RU53818U1 - BATTERY OF ELECTRIC ENERGY STORES - Google Patents

Abstract

Usage: in the manufacture of batteries of electric energy storage devices (ENE): batteries, ionistors, rechargeable primary HIT. SUMMARY OF THE INVENTION The ENE battery contains many single ENEs or modules from several ENEs connected to a serial electric circuit, a monitoring and control system (CMS), a leveling device that provides voltage equalization on individual ENEs or modules and is powered by an additional DC source (IPT). As an INT, an additional HIT included in the battery or an external charger that can be disconnected from the battery when it is discharged and stored can be used. When using a rechargeable auxiliary CIT, its charge is produced simultaneously with the charge of EIE. The battery may have a microprocessor SKU that provides an indication of the degree of charge of the battery and its interface with the PC.

Description

The utility model relates to the field of electrical engineering and can be used to create batteries of secondary current sources.

Closest to this utility model is a battery of electric energy storage devices (ENE), containing many single ENEs or modules from several ENEs connected to a serial electric circuit, a battery monitoring and control system, as well as electronic units providing voltage equalization on separate ENEs or modules , the power of which is provided from an additional energy source [RF Patent No. 2230418, publ. 2004].

A disadvantage of the known battery is the relative complexity of its operation due to the presence of an external energy source that requires additional maintenance, and in the case of using a stationary energy source, loss of battery autonomy (mobility).

The objective of the invention is to create a simple-to-operate battery of electric energy storage devices, providing equalization of voltages on a single EEE connected to a serial electric circuit during charging, discharging and storage of the battery.

The specified technical result is achieved by the fact that:

Option 1.

In an electric energy storage battery containing a plurality of single ENEs or modules consisting of several ENEs connected in a serial electric circuit, a battery monitoring and control system, at least one electronic equalizing device, providing voltage equalization on separate ENEs or modules and powered by an additional DC power source

characterized in that a device for charging the battery is used as an additional DC source.

In the battery, the device for charging the battery is connected to its terminals, and to supply power to the equalization device from the device for charging the battery, the battery power circuit is used in such a way that the power circuit of the equalization device is connected to one or more neighboring EECs or modules.

In the battery, an electronic converter is used as a device for charging the battery, powered by a stationary alternating current network or a wind generator or hydro generator.

In a battery, an electrochemical fuel cell generator is used as a device for charging a battery.

In the battery, a metal-air current source is used as a device for charging the battery.

In a battery, a primary HIT battery is used as a device for charging a battery.

A battery uses a battery of photoelectric, thermoelectric, or thermoelectrochemical converters as a device for charging a battery.

The power circuit of the battery has a switch that allows it to be disconnected from the device to charge the battery or load.

The switch uses electronic keys.

The switch uses electromagnetic relays.

The battery contains a current sensor, the output signal of which is supplied to the monitoring and control system.

In the battery, the monitoring and control system generates information signals about the degree of charge and the occurrence of an emergency in the battery.

To indicate information signals, LED or liquid crystal indicators are used.

In the battery, the monitoring and control system contains at least one microprocessor.

The battery has at least one information connector for connecting to a personal computer or an external (relative to the battery) microprocessor control system.

RS 232, RS 485 or CAN interfaces are used to connect the battery.

In an electric energy storage battery containing a plurality of single ENEs or modules consisting of several ENEs connected in a serial electric circuit, a battery monitoring and control system, at least one electronic equalizing device, providing voltage equalization on separate ENEs or modules and powered by an additional DC source, as an additional DC source, an electrically rechargeable chemical current source is used, one of the terminals of which are galvanically connected to the terminal of a battery of opposite polarity, and the additional DC source is charged from the charger simultaneously with the battery so that the additional DC source and battery are connected in series with one charger.

There is a switch in the battery power circuit that allows it to be disconnected from the charger or load.

The switch allows you to disconnect from the charger the circuit of an additional DC source without interrupting the battery charge or the charging circuit of the battery without interrupting the charge of an additional DC source.

The switch uses electronic keys.

The switch uses electromagnetic relays.

The battery contains a current sensor, the output signal of which is supplied to the monitoring and control system.

In the battery, the monitoring and control system generates information signals about the degree of charge and the occurrence of an emergency in the battery.

To indicate information signals, LED or liquid crystal indicators are used.

In the battery, the monitoring and control system contains at least one microprocessor.

The battery has at least one information connector for connecting to a personal computer or an external (relative to the battery) microprocessor control system.

RS 232, RS 485 or CAN interfaces are used to connect the battery.

Examples of specific performance.

The design of the battery according to option 1A.

The battery of electric energy storage devices (ENE) is made according to the electrical circuit shown in figure 1. The battery has 4 G1-G4 energizers connected in series, which are lithium-ion batteries, a control and management system (SKU) A1, a leveling device (HC) A2, leveling the voltage on the energizer, an additional DC source (IPT) A3 (charger) connected to the terminals of the battery U ₊ and U _- using a detachable connection for its charge and representing an electronic converter powered by a stationary alternating current network, a current sensor DT working on the Hall effect, and an electromagnetic relay K1, we control 1st SKU A1. HC A2 is connected to each ENE G1-G4 using an electric harness. Through the same harness to the power supply G1-G4 connected and SKU A1. The power supply system is supplied from the G1-G4 power supply unit, and the power supply unit is powered from the IPT A3 (charger).

The algorithm of the battery 1a.

The battery is charged from IPT A3 (charger). In the process of charging, the voltage is equalized to the G1-G4 power supply due to recharging from HC A2. Using the current sensor DT in SKU A1, information about the magnitude of the charging current is entered. If the current or voltage value at any ENE G1-G4 exceeds the specified values, the ACS A1 breaks the battery charging circuit using relay K1. At the same time, HC A2 can continue to equalize the voltage in the battery, recharging the "lagging" power. At the end of the recharge of the ENE G1-G4, the IPT A3 battery (charger) is disconnected from the battery terminals U ₊ and U _- using the plug-in connection during the discharge and storage of the battery. During storage and discharge, voltage equalization in the battery is not performed.

Battery design according to option 1δ.

The battery of electric energy storage devices (ENE) is made according to the electrical circuit shown in figure 2. The battery has 4 connected in series ENE G1-G4, which are modules of 2 parallel-connected lithium-ion batteries, a monitoring and control system (CMS), made in the form of two independent blocks A1.1 and A1.2, two leveling devices ( HC) A2.1 and A2.2, leveling the voltage on the battery of the battery, an additional DC source (IPT) A3 (charger), connected to the battery terminals U ₊ and U _- using a detachable connection for charging the battery and which is a metal- air current source, e K1 electromagnetic relay controlled by SKU A1.1 and A1.2. HC A2.1 and A2.2 are connected to the G1-G2 power supply and to the G3-G4 power supply via electrical harnesses. Through the same harnesses to the power supply G1-G4 connected and SKU A1.1 and A1.2. The power supply of SKU A1.1 is supplied from G1-G2 batteries, and the power supply to SKU A1.2 is supplied from G3-G4 power sources. The HC A2.1 is powered by IPT A3 (charger), using the electric circuit ENE G3-G4 to connect to (-) IPT A3 (charger). The power supply of UV A2.2 is carried out from IPT A3 (charger

devices), when using the electric circuit of the ENE G1-G2 and the electromagnetic relay K1 to connect to (+) IPT A3 (charger).

The battery operation algorithm is 1δ.

The battery is charged from IPT A3 (charger). In the process of charging, the voltage is equalized at the G1-G4 power generator with the help of HC A2.1 and A2.2. When the voltage at any ENE G1-G4 is exceeded, the specified values, SKU A1.1 and A1.2 breaks the battery charging circuit using relay K1, while the charge and voltage equalization in the battery are stopped. During the discharge and storage of the battery, the IPT A3 (charger) is disconnected from the battery terminals U ₊ and U _- by means of a plug-in connection. When storing and discharging the battery, in accordance with the A1.1 and A1.2 SKU operation algorithm, voltage equalization in the battery can be performed when HC А2.1 and А2.2 are supplied from the power supply devices G1-G2 and G3-G4, respectively.

Battery design according to option 2.

The battery of electric energy storage devices (ENE) is made according to the electrical circuit shown in figure 3. The battery has 4 connected in series ENE G1-G4, which are lithium-ion batteries, microprocessor-based monitoring and control system (ACS) A1, leveling device (HC) A2, leveling voltage on the battery batteries. The HC A2 is powered from an additional DC source (IPT) A3, which is a single lithium-ion battery. HC A2 is connected to each GEE-G4 and IPT A3 using an electrical harness. Through the same harness, GIS A1 is also connected to G1-G4 and IPT A3. The power supply system for A1 is also provided from IPT A3 through HC A2. SKU A1 has a connector X1 for connecting to a personal computer via the RS 232 interface. SKU A1 controls electromagnetic relays K1 and K2, to which the charger (memory) A4 is connected via a plug-in connection as necessary.

Battery operation algorithm according to option 2.

For the charge, the ENEs G1 - G4 are connected to the A4 memory in series with IPT A3 via electromagnetic relays K1 and K2 and are charged simultaneously with it (relays K1 and K2 in the position shown in figure 3). In the process of charging, SKU A1 controls the voltage at the GEE-G4 and IPT A3. Upon reaching the maximum degree of charge IPT A3 is disconnected from the memory A4 by command SKU A1 by switching the electromagnetic relay K1, and the charge of the electric power supply G1-G4 continues. If the first to reach the maximum degree of charge of the ENE G1-G4, they are disconnected from the charger by switching the electromagnetic relay K2. In the process of charging the HC-A2 battery according to the commands of SKU A1, it provides voltage equalization on the G1-G4 power supply unit, additionally recharging the power supply unit lagging behind.

After disconnecting from the battery using the plug-in connection of the charger A4, the battery is either connected to the load via terminals U ₊ and U _- , or is in storage mode. In both cases, SCA A1 monitors the voltage at the G1-G4 power supply and, if necessary, charges the power supply with a large self-discharge with the help of HC A2, using the IPT A3 energy.

Claims (27)

1. A battery of electrical energy storage devices (ENE), comprising a plurality of single ENEs or modules consisting of several ENEs connected to a serial electric circuit, a battery monitoring and control system, at least one electronic equalizing device providing voltage equalization on individual ENEs or modules and powered by an additional DC source, characterized in that it is used as a constant current source in the device to charge the battery. 2. The ENE battery according to claim 1, characterized in that the device for charging the battery is connected to its terminals, and a battery power circuit is used to supply power to the equalization device from a direct current source so that the power circuit of the equalization device is connected to one or more neighboring energy or modules. 3. The battery ENE according to claim 1, characterized in that as a device for charging the battery, an electronic converter is used, powered by a stationary alternating current network or a wind generator or hydro generator. 4. The ENE battery according to claim 1, characterized in that an electrochemical generator based on fuel cells is used as a device for charging a battery. 5. The ENE battery according to claim 1, characterized in that a metal-air current source is used as a device for charging the battery. 6. The ENE battery according to claim 1, characterized in that the primary HIT battery is used as a device for charging the battery.
7. The ENE battery according to claim 1, characterized in that a battery of photoelectric, thermoelectric or thermoelectrochemical converters is used as a device for charging. 8. Battery ENE according to any one of claims 1 to 7, characterized in that the power circuit of the battery has a switch that allows it to be disconnected from the device for charge or load. 9. The ENE battery according to claim 8, characterized in that the electronic keys are used in the switch. 10. Battery ENE according to claim 8. characterized in that the switch uses electromagnetic relays. 11. Battery ENE according to any one of claims 1 to 7, characterized in that it contains a current sensor, the output signal of which is supplied to the monitoring and control system. 12. Battery ENE according to any one of claims 1 to 7, characterized in that the monitoring and control system generates information signals about the degree of charge and the occurrence of an emergency in the battery. 13. The ENE battery according to claim 12, characterized in that LED or liquid crystal indicators are used to indicate information signals. 14. The ENE battery according to any one of claims 1 to 7, characterized in that the monitoring and control system comprises at least one microprocessor. 15. The ENE battery according to claim 14, characterized in that the battery has at least one data connector for connecting to a personal computer or an external microprocessor control system relative to the battery. 16. The ENE battery according to clause 15, wherein the RS 232, RS 485 or CAN interfaces are used for connection. 17. A battery of electrical energy storage devices containing a plurality of single ENEs or modules consisting of several ENEs connected to a serial electric circuit, a battery monitoring and control system, at least one electronic equalizing device providing voltage equalization on separate ENEs or modules and powered from an additional DC source, characterized in that as an additional DC source, an electrically rechargeable chemically used a current source, one of terminals electrically connected to the terminal of opposite polarity of the battery and charge the DC power produced from the charger to charge the battery simultaneously so that the DC power source and the battery are connected in series to one charger. 18. The ENE battery according to claim 17, characterized in that there is a switch in the battery power circuit that allows it to be disconnected from the charger or load. 19. The ENE battery according to claim 18, characterized in that the switch will allow disconnecting the additional DC source circuit from the charger without interrupting the battery charge or the battery charging circuit without interrupting the charge of the additional DC source. 20. The ENE battery according to claim 18, characterized in that the electronic keys are used in the switch. 21. The ENE battery according to claim 18, characterized in that the relay uses electromagnetic relays. 22. Battery ENE according to any one of paragraphs.17-21, characterized in that it contains a current sensor, the output signal of which is supplied to the monitoring and control system. 23. Battery ENE according to any one of paragraphs.17-21, characterized in that the monitoring and control system generates information signals about the degree of charge and the occurrence of an emergency in the battery. 24. The ENE battery according to claim 23, characterized in that LED or liquid crystal indicators are used to indicate information signals. 25. Battery ENE according to any one of paragraphs.17-21, characterized in that the monitoring and control system contains at least one microprocessor. 26. The ENE battery according to claim 25, wherein the battery has at least one data connector for connecting to a personal computer or an external microprocessor control system relative to the battery. 27. The ENE battery according to claim 26, characterized in that the interfaces RS 232, RS 485, or CAN are used.