RU2387054C2 - Computer-aided software-hardware complex for charging and aging 'prisma' storage batteries - Google Patents

Abstract

FIELD: electrical engineering. ^ SUBSTANCE: invention relates to appliances intended for maintenance of storage batteries, particularly lead starter storage batteries with capacity approximating to 200 A/h. Proposed software device controlling storage battery charging/discharging consists of system controller (3) and PC (4). Software-controlled measuring adapters (10) with indication panels (11) convert the data from voltage transducers (9) and electrolyte temperature pickups (8) into digital form. Indication panels (11) display the storage battery state, i.e. connection, charging, discharging, interlocking, storage battery charge level scale, operation, availability of communication in charging/discharging control circuit. Power supplies (6) are implemented as pulsed program-controlled devices. Discharge circuits represent unit (7) of discharge resistors. Data exchange between power supplies (6), adapters (10), unit of discharge resistors (7) and control device (3, 4) is effected via interface (2). ^ EFFECT: possibility to charge high-power storage batteries and longer life. ^ 3 cl, 1 dwg

Description

The invention relates to devices for servicing and maintaining electric batteries, in particular rechargeable batteries, in particular lead starter batteries, with a capacity of up to 200 A / hour.

A known complex for charging and training batteries (AB), containing a common power source, a voltmeter connected to its output, charging cells connected in parallel with the power source and including several batteries, charge-discharge switches connected in series with the batteries, load resistor , ammeter, fuses. The system allows you to charge the battery at a constant charge current through the charge-discharge switches, which switch manually, as well as conduct a control and training cycle by alternately discharging and charging the battery. The battery charge starts immediately when it is connected to a power source and stops immediately after it is turned off. The magnitude of the required voltage is supported by a voltmeter. The value of the charging current is set by the ammeter at the beginning of the battery charge by means of a load rheostat ("Lead starter batteries" / Manual / approved deputy head of the Main Armored Directorate and deputy head of the Automotive Department, M .: Military Publishing House of the Ministry of Defense of the USSR, 1983 , Fig. 41, p. 51; Fig. 42, p. 52).

A disadvantage of the known complex is the impossibility of automatic monitoring of the state of the battery as a whole, and of individual batteries of the battery in the process of charge and discharge, as well as the inability to automatically control the process of charge and discharge.

Closest to the proposed device is an automated software and hardware complex for charging and training batteries, including M charging modules connected by an address-information network and connected through it to the host computer, with each of the M charging modules including an address-information bus connected with address and information highway, several rechargeable batteries, power supply, module controller connected to address and information bus, switch, start indicators and / continuation of the charge / discharge process, the battery ready for use, an emergency. Each battery (charging cell) is connected through a distribution and switching unit to the corresponding charge-discharge channel, which contains a switching device, a current control device, a color-switching device for indicators and light indicators (RF patent No. 2134477, H02J 7/10, H01M 10 / 42, 08/10/99).

The well-known complex allows you to programmatically control the state of all ABs at the same time after a specified period of time: put on charge / discharge, removed from charge / discharge, charged / undercharged to rated capacity, operational / faulty. According to the results of a program survey, also from the host computer, simultaneously through the module controllers, the corresponding commands are issued to the distribution and switching units: about the beginning / cessation of charge / discharge and the inclusion of the corresponding light indication. For each survey result, the light indication allows you to visually control: the beginning / continuation of the charge / discharge process, the battery’s readiness for operation, the presence of a battery emergency, which can be caused by a battery malfunction, incorrect actions by the maintenance personnel.

The disadvantage of this complex is that the management and control of the charge / discharge of the battery in it does not provide for the participation of the operator, since the controlled parameters and time moments of control are strictly determined by the software product embedded in the host computer. The latter excludes the possibility of working in an interactive mode: the operator is a computer, which does not allow changing the AB control procedure, performing real-time selective control of the battery charge / discharge process, and also does not allow controlling the parameters of individual AB batteries. The lack of dialogue mode also leads to the inability to obtain graphical and quantitative information about the battery charge / discharge process in real time, which reduces the information content of the known complex, and therefore, worsens the battery charge / discharge conditions. The presence of only light indicators that perform a signaling role does not give a complete picture of the state of the battery. In addition, the number of displayed parameters characterizing the state of the battery and their selection: the beginning / continuation of the charge / discharge process, the battery’s readiness for operation, the presence of a battery emergency, also does not provide a complete picture of the battery status in real time. The ability to control the battery only at programmed time points and only based on the results of a collective survey requires accurate timing to avoid overcharging the battery and other undesirable situations. At the same time, since the known complex uses an AA charge with a time-varying current at constant voltage, and the system is controlled by software in a mode that does not provide for a dialogue mode, careful elimination of emergency batteries by the degree of initial AA discharge is necessary to exclude emergency situations to obtain the same initial conditions to set the charging current and further control the charge / discharge.

The absence of a dialogue mode in the well-known complex excludes the possibility of constant real-time monitoring of the battery maintenance process with obtaining graphical and quantitative information, which worsens the battery charge / discharge conditions and reduces their service life.

In addition, the well-known complex allows servicing only low-power batteries designed for mining helmets. At the same time, the low power of the charge system, as well as the lack of hardware and connections with the host computer, which make it possible to measure and control the temperature of the electrolyte, do not allow using the known system for charging powerful electrolyte starter batteries, for example, starter batteries for caterpillar vehicles and trucks.

The claimed invention solves the problem of creating an automated hardware-software complex for charging and training batteries "Prism", the implementation of which allows to achieve a technical result, consisting in the possibility of charging electrolyte batteries, including powerful ones, in increasing the battery life due to the sparing charge mode / discharge.

The essence of the claimed invention lies in the fact that in the automated software and hardware complex for charging and training batteries "Prism", which includes a control software device, M charging modules, combined address-information network with a control software device, each of M charging modules contains a storage battery (AB), a power source, a discharge device, new is that the address-information network is an interface, and the control software the triple consists of a system controller and a personal electronic computer (PC), in addition, the power supply is made pulsed program-controlled, and the discharge device is made in the form of a block of discharge resistors, while a software-controlled measuring adapter and connected to it are additionally introduced into each module the input is an electrolyte temperature sensor and a voltage sensor, while the electrolyte temperature sensor is installed in the middle battery in the hole for filling the electrolyte, and the sensor is voltage The unit is installed with the ability to measure voltage both on the battery and on individual batteries of the battery, in addition, the software-controlled measuring adapter is equipped with a display panel configured to display information: inclusion; charge; discharge; blocking; battery charge scale; Work; network connectivity; while the output of the power source and the output of the block of discharge resistors are connected and connected to the input of the battery, and the inputs and outputs of the measuring adapter, the inputs and outputs of the block of discharge resistors and the inputs and outputs of the power source are connected to the system controller and PC via the interface. The block of bit resistors contains n resistors, where n = 2, 3, ..., and is configured to connect them in various configurations. The power source is multi-channel with the ability to programmatically select a channel.

The technical result is achieved as follows. Due to the fact that the control software device consists of a system controller and a personal computer in the claimed automated software and hardware complex for charging and training the AB, real-time capability is provided for the mixed control of the operation of the AB charge complex, namely, with the participation of the operator, a PC-dialogue mode, or completely in automatic mode - programmatically. The presence of the dialogue mode allows you to control the charge / discharge mode of the battery not only at programmed time points, but also selectively at the discretion of the operator. The ability to continuously monitor the battery charge / discharge process, its individual batteries provides a sparing mode of battery maintenance and extends its service life. At the same time, the range of monitored parameters is expanding, which provides a sufficient amount of information that allows you to make operational decisions to avoid overcharging the battery and the occurrence of other undesirable situations. It also provides a gentle battery charge mode.

In addition, the presence of the dialogue mode provides the possibility of changing the order of management and control over the operation of the complex, which allows, in turn, to selectively control not only the final results of the charge process, but also intermediate stages. It also expands the amount of information about the battery charge / discharge mode and provides a sparing mode of the battery charge / discharge process, increases their service life compared to the prototype. Moreover, in the claimed complex in interactive mode, it is possible to obtain graphical and quantitative information directly on the PC display screen. The combination of program control with the control of the charge / discharge process through the operator allows you to select and control the general condition or parameter of interest at any time in real time not only the battery, but also any of the batteries included in it. At the same time, the ability to graphically and quantitatively display the state of the battery gives a complete picture of the state of the battery in real time. It also expands the information on the battery charge / discharge mode and provides, in comparison with the prototype, the sparing mode of the battery charge / discharge process, increases their service life.

A software-controlled measuring adapter, the inputs of which are connected to the outputs of the voltage sensor and the electrolyte temperature sensor, converts their output signals into a digital code, providing the possibility of entering information through the interface into the system controller and PC about the voltage at the terminals of the battery, the voltage at the individual batteries of the battery, the temperature of the electrolyte , the correct connection of AB. Moreover, the presence of the display panel, configured to display information from the adapter: inclusion; charge; charge; blocking; battery charge scale; Work; the presence of communication over the network, - provides the possibility of visual operational control of the maintenance of the battery, which also provides a gentle battery charge mode.

The introduction of a voltage sensor connected to the battery with the ability to measure voltage on the battery, as well as voltage on individual batteries of the battery in the control and training cycle, allows you to continuously measure and control the voltage on them, which, in turn, allows the claimed complex charge the battery at a constant charge current. With this method of charging the battery, the magnitude of the charging current is kept constant. As a result, while simultaneously servicing the batteries, their selection into groups is simplified, since in this case the batteries are selected according to only one criterion: according to the operating voltage of the battery, in contrast to the prototype, where the batteries are grouped by operating voltage and the amount of battery discharged. This simplifies the maintenance of the battery when setting the charge / discharge mode and reduces the likelihood of overcharging the battery, which provides sparing service conditions for the battery and, therefore, extends their service life.

The introduction of a voltage sensor connected to the battery with the ability to measure voltage on the battery, as well as the voltage on the individual batteries of the battery in the control-training cycle mode and the temperature sensor of the electrolyte installed in the middle battery in the hole for filling the electrolyte, provides the ability to control the electrolyte batteries during charging / discharge. The implementation of a pulsed power source allows for low voltages to have large charge / discharge currents. Together, this allows you to charge powerful starter electrolyte batteries. In addition, the presence of a discharge device and an electrolyte temperature sensor makes it possible for electrolyte batteries to carry out a control and training cycle (battery training): a full battery charge, a control discharge, and a final battery charge. This allows you to determine the residual capacity of the battery, and therefore, evaluate the performance of the battery and set the charge mode correctly, which extends the life of the battery.

The implementation of the discharge device in the form of a block of discharge resistors, which contains n resistors, where n = 2, 3, ..., with the possibility of their software connection in various configurations allows, through communication with the system controller, to form a discharge circuit with the required rating of the discharge circuit resistance for a specific AB, which provides a sparing mode of discharge AB, and in addition, unifies the discharge device, and therefore the complex as a whole.

The execution of the power supply programmatically controlled allows you to fully automate the battery charge / discharge process. Moreover, in conjunction with the proposed embodiment of the discharge device, this allows the charge and the control and training cycle to be performed simultaneously by several powerful electrolyte batteries with the provision of the electrical modes required for each battery.

From the above it follows that the introduction into each module of an automated software and hardware complex for charging and training the AB of programmable measuring adapters, the inputs and outputs of which are connected to the interface, as well as the introduction of voltage sensors and electrolyte temperature sensors, the outputs of which are connected to the inputs of the corresponding adapters moreover, voltage sensors are installed with the ability to measure voltage both on the battery and on individual batteries of the battery, and the electrolyte temperature sensors are installed in each battery in the middle battery into the hole for filling the electrolyte, and the execution of the power supply pulse program-controlled allows not only to make the battery charge / discharge process fully programmable, but also to charge electrolyte batteries, including powerful ones. Moreover, the execution of the control software device consisting of a system controller and a PC provides control mobility due to the possibility of using the dialogue mode in the control. As a result of the possibility of obtaining current information about the state of the battery in graphical form on the display screen in real time: the results of selective or continuous monitoring of the battery charge process, the number of monitored parameters increases, and it is also possible to perform selective control of the parameters of the charge / discharge mode of individual batteries in real time. This allows you to create a sparing charge / discharge mode for the battery, which extends their service life.

In addition, the ability to work in interactive mode allows you to expand the amount of information in the reporting documents of accounting and the technical condition of the battery, which also increases the battery life.

Thus, the proposed automated hardware-software complex for charging and training batteries “Prism” during implementation provides a technical result consisting in the possibility of charging electrolyte batteries, including powerful ones, in increasing the battery life due to the sparing charge / discharge mode.

The drawing shows a block diagram of an automated software and hardware complex for charging and training batteries "Prism". The automated hardware-software complex for charging and training batteries “Prism” contains M charging modules 1, connected by an interface 2 and connected through it to the system controller 3 and PC 4. Each of the M modules contains AB 5, a pulse program-controlled power supply 6 a discharge device 7, which is made in the form of a block of discharge resistors; an electrolyte temperature sensor 8, mounted in the middle battery AB 5 in the hole for filling the electrolyte; voltage sensor 9, installed with the ability to measure voltage on AB 5, as well as voltage on individual batteries AB 5 in the control and training cycle; software-controlled measuring adapter 10, equipped with a display panel 11, configured to display information: inclusion; charge; discharge; blocking; battery charge scale; Work; network connectivity. The output of the power source 6 and the output of the block of discharge resistors 7 are connected and connected to the input of AB 5. In addition, the outputs of the voltage sensor 9 and the sensor 8 of the electrolyte temperature are connected to the corresponding inputs of the measuring adapter 10, and the power source 6, the measuring adapter 10 and the block of discharge resistors 7 are connected by inputs and outputs to the system controller 3 and the PC 4 through the interface 2. The block of bit resistors 7 contains n resistors, where n = 2, 3, ..., and is made with the possibility of their software connection in various configurations. The power source 6 is made multi-channel with the possibility of program channel selection.

For the interaction of the hardware of the claimed automated software and hardware complex for charging and training batteries "Prism" as interface 2 can be used, for example, the RS-485 Modbus Rtu interface.

The voltage sensors 9 are a wire ending in a contact element, for example, of the type “crocodile”. In this case, the “crocodile” is connected to the controlled terminals of the AB or to the battery of the AB, and the second end of the wire is connected permanently to the adapter.

The temperature sensor 8 can be performed, for example, on the chip AD22100K1. The output of the temperature sensor 18 is a voltage proportional to the temperature.

The measuring adapter 10 is a controller that, either programmatically or at the signal of an operator with a PC, performs voltage control at the terminals of the battery, voltage control at individual sections of the battery in the control-training cycle, control of the electrolyte temperature, and control of the correct connection of the battery. The controller is controlled via the RS-485 Modbus Rtu interface. Display panel with information display: inclusion; charge; blocking; battery charge scale; Work; the presence of communication over the network, - can be performed, for example, on LEDs.

Software-controlled measuring adapters 10 can be performed, for example, on a microprocessor PIK18F252, at the input of which an analog switch is installed, made, for example, on a field-effect transistor 2N7002LT1. In the example of the complex, the adapter is made 4-channel.

As a software control device consisting of a system controller 3 and a PC 4, for example, a Pentium IV type personal computer can be used.

In the claimed complex, the control software device (system controller 3 and PC 4) is designed to control a hardware-software complex for charging and training batteries, which, when the complex is executed, allows real-time operation in a fully automatic mode to serve up to 160 AB. In the claimed complex, the system controller 3 and PC 4 allow, in the automatic mode, after connecting the AB 5 to perform: AB correctness control; auto-detection of the connected battery (12 V 24); control of the temperature of the electrolyte and protection against overheating of the battery by means of automatic shutdown of the battery calculation of the time to perform a charge or discharge AB; determination of approximate battery capacity; auto-correction of the input electrolyte density depending on the electrolyte temperature; voltage control at the terminals and batteries of the battery at the CTC; automatic transition from the current of the first to the current of the second stage; control of the minimum and maximum voltage values at the terminals and batteries of the battery at the CTC with automatic shutdown of the battery; AB charge logging control of time of connection of AB; control of battery charge / discharge time; indication of a charge level of AB; monitoring the availability of communication with the system controller and the block of charging resistors; graphical display on the computer display of the status of each of the batteries; additional information, such as electrolyte density.

The whole battery charge / discharge process is fully automated and stops when the battery is charged or discharged or when an emergency occurs, such as: electrolyte overheating; overvoltage at the terminals of the AB or its sections; too low voltage at the terminals of the AB; Invalid voltage between the batteries in the battery mode and the battery monitoring on.

In addition, the control device 3, 4 has the ability to manually replenish the battery base, change the parameters of their charge / discharge in relation to charge / discharge currents, battery capacity. The ability to periodically (once a year) calibrate the channels to improve the accuracy of voltage and temperature measurements. Possibility of port reconfiguration in case of changing parameters via RS-485 Modbus Rtu interface.

In the claimed complex as a pulse program-controlled power source 6, a pulse program-controlled power source of chargers AGRB 122.00.00.TU manufactured by the enterprise NPK VIL can be used. The power source is an AC voltage to DC stabilized current converter with a value from 0 to 20 A, with voltage limitation. The input voltage is 380 V, 50 Hz. The power source is configured to manually and automatically control the value of the stabilized output current in the required range. In automatic mode, the power supply is controlled via the RS-485 Modbus Rtu interface.

Block 7 bit resistors is designed for independent discharge of several batteries during the control and training cycle (CTC). The discharge current (configuration of the resistor connection) is set by the control device 3, 4. The block 7 of the discharge resistors has an input resistor selection circuit, for example, a majority element, which is controlled via the RS-485 Modbus Rtu interface.

The claimed automated software and hardware system for charging and training AB works as follows. Before connecting the battery 5 to the power source 6, the control device 3, 4 programmatically determines the type of the connected AB 5 (12 V, 24 V) from the database and gives a command to set the required charging current and duration of the charging time for the connected battery 4.

After connecting the power source 6, the adapter 10 monitors the status of the battery 5, displaying operational information on the display panel 11: inclusion; charge; discharge; blocking; battery charge scale; Work; the presence of communication over the charge / discharge control network. At the same time, all information, including information on the voltage on the AB 5 and the temperature of the electrolyte, from the adapter output through the interface 2 is fed to a software control device 3, 4, which programmatically monitors and controls the process of charging batteries 5.

In the process of charging the AB 5, the control device 3, 4, receiving real-time information from the measuring adapter 10, monitors the temperature of the electrolyte from the sensor 8 and the voltage at the terminals of the AB 4 from the sensor 9, which gradually increases during the charge and reaches the end of the charge norms. If the electrolyte temperature is higher than the permissible value, the control device 3, 4 disconnects the power supply 6 from this battery 5 for the time required for the electrolyte to cool down to a temperature of an acceptable value. After the electrolyte temperature returns to normal, by a signal from the output of the adapter 10, the control device 3, 4 reconnects the power source 6 to this AB 5 and sets it to continue charging.

The charge of AB 5 continues until the voltage at the terminals of AB 5, which controls the sensor 9, and the density of the electrolyte (calculated by the control device programmatically) are constant for 1 hour while there is a lot of gas emission. After fulfilling this condition, the control device disconnects the charged AB 5 from the power sources.

When charging several batteries of the same type AB 5 at the same time after the end of the set charge time, the control device 3, 4 detects the lagging AB 5 according to information from adapter 10: voltage control at the AB terminals; battery level; the work is over.

Lagging AB 5 recharge for a given control time. Since the charged batteries are turned off, the recharge mode of the AB 5 is excluded.

If, at the end of the control time, the lagging AB 5s are not charged, they are subjected to a control and training cycle (CTC): a full charge of the AB (already completed), a control discharge with a given current for a set time determined by the type of battery, and then the final full charge. In this case, the control device 3, 4 programmatically determines the value of the discharge resistance for this type of connected AB 5 and gives the command to the inputs of the block 7 of the discharge resistors. The block of discharge resistors 7 contains n resistors, where n = 2, 3, ..., and is configured to connect them in various configurations. As a result, an electrical connection of discharge resistances is formed, the cumulative value of which corresponds to the required nominal value.

The control device determines software the delivered capacity of AB 5. If AB 5, having not fulfilled the warranty period, gives less than 100% of the nominal capacity, then it is subjected to repeated CTC. If AB 5, having not fulfilled the warranty period, at repeated CTC gives less than 100% of the nominal capacity, then it is advertised.

At the end of the charge or KTC control device 3, 4 turns off the power source 6. Information on the display panels 11 adapters 10: off; There is no communication over the charge / discharge control network.

Claims (3)

1. Automated software and hardware complex for charging and training batteries “Prism”, including a control software device, M charging modules, combined address-information network with a control software device, each of the M charging modules contains a battery (AB), a power source, a discharge device, characterized in that the address-information network is an interface, and the control software device consists of a system controller and personally electronic computer (PC), in addition, the power supply is made pulsed program-controlled, and the discharge device is made in the form of a block of discharge resistors, while each module additionally has a software-controlled measuring adapter and, connected to its input, an electrolyte temperature sensor and a voltage sensor, while the electrolyte temperature sensor is installed in the middle battery in the hole for filling the electrolyte, and the voltage sensor is installed with the ability to measure voltage as AB, as well as on separate AB batteries, in addition, the program-controlled measuring adapter is equipped with an indication panel configured to display information: inclusion; charge; discharge; blocking; battery charge scale; Work; network connectivity; at the same time, the output of the power source and the output of the block of discharge resistors are connected and connected to the input of the battery, while the inputs and outputs of the measuring adapter, the inputs and outputs of the block of discharge resistors and the inputs and outputs of the power source are connected to the system controller and the PC via an interface. 2. The complex according to claim 1, characterized in that the block of discharge resistors contains n resistors, where n = 2, 3, ..., and is configured to connect them in various configurations. 3. The complex according to claim 1, characterized in that the power source is multi-channel with the ability to programmatically select a channel.