RU164335U1 - LITHIUM BATTERY - Google Patents

Abstract

A lithium battery containing at least one circuit in series of electrically connected terminals of opposite polarity of lithium current sources (IT), the positive and negative terminals of which are connected, respectively, to the positive and negative current terminals of the battery, a field effect transistor whose conductive channel is connected between one of terminals of the IT circuit and battery current output, a thermal fuse located in the zone of the heat energy flow from the field effect transistor and having a tripping temperature not exceeding the maximum permissible operating temperature of the field-effect transistor, characterized in that it is equipped with a diode connected between the gate of the field-effect transistor and the output of the IT circuit, to which the conductive channel of the field-effect transistor is connected, and a thermal fuse is connected between the field-effect transistor gate and the electrical connection with the opposite polarity terminals of the two ITs, which are extreme in a chain of series-connected IT and placed on the side of connecting the conductive channel of the field-effect transistor to the IT circuit.

Description

The utility model relates to the field of electrical engineering, in particular, electrical equipment, namely, a lithium battery for direct conversion of chemical energy into electrical energy, and can be used in the manufacture of batteries from primary chemical current sources and / or secondary chemical current sources, for example, lithium ion batteries (IT), designed for autonomous power supply of diagnostic equipment for in-line inspection devices for oil and gas pipelines, as well as for use I as autonomous power supplies of various other electronic devices, devices and systems.

Known primary lithium battery containing at least two parallel connected to current leads through a thermal fuse electrical circuit, consisting of primary lithium cells, each of which has a parallel diode connected to it, each electrical circuit has a protective tool in the form of series-connected in a diode, and the battery has test leads, each of which is connected to one corresponding circuit at a point located between the last primary lithium element of the circuit and sequentially connected diode. Each control terminal of the battery can be connected to the corresponding electric circuit through a high-resistance resistor. In this case, the battery can be equipped with additional test leads by the number of other primary lithium cells, except the last, and each of the additional test leads is connected to the positive terminal of the corresponding primary lithium cell (see RF patent for utility model No. 45204. IPC Н01М 10/00, published on April 27, 2005).

The well-known design uses the so-called diode protection of primary lithium current sources from their charge and overdischarge, in which a diode is connected in parallel with IT, and a diode is switched on in each circuit of series-connected IT, eliminating the possibility of charging IT. Diode protection eliminates the possibility of charging IT, it limits the voltage of IT polarity reversal during its overdischarge, but it does not protect IT from a deep discharge, i.e. IT discharge at a discharge voltage of less than 2 V. In this case, secondary lithium IT accumulates by-products, including fire hazardous products, which are unstable, and the presence of even small amounts of water dramatically accelerates the exothermic decomposition of these products, which is likely to lead to IT explosion. With a deep discharge in IT, it is possible that the electrolyte is completely consumed and so-called “dry spots” are formed, resulting in lithium ignition and IT explosion, which is not permissible in operation. This indicates a lack of reliability and safety of the battery as a whole.

Also known is a primary lithium battery containing at least two parallel circuits, each of which consists of series-connected primary lithium IT, combined in a single housing equipped with contact leads, while the battery is additionally equipped with an electronic controller that contains diodes, each of which are connected in parallel with one IT, and at least two diodes connected in series after each IT, which is the last in each chain of IT connected in series, with each I chain of series-connected primary lithium IT is further provided with a fuse connected between a common wire of parallel chains and the first IT chain. At least one circuit of series-connected primary lithium ITs can be additionally equipped with fuses connected between each IT circuit and its connection with a diode connected in parallel with IT (see RF patent for utility model No. 46388, IPC H01M 10/48, publ. June 27, 2005).

The known battery is also equipped with diode protection and fuses to eliminate the effects of in-circuit short circuits. However, the well-known protection does not protect against a deep IT discharge, during which accumulation of side unstable, including fire hazardous products can occur, which can lead to an IT explosion, which indicates insufficient reliability and safety of the battery as a whole.

Closest to the proposed technical solution is a primary lithium battery containing at least one circuit of series-connected primary lithium current sources (IT), the positive and negative terminals of which are connected, respectively, to the positive and negative current terminals of the battery, a field effect transistor, a reference source voltage with positive and negative terminals, while the conductive channel of the field-effect transistor is connected between one of the terminals of the IT circuit and the battery current output, the source is voltage is connected by a terminal of the same polarity to another terminal of the IT circuit, a thermal fuse located in the heat energy flow zone from the field effect transistor and having a trip temperature not exceeding the maximum allowable operating temperature of the field effect transistor, characterized in that it is equipped with a resistor connected to the gate of the field effect transistor and the output of the IT circuit to which the conductive channel of the field-effect transistor is connected, and the thermal fuse is electrically connected in series with the reference source apryazheniya in the chain connecting the gate of the FET with the output circuit of IT. (see RF patent for utility model No. 94383, IPC Н01М 10/48, published on 05/20/2010).

The known battery design eliminates the possibility of deep discharge of the battery and its constituent elements. An exception to the possibility of deep discharge is provided by additional elements built into the battery, such as a field effect transistor, a voltage reference source, as well as a safety element - a thermal fuse installed in the zone of heat energy flow from the field effect transistor and included in the control circuit of the field effect transistor.

The disadvantages of this design is the sufficient complexity of the design of the battery. The complexity of the design is primarily associated with the presence in the battery of a built-in reference voltage source, which in itself is a rather complex device and requires space in the battery to accommodate it. This drawback is especially manifested when it is necessary to conserve battery power for a long time, which in turn requires the use of a time-stable characteristics and, accordingly, structurally complex reference voltage source.

The task to which the claimed technical solution is directed is to expand the arsenal of technical means in this area.

This task is achieved due to the fact that a lithium battery containing at least one circuit in series electrically connected to the terminals of the opposite polarity of lithium current sources (IT), the positive and negative terminals of which are connected, respectively, to the positive and negative current terminals of the battery, a field effect transistor the conductive channel of which is connected between one of the terminals of the IT circuit and the battery current output, a thermal fuse located in the zone of heat energy flow from the field effect transistor and having operating temperature not exceeding the maximum permissible operating temperature of the field-effect transistor, according to a utility model, the battery is equipped with a diode connected between the gate of the field-effect transistor and the output of the IT circuit, to which the conductive channel of the field-effect transistor is connected, and a thermal fuse is connected between the field-effect transistor gate and the electrical connection with terminals of opposite polarity two ITs, which are extreme in the chain of series-connected IT and located on the connection side of the conductive channel Olevia transistor IT chain.

By "thermal fuse" in the present description of a utility model is meant a one-time fuse that opens the circuit if the ambient temperature in the circuit exceeds the fuse tripping temperature.

The technical result provided by the above set of features is to simplify the design of the device by using the discharge voltage of one of the IT to directly control the conductive channel of the field effect transistor, namely: to close the conductive channel of the transistor during a deep discharge of IT and, accordingly, due to this, termination of the discharge batteries for external load.

The device is illustrated in the drawing (Fig. 1), which shows an example of an electrical circuit of a lithium battery.

The numbers in the drawing indicate: 1 - lithium current sources of IT; 2 - field effect transistor; 3 - thermal fuse located in the heat flux from the field effect transistor 2; 4 - diode; 5 - resistor.

A lithium battery contains at least one circuit of lithium current sources (IT) 1 with opposite polarity terminals, the positive and negative terminals of which are connected, respectively, to the positive and negative battery current leads, a field effect transistor 2, whose conductive channel is connected between one from the terminals of the IT circuit and the battery current lead, a thermal fuse 3, located in the zone of the flow of thermal energy from the field effect transistor and having a tripping temperature not exceeding the maximum allowable operating temperature of the field-effect transistor, diode 4, connected between the gate of the field-effect transistor and the output of the IT circuit, to which the conductive channel of the field-effect transistor is connected, and the thermal fuse 3 is connected between the gate of the field-effect transistor 2 and the electrical connection with the opposite polarity terminals of the two ITs, which are extreme in the circuit connected in series IT 1 and placed on the side of the connection of the conductive channel of the field effect transistor 2 to the circuit IT 1.

The lithium battery can also be equipped with a resistor 5, which is advisable to use for safety - to limit the IT discharge current in case of accidental (abnormal) damage (electrical or thermal breakdown) of diode 4 and / or insulation between the gate and the conducting channel of the field-effect transistor.

As current sources of the IT1 circuit, for example, current sources SPL-16S, manufactured by L&P Co., Ltd (South Korea), can be used.

As the field effect transistor 2, for example, field effect transistors IRLR2905, IRL2505, IRL2705 manufactured by International Rectifier (IR) with a closing voltage of the conductive channel (voltage between the gate and the source of the conductive channel of the field effect transistor), which is within the range (1.0-2 5) B.

As a thermal fuse, for example, small-sized thermal fuses of the TZK series (TZK-10; 102 ° C; 0.1 A; 250 V) manufactured by Bourns, Inc (USA) with a response temperature of 90 ÷ 110 ° C can be used.

As a diode, diodes of the 1N4001-1N4007 series of various manufacturers can be used.

The lithium battery operates as follows.

During operation of a lithium battery under load (battery discharge process), the operating voltage of the IT and the battery as a whole decreases.

Consistently in the IT circuit 1 between the output of the IT 1 circuit and one of the current outputs, for example, “negative”, a field-effect transistor 2 is connected with its conductive channel.

The field effect transistor is used due to the fact that the control currents of the conductive channel in this type of transistor are practically zero (~ 1 · 10 ^-7 A), i.e. the conductive channel (the value of its resistance and, accordingly, the internal resistance of the battery) is controlled by practically discharge IT voltage without any additional significant discharge currents.

If the discharge voltage of the IT battery is higher than 2.5 V, the conductive channel of the field-effect transistor 2 will be open, and through it, the battery and the load as a whole will flow freely.

However, when the discharge voltage value of the IT battery becomes equal to or lower than 1.0 V, the conductive channel of the field effect transistor 2 will be closed. In this case, the load from the battery will be disconnected by disconnecting the IT 1 circuit from the battery current outputs due to a significant increase in the internal resistance of the conducting channel of the field effect transistor and, accordingly, the battery.

At large discharge currents (more than 1.0 A) and a discharge voltage on IT equal to (1.0-2.5) V (i.e. during the transition period, during the closure of the conducting channel of the field-effect transistor), the field-effect transistor can be heated to a temperature exceeding permissible (above 175 ° C), at which thermal breakdown of the field effect transistor is possible.

To prevent this from happening, a thermal fuse with a tripping temperature of 90-110 ° C is placed in the zone of the flow of thermal energy from the field effect transistor. Therefore, if the transistor heats up, at a temperature of approximately 110 ° C, the thermal fuse trips. Since the gate of the field-effect transistor is connected via a diode to the conductive channel, when the thermal fuse is activated, the gate potential is compared with the potential of the conductive channel. Under such conditions, the transistor closes and, accordingly, the flow of electric current through the battery load stops.

At the same time, the requirement for the thermal fuse tripping temperature not exceeding the maximum permissible operating temperature of the field effect transistor is necessary for shutting down the field effect transistor before its failure due to possible overheating.

The proposed utility model does not include a reference voltage source. This greatly simplifies the design of the battery as a whole in comparison with the prototype.

Claims (1)

A lithium battery containing at least one circuit in series of electrically connected terminals of opposite polarity of lithium current sources (IT), the positive and negative terminals of which are connected, respectively, to the positive and negative current terminals of the battery, a field effect transistor whose conductive channel is connected between one of terminals of the IT circuit and battery current output, a thermal fuse located in the zone of the heat energy flow from the field effect transistor and having a tripping temperature not exceeding the maximum permissible operating temperature of the field-effect transistor, characterized in that it is equipped with a diode connected between the gate of the field-effect transistor and the output of the IT circuit, to which the conductive channel of the field-effect transistor is connected, and a thermal fuse is connected between the field-effect transistor gate and the electrical connection with the opposite polarity terminals of the two ITs, which are extreme in a chain of series-connected IT and placed on the side of connecting the conductive channel of the field-effect transistor to the IT circuit.

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