Chemistry: electrical current producing apparatus – product – and – With control means responsive to battery condition sensing...
Reexamination Certificate
2001-06-20
2003-07-29
Ryan, Patrick (Department: 1745)
Chemistry: electrical current producing apparatus, product, and
With control means responsive to battery condition sensing...
C429S062000, C429S116000, C429S110000, C429S112000, C429S056000, C429S090000, C429S122000
Reexamination Certificate
active
06599656
ABSTRACT:
CROSS-REFERENCE TO RELATED APPLICATIONS
This application is based on French Patent Application No. 00 08 153 filed Jun. 26, 2000, the disclosure of which is hereby incorporated by reference thereto in its entirety, and the priority of which is hereby claimed under 35 U.S.C. §119.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a storage cell battery incorporating a safety device. The device operates in the event of an anomaly in the operation of one or more cells to increase the response time and minimize the risks, in particular of fire. This is why the invention is more particularly intended to be applied to lithium rechargeable storage cell batteries, some components of which are inflammable. Improving the safety of the user is one imperative for “consumer” applications, for example if the battery is installed in an electric vehicle.
2. Description of the Prior Art
Storage cells have an enclosure containing an electrode assembly impregnated with electrolyte and made up of at least one positive electrode, at least one negative electrode, and at least one separator disposed between the electrodes. The cells can be combined to form a battery by series or parallel connections. They are placed together in a closed container. An anomaly in the operation of the battery can be caused by the malfunctioning of one of the cells (short circuit, etc) or an external disturbance (impact, temperature rise, etc). The anomaly causes the battery to become heated and increases the risk of fire. The proximity of a large number of cells multiplies the risk accordingly, which makes external intervention necessary for permanently safeguarding the battery. The risk is particularly high in the case of lithium cells, which in particular contain organic solvents that are readily volatile at relatively low temperatures in the range from 70° C. to 120° C., with flash points in the range of ambient temperature up to 100-200° C.
Safety devices have been proposed whose object is to extinguish a fire using an extinguishing agent that can take the form of a gas, a liquid, a powder, granules or a mixture of the above.
The device can be installed inside the cell itself, as described in the documents JP-9 161 754 and U.S. Pat. No. 5,523,178. This has the drawback of increasing the total volume of the battery in proportion to the number of cells constituting it. The energy per unit volume of this kind of battery falls, and soon becomes incompatible with user expectations. In other cases (JP-03 112 570), an extinguishing agent stored externally is introduced directly into the interior of each cell, which requires an injection conduit specific to each cell. Once again, the resulting overall size is prohibitive for a consumer application, for example in an electric vehicle, where the space available for the battery is very constricted.
In the particular case of sodium-sulfur (Na—S) cell batteries, which operate at high temperatures (300° C.-400° C.), several documents (JP-4 288 169, JP-4 300 563, JP-4 303 466 and JP-5 031 207) describe fire-fighting equipment that injects a granulated extinguishing agent into the container of a battery via an injection nozzle (JP-4 288 169 or JP-5 031 207) or preferably via a distribution manifold so that the agent is distributed homogeneously (JP-4 300 563 or JP-4 303 466). Injection is commanded by a fire detector, such as a temperature probe, placed on the container. The fire-fighting equipment is disposed outside the battery. It includes in particular a storage tank containing the extinguishing agent granules and an inert gas and a device for pressurizing the gas contained in the storage tank. The storage tank and the device are connected to each other and to the container by pipes and valves.
It takes a long time for the fire-fighting equipment to respond, in particular because this entails a time-delay to pressurize the storage tank using a gas supply device. To reduce this time-delay, it has been proposed to keep the storage tank pressurized by connecting it to a pressurized cylinder (JP-5 084 318). However, pressurized gas leaks into the valves and the pipes and when fire breaks out there is insufficient gas to entrain the extinguishing agent. A compressor can be added to the equipment to remedy this drawback (JP-5 089 908). This improvement requires an additional component, and therefore increases the volume of the equipment, increases its cost and requires more complicated maintenance. Moreover, if the storage tank is pressurized, the powder and the granules of extinguishing agent can find their way into the seats of the valves and the connecting flanges, which increases leaks.
Also in the case of Na—S cells, the document JP-5 317 440 proposes fire-fighting equipment that does not include any auxiliary device for pressurizing the storage tank. The equipment includes a device for supplying pressurized gas to the extinguishing agent storage tank and a device for admitting pressurized gas to the battery container. If fire breaks out in the container, the gas is emitted simultaneously toward the container and toward the storage tank by an array of pipes and a set of automatic valves whose control circuit is connected to the fire detector. Once the pressure in the storage tank has reached the required value, the control device interrupts the emission of gas by the emission device. The extinguishing agent entrained by the gas from the supply device is then fed into the container.
The devices previously described have the drawback of reacting too slowly for the safety of the user. The outbreak of fire is detected by a temperature sensor which causes valves to be opened via a control circuit. The gas must then flow through the pipes before reaching the container. These successive operations necessitate time-delays that can be as much as several seconds.
In the case of a lithium rechargeable cell battery, in particular, because of the presence of very volatile organic solvents, this time period is sufficient to reach an unacceptable level of risk. In particular, this battery has a high risk of fire due to products generated by thermal runaway of the reaction.
An object of the present invention is to eliminate the drawbacks of the prior art and in particular to shorten the time-delay between detecting an anomaly and the removal from danger of a cell battery in order to enhance the safety of the user. The invention relates more precisely to a safety device, in particular a fire-fighting device, solving this problem.
SUMMARY OF THE INVENTION
The present invention provides a storage cell battery including:
at least one cell having an enclosure containing an electrode assembly impregnated with an electrolyte and comprising at least one positive electrode, at least one negative electrode and at least one separator disposed between the electrodes,
a common container provided with a first orifice, and
a safety device including an anomaly detector, a storage tank containing a non-inflammable gas under pressure and connected to the first orifice, and a control system in the form of a pyrotechnic mechanism for controlling the admission of the gas into the common container.
The function of the safety device according to the invention is to prevent the onset or to stop the evolution of a fire affecting the cells and which is likely to propagate. The combination of a pyrotechnic mechanism with a very short response time and a non-inflammable gas injected at high speed into the container because of the pressure fills the common container virtually immediately and improves the efficiency of flame inhibition. With the danger averted in this way, the user can act himself or call on external help.
The anomaly detector includes a system for measuring the value of the parameter to be detected and a system for comparing the measured value to a reference value. The measuring system can be a temperature sensor, for example, a pressure sensor or a shock detector. The comparator system can be a probe for measuring the outdoor temperature or a sensor for measuring the
Alcatel
Martin Angela J
Ryan Patrick
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