RU41555U1 - CHARGING AND CHARGING DEVICE - Google Patents

Abstract

The utility model relates to emergency or standby power supply schemes in which the distribution system is disconnected from a normal source and connected to a standby source with automatic switching, with devices for charging standby batteries from the AC mains through converters, and can be used, for example, as a system component uninterruptible power supply. The task is to develop a device with high efficiency, providing battery charging, as well as switching the power of the AC output circuit to a backup power source in the event of an AC mains failure or deviation of its value from the specified parameters, with the possibility of reconnecting the output circuit to an AC network current in case the AC voltage corresponds to the specified parameters. This problem is solved as follows. The switching-charging device contains a network rectifier and a measuring rectifier, the output of the network rectifier is connected to the supply circuit of the power keys of the charging power source, the output of the measuring rectifier is connected to the inputs of the comparators of the lower and upper voltage values, the outputs of the comparators of the lower and upper voltage values are connected to the input of the switching relay, Relay switching outputs are connected to the input of the mains voltage, the input of the emergency power supply and the network output of the device. The output of the PWM control unit is connected to the input of the control circuit of the power keys, the output of the control circuit of the power keys is connected to the input of the power keys of the charging power source, connected in a half-bridge circuit. The outputs of the power keys of the charging power source are connected to the primary winding of the charging power transformer, the outputs of the secondary winding are connected to the input of the rectifier, and the output of the rectifier is connected to the input of the charging voltage comparator and to the input of the current limiting unit, the output of the charging voltage comparator and the measuring output of the current limiting unit are connected with the input of the feedback optocoupler through diodes, the output of the feedback optocoupler is connected to the control input of the PWM control unit. The output of the current limiting block is connected to the input of the battery reverse polarity protection block, the output of the battery reverse polarity protection block is connected to the battery input. The switching-charging device implements protection against the wrong polarity of the battery connection, current protection and negative feedback on current and voltage to stabilize the value of the charging output voltage and limiting the output charging current, and also a circuit for switching the emergency power supply circuit and network voltage to the device output is implemented depending on the parameters of the mains voltage. The proposed utility model solves the problem of ensuring battery charging, as well as switching the power supply of the AC output circuit to the backup power source in case of loss of AC voltage or deviation of its value from the specified parameters, with automatic reverse connection of the output circuit to AC power in case of voltage AC power will meet the specified parameters. In this case, unlike similar devices, the power of the AC output circuit is connected either to the mains supply or, when the mains voltage deviates from the set parameters, to a backup power source with automatic reverse connection of the output circuit to the AC network if current will correspond to the set parameters.

Description

The utility model relates to emergency backup power supply schemes in which the distribution system is disconnected from the normal source and connected to the backup source with automatic switching, with devices for charging backup batteries from the AC mains through the converters, and can be used, for example, as a system component uninterruptible power supply.

Known automatic pulse charger according to patent RU 2071625 C1, 1992. The device is based on a block diagram in which, in addition to a transformer, a rectifier, a current-limiting current element, a control element that limits the current and voltage of the charge, and a short circuit protection unit in AB banks and incorrect switching on the polarity, an element is inserted that protects the battery from a short circuit on the line connecting it to the charger, as well as two indicators: red, indicating emergency mode, and green - normal th charging the battery. The control element forms a charging current during storage of the battery, equal to the self-discharge current of the battery. which excludes its full discharge and provides constant readiness for work. The protection unit performs a diagnostic function by comparing the battery EMF with the reference voltage of a working battery.

The disadvantage of the device according to the patent RU 2071625 C1, 1992. We can consider the low efficiency of the transformer power source, the lack of emergency switching circuit voltage.

The onboard charger according to patent RU 2101830 C1, 1996 is also known. Summary of the invention: by introducing into the device two relays, two 4 OR-NOT logic elements, a current sensor of a power converter and an auxiliary power supply in the device, the galvanically isolated voltage is stabilized at the load . Connecting an auxiliary power supply to a rechargeable battery provides protection against sudden on-off power supply.

The device operates as follows. The control unit, implemented on logic elements, generates control signals of the day transistor switches. The AC mains voltage is rectified, and then, using a half-bridge pulse voltage converter, it is converted to DC voltage to charge the battery. A high-frequency inductor provides soft PWM control and a more explicit dependence of the amplitude value of the voltage on the secondary winding of the transformer on the duration of the control pulse. This is necessary to expand the range of variation of the output voltage of the converter and to provide a margin for control (compensation). A negative voltage feedback is introduced in the circuit to stabilize the output voltage. The constant voltage taken from the output of the device is supplied to the measuring circuit of the control unit and compared with the setpoint voltage. Then the difference between the output voltage and the set voltage, which is a mismatch signal, is converted into the duration of the control pulses generated by the control unit according to the PWM principle, which depends on the amplitude of the mismatch voltage. Then these pulses are fed to transistor switch control circuits, which are galvanically isolated nodes with separate power from the transformer windings and optical isolation by a control signal at the input, connected with the control inputs of the transistor switches. Thus, the feedback loop closes and provides with a certain accuracy

Equal output voltage to voltage setting. The relays introduced into the device provide protection against power failure by switching the operating mode of the control unit.

The disadvantage of the device according to the patent RU 2101830 C1 1996 can be considered the lack of emergency switching circuit of the mains voltage and the use of relays with low speed in the protection against loss of mains voltage, which reduces the reliability of the device.

Of the above analogues in technical essence, the closest to the proposed utility model is the device according to patent RU 2101830 C1 1996. It is accepted as a prototype.

The task was: to develop a device with high efficiency, providing battery charging as well as switching the power of the AC output circuit to a backup power source in the event of a failure of the AC mains voltage or deviation of its value from the set parameters, with automatic reverse connection of the output circuit to the AC network current in case the AC voltage corresponds to the specified parameters.

This problem is solved as follows, the switching charger contains a network rectifier and a measuring rectifier, the output of the network rectifier is connected to the power circuit of the power keys of the charging power source, the output of the measuring rectifier is connected to the inputs of the comparators of the lower and upper voltage values, the outputs of the comparators of the lower and upper voltage values connected to the input of the switching relay, the switching outputs of the relay are connected to the input of the mains voltage, the input of the emergency power supply and network output device. The output of the PWM control unit is connected to the input of the control circuit of the power keys, the output of the control circuit of the power keys is connected to the input of the power keys of the charging power source, connected in a half-bridge circuit. The outputs of the power keys of the charging power source are connected to the primary winding of the charging power transformer, the outputs of the secondary winding are connected to the input of the rectifier, and the output of the rectifier is connected to the input of the charging voltage comparator and the input of the current limiting unit, the output of the charging voltage comparator and the measuring output of the current limiting unit are connected through diodes with feedback optocouplers input; feedback optocouplers output is connected to the control input of the PWM control unit. The output of the current limiting block is connected to the input of the battery protection reverse polarity protection block, the output of the battery reverse polarity protection block is connected to the battery pole. The switching and charging device implements protection against the wrong polarity of connecting the battery, current protection, and negative feedback on current and voltage to stabilize the value of the charging output voltage and limiting the output charging current, also a circuit for switching the emergency power supply circuit and network voltage to the device output is implemented depending on the parameters of the mains voltage.

Further, the essence of the utility model is illustrated in the drawing, which shows:

- figure 1 is a functional diagram of a switching-charging device. The device comprises: a PWM control unit 1, a control circuit of power switches 2, power switches 3 and 4 of a charging power source, a transformer of a charging power source 5, capacitors 6 and 7, a rectifying diode 8, a smoothing capacitor 9, a choke 10, a network rectifier 11, a measuring rectifier 12, charging voltage comparator 13, current limiting unit 14, diodes 15 and 16, feedback optocoupler 17, upper voltage value comparator 18, lower comparator

voltage values 19, diodes 20 and 21, the switching relay 22, the unit is protected from the wrong polarity of the battery 23.

Switching charger works as follows. The network voltage is supplied to the device’s network input, then to the network rectifier 11 and the measuring rectifier 12. The constant voltage from the output of the network rectifier 11 is supplied to the power switches of the charging power supply 3 and 4. The voltage from the output of the measuring rectifier 12 is supplied to the lower and upper value comparators voltage 18 and 19, where it is compared with the specified voltage values of the upper and lower levels U _in and U _n , in case of input voltage mismatch with the specified values, the comparators 18 or 19 give out The input voltage of the input of the switching relay 22, which leads to switching the contact group of the relay so that the input of the emergency power supply is switched to the output of the device. If the mains voltage complies with the set limits, the comparators do not work and the contact group of the relay commutes the mains voltage to the output of the device. The PWM control unit 1 generates rectangular control pulses, phase shifted by 180 °, with a protective pause between them. The control pulses from the output of the PWM control unit are supplied to the control circuit of the power switches 2. Power switches 3 and 4 in conjunction with the transformer 5 are a circuit of the charging power source, implemented according to the half-bridge switching circuit. The smoothing capacitor 9 and the inductor 10 prevent the high-frequency component of the output voltage of the transformer from penetrating the battery charging circuit. The circuit introduced current protection and stabilization of the output voltage. The voltage taken from the output of the comparator of the charging voltage 13 and the measuring output of the current limiting unit 14 is supplied to the feedback optocoupler and, if the parameters of the output charging voltage or current do not match the specified values, the signal from the output of the optocoupler fed to the input of the PWM control unit leads to changing the duration of the control pulses input at power keys, which in turn leads to the return parameters in the charging voltage limits specified charging voltage values U _s and the maximum of the current set current limiting unit 14.

The protection unit against the wrong polarity of connecting the battery 23 ensures the passage of charging voltage to the battery in the case of the correct polarity of its connection and prohibits the passage of current in the output circuit of the charger in the event of an incorrect polarity of connecting the battery.

Thus, the proposed utility model solves the problem of charging the batteries, as well as switching the power supply of the AC output circuit to the backup power source in case of loss of AC voltage or deviation of its value from the set parameters, with automatic reverse connection of the output circuit to AC in the event that the AC voltage meets the specified parameters. In this case, unlike similar devices, the power of the AC output circuit is connected either to the mains supply or, when the mains voltage deviates from the set parameters, to a backup power source with automatic reverse connection of the output circuit to the AC network in case of AC voltage current will correspond to the set parameters.

Claims (1)

A switching charger containing a network rectifier and a measuring rectifier, the output of the network rectifier is connected to the supply circuit of the power keys of the charging power source, the output of the measuring rectifier is connected to the inputs of the comparators of the lower and upper voltage values, the outputs of the comparators of the lower and upper voltage values are connected to the input of the switching relay, switching relay outputs are connected to the input of the mains voltage, the input of the emergency power supply and the network output of the device, the output of the block M control is connected to the input of the control circuit of the power keys, the output of the control circuit of the power keys is connected to the input of the power keys of the charging power source connected in a half-bridge circuit, the outputs of the power keys of the charging power supply are connected to the primary winding of the charging power transformer, the outputs of the secondary winding are connected to the input rectifier, and the rectifier output is connected to the input of the charging voltage comparator and the input of the current limiting unit, the output of the charging voltage comparator and measuring output the current limiting unit is connected via diodes to the feedback optocoupler input, the feedback optocoupler output is connected to the control input of the PWM control unit, the output of the current limiting unit is connected to the input of the battery protection block from the wrong polarity, the output of the battery protection block from the wrong polarity is connected to the pole battery, characterized in that the power of the AC output circuit is connected either to the mains supply, or, when the mains voltage deviates from the set parameters, to the backup a power source with automatic reverse connection of the output circuit to the AC network in case the AC voltage meets the specified parameters.