duty cycle for controlling transistors in response to signals received from an amplifier, a temperature sensor, an input signal receiving unit, an autonomous power source and a network voltage sensor, and also made with the ability to process and store signals received from the input signal receiving unit and is designed to control changes in the parameters of the supply network and the value of the output voltage Nia and charge control autonomous power source, operation control and temperature field mode transistors, in addition, the microcontroller is used to set values of allowable slots exceedances boundary parameters mains and select autonomous mode or mains supply for controlling switching of the switching unit.