EP2664022A1 - Battery temperature control by means of material that changes the state of aggregation thereof - Google Patents

Abstract

The invention relates to a device for controlling the temperature of a battery (1), comprising a battery (2) and a latent heat accumulator (3), which can change the state of aggregation thereof from liquid to solid and can give off heat of crystallization in the process in order to heat up the battery (2), wherein the crystallization can be triggered by a pulse.

Description

 Description title

 Battery temperature control by aggregate state change material

The present invention relates to a device for tempering a battery (1) comprising a battery (2) and a latent heat accumulator (3), which can change its state of aggregation from liquid to solid and thereby

Heat of crystallization for heating the battery (2) can give off and wherein the crystallization can be triggered by a pulse. The present invention further relates to products comprising this device and a method for controlling the temperature of batteries.

State of the art

The usable capacity and performance of conventional Li-ion batteries is strongly influenced by the ambient temperature of the component. Therefore, especially at low ambient temperatures, it is necessary to set the battery to near-room temperature, i.e., prior to or directly at start-up. To heat 18 ° C to 20 ° C. For this purpose, separate heating systems are optionally heated in conjunction with an additional battery of other chemistry (e.g., lead acid).

The principle that released in the crystallization of a material

Heat of crystallization for heating is known, for example, from gel pocket warmers. For a gel pocket warmer, the

 Crystallization be initiated for example by a bendable metal plate.

Disclosure of the invention The invention relates to a device for controlling the temperature of a battery (1) comprising a battery (2) and a latent heat accumulator (3), which can change its state of aggregation from liquid to solid and thereby

Heat of crystallization for heating the battery (2) and emits the crystallization is triggered by a pulse.

The invention also provides a device for tempering a battery (1) comprising a battery (2) and a latent heat accumulator (3), which can absorb excess heat of the battery (2) and thereby changes its state of aggregation from solid to liquid and thus the battery (2) cools.

In one embodiment of the invention, the device is characterized

characterized in that the latent heat storage (3) is a gel.

In one embodiment of the invention, the device is characterized

in that the latent heat store (3) is located in a housing (4) which is arranged around the battery (1). The housing can completely enclose the battery. The housing can only enclose parts of the battery.

In a further embodiment, the device is characterized in that the latent heat accumulator (3) is located in a plurality of separate housings (4) arranged around the battery (1). In a special

Embodiment, the device is characterized in that the change of the state of aggregation of the latent heat storage (3) in the separate

Housings (4) can be controlled independently.

In a further embodiment, the device is characterized in that the latent heat accumulator (3) is located directly in the battery (1).

Another aspect of the invention relates to a product, characterized in that it comprises a device according to the invention. In a particular embodiment of the invention, the product is a device or a vehicle.

Another aspect of the invention relates to a method for controlling the temperature of a battery, characterized in that a battery (2) with a

Latent heat storage (3) is brought into contact and wherein the battery is heated by the latent heat storage (3) has a liquid

Has state of aggregation and the latent heat storage (3) his State of matter from liquid to solid can change while heat of crystallization to heat the battery (2) and the crystallization of the latent heat storage (3) is triggered by a pulse, and wherein the battery is cooled by the fact that the latent heat storage (3) has a solid state and the latent heat storage (3) can absorb heat and thereby changes its state of matter from solid to liquid.

Another aspect of the invention relates to a method for heating a battery (2), characterized in that a battery (2) with a

Latent heat storage (3) is brought into contact and wherein the

 Latent heat store (3) has a liquid state of matter and the latent heat storage (3) can change its state from liquid to solid and thereby heat of crystallization to heat the battery (2) emits and wherein the crystallization of the latent heat storage (3) is triggered by a pulse.

Another aspect of the invention relates to a method for cooling a battery (2), characterized in that a battery (2) with a

Latent heat store (3) is brought into contact, wherein the

Latent heat storage (3) has a solid state of matter and the

Latent heat storage (3) can absorb heat while keeping its

Physical state changes from solid to liquid.

The present invention utilizes the in the crystallization of a

Latent heat storage (3) released heat of crystallization for heating a battery (2) at low ambient temperature to an optimum

Operating temperatur. The liberated heat of crystallization may be used to heat a battery (2) to a preferred temperature range for operation of the battery (eg 18 °, 19 °, 20 ° C, 40 ° C, 60 ° C). The preferred temperature range depends on the cell chemistry used and the battery type.

If the battery (2) after prolonged life at low temperatures are turned on, by a suitable pulse (Tigger) the

Crystallization of the latent heat storage (3) are initiated, whereupon this releases its thermally stored energy in the form of heat of crystallization and heats the battery (2) with it.

Electrochemical cells are electrochemical energy storage and

Energy converters. During the discharge of an electrochemical cell stored chemical energy is converted by the electrochemical redox reaction into electrical energy. Primary cells can only be discharged once and not recharged. In these cells, the reactions during discharge are partly irreversible. In contrast, the rechargeable

Secondary batteries (accumulators) largely in the state of charge similar to the

To bring new condition, so that a multiple conversion of chemical to electrical energy and back is possible. In the present application, the term battery is used as a generic term for battery, electrochemical cell and accumulator.

The capacity is given in ampere-hours (abbreviation: Ah) or in ampere-seconds = coulomb (unit symbol: C). The capacity of a battery is the electric charge stored in the battery. you

differentiates the theoretical capacity (depends on the amount of active material in the battery) of the under certain conditions

removable charge (usable capacity). The usable capacity of a battery depends on the discharge conditions, for example, the temperature and the history of the battery (for example, duration and conditions of storage before discharge).

All batteries are subject to self-discharge when stored. The

Self-discharge speed depends, among other things, on the type of battery and the temperature. The lower the storage temperature, the lower the self-discharge. Therefore, it may be advantageous to store the battery at low temperature just before use, to the optimum

 To bring operating temperature.

A lithium battery is a primary cell that uses lithium as the active material in the negative electrode. In contrast to the lithium-ion battery, it is not designed to be rechargeable. The latter are often referred to as lithium battery. Examples of lithium batteries are the Lithium thionyl chloride battery, lithium manganese dioxide battery, lithium sulfur dioxide battery, lithium carbon monofluoride battery, lithium iodine battery, lithium iron sulfide battery. Examples of other batteries are the alkaline manganese battery, nickel

Oxyhydroxide battery, mercury oxide zinc battery, silver oxide zinc cells, zinc brownstone cell, zinc chloride battery, zinc air battery,

An accumulator (rechargeable battery) is a reusable storage for electrical energy, mostly based on an electrochemical system, and thus a

Special form of a battery. In contrast to a non-rechargeable battery of primary cells, a rechargeable battery consists of one or more rechargeable secondary cells. In vehicles, accumulators are used as a starter battery for generating power for light, on-board electronics and for the starter for starting the internal combustion engine. They provide power until the engine is running, then the accumulator is recharged via the generator operating as a generator. Similarly, accumulators can be used in motorcycles, ships and aircraft. Examples of rechargeable batteries are the NiCd (nickel-cadmium) rechargeable battery, the NiH ₂ (nickel-hydrogen) rechargeable battery, the NiMH (nickel-metal hydride) rechargeable battery, NiFe (nickel-iron) rechargeable battery, the Li Ion - (Li-ion accumulator, LiPo (lithium-polymer) accumulator, LiFe (lithium-metal) accumulator, LMP (lithium-metal-polymer) accumulator, Li-Mn - (lithium-manganese -) Accumulator, the LiFeP0 ₄ - (Lithium-Iron-Phosphate) accumulator, the LiTi - (lithium titanate) accumulator, the LiS - (lithium-sulfur)

Rechargeable battery, the Rechargeable Alkaline Manganese (RAM) rechargeable battery, PTMA (2,2,6,6-tetramethylpiperidinoxy-4-yl methacrylate) rechargeable battery, Na / NiCI (sodium nickel chloride high temperature) rechargeable battery, the SCiB - (Super charge lon-battery) accumulator, the SnC / Li ₂ S - (tin-sulfur-lithium)

Accumulator, the silver-zinc accumulator, the vanadium redox accumulator, the zinc-bromine accumulator.

In the simplest embodiment, the latent heat store (3) is arranged around the battery (2). The latent heat storage is a storage material that can change its state of aggregation from liquid to solid and vice versa, and thereby releases or absorbs energy. The latent heat store (3) is preferably located in one or more containers, for example one or more housings (4), one or more foils in order to fix the latent heat store (3) in the liquid state. Of the

Latent heat storage (3) is located for example in a container made of pure plastic or a container made of a plastic with additives (for example ceramic particles) to increase the thermal conductivity or a container made of metal, which preferably has a high thermal conductivity (eg copper, aluminum) and optionally in addition has a low density.

The latent heat storage is present as a liquid that performs a phase change on cooling. Mostly salt water or a special gel with high heat storage coefficient is used as material for latent heat storage. In this case, the phase change can be recognized by the fact that the

Latent heat storage is hard and thick when charged (i.e., cooled). The latent heat storage can be added to a substance that prevents fouling.

Latent heat storage (3) work by utilizing the enthalpy of reversible thermodynamic changes in state of the storage material, preferably the solid-liquid phase transition (solidification / melting).

Latent heat storage contain, for example, special salts or paraffins as content, which serve as a storage medium. When charging the storage material of the latent heat storage (3), the memory material is melted, which can thus absorb a lot of heat energy (heat of fusion). This process is reversible. When solidifying, the storage material returns exactly this amount of heat. For example, Glauber's salt or alum or sodium acetate trihydrate may be used as

Storage medium can be used in latent heat storage. Sodium acetate trihydrate, for example, is liquefied at a melting temperature of 58 ° C and remains even at much lower temperatures - possibly down to -20 ° C - liquid and exists there as a supercooled melt in one

metastable state. The crystallization can be triggered by a pulse, for example a metal plate, which is pressed into the latent heat storage. Of the

Latent heat storage heats up, whereby the complete

Crystallization and thus the release of latent heat can extend over a longer time.

In the present invention, events or materials that initiate the crystallization of the latent heat storage are referred to as a pulse or trigger. Examples of triggers are platelets that can be pushed into the latent heat storage. Triggers are also crystallization seeds that are added to the latent heat storage. Triggers can be pressure waves that trigger crystallization in the supersaturated solution of latent heat storage. The compression of the latent heat storage can also trigger the crystallization.

The advantage of this heat storage technique is based on storing as much heat energy in as little mass as possible in a temperature range which is precisely defined by the melting temperature of the latent heat storage used. For technical applications of liquid-crystalline latent heat storage, recrystallization shortly below the melting temperature is generally desired.

Modern latent or paraffin-based latent heat storage systems have physical properties developed for various applications and are available for almost all temperature ranges. They are increasingly finding

Application and allow the buffering of the temperature in the range of the optimal operating temperature of the battery down as above.

Crystallization is the process of forming crystals from a supersaturated solution. For a crystal to form, the material to be crystallized must first be supersaturated. This happens, for example, by cooling processes of solutions or melts, or by evaporation of the solvent. For crystals consisting of several components (for example ionic crystals), the supersaturation can also be produced by mixing two solutions, each containing one of the components. Here are the previously solved Molecules or elements in a regular, partly substance-specific form. This process can be accelerated by adding seed crystals, which then continue to grow in the supersaturated solution. Without

"Agglomeration sites", i.e. without nucleation, supercooling down to -30 ° C is possible before the water molecules are arranged in a crystal lattice.

For example, then a vibration can trigger the crystallization spontaneously.

The heat of crystallization (solidification heat) is released when a substance changes its state of aggregation from liquid to solid. Due to the

 Conservation Theorem, the released energy is equal to the energy required to melt the substance (see also heat of fusion). For different substances, the heat of solidification (= heat of fusion) per kilogram of mass varies in size.

Further advantages and advantageous embodiments of the subject invention are illustrated by the drawings and explained in the following description. It should be noted that the

Drawing has only descriptive character and is not intended to limit the invention in any way. It shows

Fig. 1 shows the schematic structure of a device for temperature control of a battery (1). Figure 1 shows a device for temperature control of a battery (1), with battery

(2), latent heat storage (3) and housing (4). In this simplest

Embodiment, the latent heat storage (3) is arranged around the battery cell (2). The latent heat storage is a storage material that can change its state of matter from liquid to solid and vice versa and thereby emits or absorbs energy. Preferably, the is

Latent heat storage (3) in one or more containers, for example one or more housings (4), one or more film to fix the latent heat storage (3) in the liquid state.

The functioning device for battery temperature control (1) is as follows: The device for temperature control of a battery (1) has on the one hand a

Cooling function.

When the battery is in operation, energy is generated by the battery. Most of the energy is consumed. Part of the energy is converted into heat. The heat energy is transferred from the battery to the

Latent heat storage delivered, which surrounds the battery. Of the

Latent heat storage absorbs the heat energy. The heat supply causes a phase transition in the latent heat storage, causing the

Physical state of latent heat storage changes. The previously solid

Storage material changes into the liquid state of aggregation. The absorption of the excess heat of the battery by the latent heat storage leads to melting of the storage material. The heat dissipation cools the battery.

On the other hand, the device for controlling the temperature of a battery (1) has a heating function.

If the battery (2) is not in operation or is switched off, no energy is generated by the battery (2). The latent heat storage (3) is in the liquid state. By a pulse, the crystallization of the latent heat storage (3) is triggered. In this case, there is a phase transition from the liquid to the solid state in the latent heat storage. During the crystallization, the heat of crystallization is released, that of the at

Latent heat storage (3) adjacent battery (2) is recorded. This will warm the battery up. The device acts as a heating element.

The device and the output from the latent heat storage

Heat of crystallization can be used to heat or preheat the battery.

The housing (4) can be designed such that the latent heat accumulator is mounted in several separate housings. The individual housings can be controlled together. In a preferred embodiment, the individual housings can be controlled independently of one another. This means that the crystallization can be triggered independently in the individual housings. This means that the pulses can be triggered independently of each other in the individual housings. About the number of triggered

Crystallization processes or the number of driven housing or the number of driven latent heat storage can be adjusted in this way, the amount of heat released. In this way, regardless of the low outlet temperature, the optimum operating temperature of the battery can be adjusted. With a large number of small cases, the

Contain latent heat storage and surrounding the battery, the battery can be tempered and optionally the temperature of the battery can be set exactly.

To achieve a better heating directly at the battery can the

Latent heat storage also be installed in the battery. Preferably, the latent heat storage is then in small intervals in the battery.

The crystallization of the latent heat storage and thus the heating function of the device for temperature control of a battery (1) is not triggered when the ambient temperature is high enough. The latent heat storage (1) then remains off and does not heat up the battery.

The device according to the invention for controlling the temperature of a battery (1) can be used in all stationary or mobile batteries regardless of the chemical composition.

The invention also includes products comprising the device for controlling the temperature of a battery (1), for example devices and vehicles.

The device for controlling the temperature of a battery (1) can be used in all devices in which a battery is to operate at a certain temperature, for example in motor vehicles, in stationary power stores (for example in connection with photovoltaic systems or wind turbines) or in

Power tools. A particular embodiment of the invention relates to the use of the device for temperature control of a battery (1) in vehicles, such as cars, ships, aircraft, motorcycles.

The advantages of the device according to the invention for controlling the temperature of a battery (1) are that a car can start at very low temperatures without requiring an energy-intensive preheating of the battery by means of a separate system. Energy consumption for preheating the battery at low ambient temperatures is reduced. With the device, a faster heating of the battery can be achieved, the warm-up phase is shortened. With the device, operation of the battery in the optimal

Temperature range can be ensured. This can increase the life of the battery. An additional battery heater may be unnecessary. As a result, the manufacturing and repair costs are reduced.

The invention can be detected clearly and simply visually or by simple measuring technology on the product by the use of a heating / cooling medium with latent heat storage.

Claims

claims

1. A device for tempering a battery (1) comprising a battery (2) and a latent heat storage (3), which can change its state of matter from liquid to solid and thereby heat of crystallization for heating the battery (2) can deliver and wherein the crystallization by a Pulse can be triggered.

2. A device for tempering a battery (1) comprising a battery (2) and a latent heat storage (3), which can absorb excess heat of the battery (2) and thereby changes its state of aggregation from solid to liquid and thus the battery (2) cools ,

3. Device according to one of claims 1 or 2, characterized in that the latent heat storage (3) is a gel.

4. Device according to one of claims 1 to 3, characterized in that the latent heat accumulator (3) is in a housing (4) which is arranged around the battery (1).

5. Device according to one of claims 1 to 3, characterized in that the latent heat accumulator (3) in a plurality of separate housings (4), which is arranged around the battery (1).

6. Apparatus according to claim 5, characterized in that the change of the state of aggregation of the latent heat storage (3) in the separate housings (4) can be controlled independently.

7. Device according to one of claims 1 to 3, characterized in that the latent heat storage (3) is located directly in the battery (1).

8. product comprising a device according to one of claims 1 to 7.

9. A method for heating a battery (2), characterized in that a battery (2) with a latent heat storage (3) is brought into contact and wherein the latent heat storage (3) has a liquid state of matter and the latent heat storage (3) its state of aggregation can change liquid to firm and thereby heat of crystallization to

 Heating the battery (2) gives off and wherein the crystallization of the

 Latent heat storage (3) is triggered by a pulse.

10. A method for cooling a battery (2), characterized in that a battery (2) with a latent heat storage (3) is brought into contact, wherein the latent heat storage (3) has a solid state and the latent heat storage (3) can absorb heat and thereby changes its state of aggregation from solid to liquid.