WO2016001091A1

WO2016001091A1 - Method and device for cooling a battery

Info

Publication number: WO2016001091A1
Application number: PCT/EP2015/064554
Authority: WO
Inventors: Theodoros Papadopoulos; Jochen SCHÄFER; Wolfgang Weydanz
Original assignee: Siemens Aktiengesellschaft
Priority date: 2014-07-02
Filing date: 2015-06-26
Publication date: 2016-01-07
Also published as: DE102014212833A1

Abstract

The invention relates to a method for cooling a battery (2), in which at least one electrolyte liquid (4) of the battery (2) is conducted to a heat exchanger (8) for cooling, waste heat (10) of the electrolyte liquid (4) is transferred via the heat exchanger (8) to a heat sink (121, 122, 123) and in which a temperature of the heat sink (121, 122, 123) is determined. According to the invention, the electrolyte liquid (4) is conducted to the heat exchanger (8) if the determined temperature of the heat sink (121, 122, 123) is lower than or equal to a predetermined threshold temperature. The invention further relates to a device for cooling a battery (2).

Description

description

The invention relates to a method according to the preamble of claim 1 and a device according to the description of the claim 11 Oberbe ^¬ .

One of the biggest challenges in the energy industry is the development of reliable and highly efficient energy storage systems. An efficient Energiespei ^¬ chersystem is a liquid redox battery (eng. Redox flow battery) which is formed for example as vanadium redox battery liquid. In general, a redox liquid battery consists of two containers each comprising an electrolyte liquid (electrolyte). The two Elect ^¬ rolytflüssigkeiten electrochemically coupled within a reactor by means of a membrane, whereby an electrical nenfluss and thus creates an electrical voltage. For example, a vanadium redox liquid battery has an open circuit voltage of 1.41V at an operating temperature of about 25 ° C.

Most redox liquid batteries have an operating temperature in the range of 10 ° C to a maximum of 35 ° C. In an operation ^¬ temperature above 35 ° C typical electrolyte ^¬ liquids begin to crystallize at least partially. Below 10 ° C, the efficiency of known redox liquid batteries drops significantly. It follows that the temperature of the electrolyte liquids or the operating temperature of redox liquid batteries must always be within a certain temperature range, for example from 10 ° C to 35 ° C. However, up occur much higher temperatures, particularly during loading or Entla ^¬ dens of redox liquid batteries. The increase of the temperatures takes place, for example due to losses in the chemical process, resistive losses or losses during operation of pumps.

According to the state of the art, cooling of redox liquid batteries takes place by means of a cooler, in particular a fan, which actively cools the redox liquid battery during its operation, for example during loading or unloading. Typically, the redox liquid battery is cooled if the temperature of the electrolyte liquids is above 32 ° C. By the connection of the

Cooling incurs additional costs for the electrical supply of the cooling system. Especially at high ambient temperatures ^¬ temperatures, for example above 25 ° C, an approximately constant cooling and therefore additional electrical power is needed.

The present invention has for its object to improve the cooling of a battery. The object is achieved by a method having the features of independent claim 1, and by a device having the features of independent claim 11 ge ^¬ triggers. In the dependent claims, advantageous Substituted ^¬ staltungen and developments of the invention are given.

In the inventive method for cooling a battery, a liquid electrolyte of the battery for cooling is at least directed to a heat exchanger to transfer a waste heat of the electrolyte fluid through the heat exchanger to a heat sink, and a temperature of the heat sink, it averages ^¬. According to the invention, the line of electrolyte ^¬ liquid is carried to the heat exchanger, if the determined Tempe ^¬ temperature of the heat sink is less than or equal to a predetermined limit temperature. According to the invention the cooling of the battery, which a heat exchanger is carried UNMIT ^¬ telbar via line the electrolyte liquid, not solely determined by a maximum operating temperature of the battery, but by a boundary temperature of the heat sink. If the temperature of the heat sink is less than or equal to the predetermined limit temperature, the electrolyte fluid is conducted to the heat exchanger. As a result, a particularly efficient cooling of the electrolyte fluid and thus of the battery as a whole is advantageously made possible. By determining the limit temperature and determining the temperature of the heat sink, it is possible to operate the battery without further cooling, for example during charging or discharging of the battery.

In particular, it is provided that the line of the electrolytic ^¬ lytflüssigkeit to the heat carrier takes place only in the resting state of the battery. As a resting state of the battery is to be understood here ^¬ in a state in which the battery neither corresponds invite yet is loaded. Advantageously, thus the battery is cooled at rest. In other words, a pre-cooling of the electrolyte liquid of the battery.

According to the invention, the cooling of the battery takes place directly via the electrolyte ^liquid which is conducted to the heat exchanger, which heat exchanger is thermally coupled to a heat sink. This is of advantage since ty ^¬ european liquid electrolytes have a high compared to water thermal heat capacity. Furthermore, for typical, known in the prior art batteries optionally high levels of electrolyte fluid is needed, so that in turn more heat through the electrolyte liquid can be dispensed and discharged. Due to the thermal inertia of the electrolyte fluid, which is due to the high total mass of the electrolyte fluid is, the line and thus the cooling of the electrolyte ^¬ liquid exclusively take place when the determined temperature of the heat sink is less than or equal to the predetermined limit temperature. In other words, in particular, no steady, ie continuous cooling of the Batte ^¬ rie done. Only under advantageous and suitable conditions, that is, that the temperature of the heat sink is less than or equal to the predetermined limit temperature, the electrolyte liquid is passed to the heat carrier and thus the battery is cooled. By a sufficiently long time cooling the

Electrolyte liquid is made possible due to the thermal inertia of the electrolyte liquid, even during operation of the battery, for example, not advantageous Bedingun ^¬ gene, that is at a temperature of the heat sink is greater than the predetermined limit temperature, the reliable operation of the battery.

The device according to the invention comprises a battery with at least one electrolyte fluid, one

Heat exchanger, wherein the heat exchanger is fluidly coupled to the battery by means of the electrolyte liquid, a unit for determining a temperature of a thermally coupled to the heat exchanger heat sink and a control unit. According to the invention, the control unit forms a line of the electrolyte liquid for

Heat exchanger to cause, if the determined temperature of the heat sink is less than or equal to a predetermined limit temperature. In other words, the conduction of the Elektrolytflüssig ^¬ speed to the heat exchanger and thus the cooling of the battery is then or only if appropriate conditions prevail, that is, the temperature of the heat sink is sufficiently small. As a sufficiently small temperature of the heat sink, a temperature is designated, which is less than or equal to the predetermined limit temperature. It results to the invention the method according to the invention similar and equivalent Vortei ^¬ le of the device according to the invention.

According to an advantageous embodiment of the invention, a heat surrounding the ambient air is ver ^¬ used as a heat sink, wherein a night temperature of the surrounding air during the night is set as the limit temperature.

In other words, the battery is cooled during the night. At night, the air surrounding the heat exchanger (ambient air) typically has a temperature which is lower than a temperature of the surrounding air during the day. The night temperature may be an average of the ambient air temperatures or a maximum ambient air temperature during the night. The limit temperature then ^corresponds to the predetermined or specified night temperature. Further, as the ambient air, the medium or the fluid is referred to, which surrounds the heat exchanger at least partially during normal use.

For example, if a particular by averaging Nachttem ^¬ temperature of 18 ° C is present, the cooling of the electrolyte liquid ^¬ takes place by means of the ambient air at a mean temperature of the heat sink of 18 ° C. Since the night-time temperature of the heat sink is typically less than a ^¬ entspre accordingly certain days temperature (average temperature of the ambient air during the day), the cooling of the electric ^¬ lytflüssigkeit or the battery is significantly verbes ^¬ sert. In particular, the electrolytic liquid is cooled down during the night, so that should be no additional cooling of the liquid electrolyte or the battery during the day or currency ^¬ rend an operation on the day at best. In other words, the cooling of the battery un ^¬ ter appropriate conditions takes place, that is at a temperature as low as possible wrestle the heat sink. The cooling of the battery or of the electrolyte fluid is adjusted to the temperature. temperature of the heat sink or tuned to the changes in the temperature of the heat sink.

In particular, it is advantageous if the limit temperature is less than a daytime temperature of the surrounding air, wherein as the daytime temperature, a temperature of the surrounding air is determined during the day.

In other words, the cooling of the battery or of the electrolyte liquid takes place exclusively during the night, that is to say exclusively under suitable conditions. The battery is therefore not cooled during the day. Cooling during the day is vorteilhafterwei ^¬ se with sufficient cooling during the night, not necessary, since the cooling of the electrolytic liquid during the night, the temperature of the electrolytic liquid has enough ge ^¬ lowers, so that due to the thermal inertia of the electrolyte liquid even during the operation of the Batte ^¬ ry day, the temperature of the electrolyte liquid underneath remains operational, critical temperature.

In an advantageous embodiment of the invention, a soil is used as a heat sink. In other words, the heat exchanger is at least partially surrounded by the soil or at least partially ^¬ introduced into the soil. Advantageously, the temperature of the soil in a fixed depth is approximately constant, so that independent of day and night, a cooling of the battery takes place. For example, the ited ^¬ temperature is determined in such a way so that it is less than or equal to an average temperature of the soil in said depth. The depth should be selected so that the best possible cooling of the electrolyte liquid takes place. According to a further advantageous embodiment of the invention, a body of water is used as a heat sink.

Here, the heat exchanger is at least partially surrounded by the water or at least partially arranged in the water. In other words, a part of the thermal energy (heat) of the liquid electrolyte ^¬ ness by means of the heat exchanger to the water übertra ^¬ gen, if a detected temperature of the water is below the predetermined threshold temperature is at least. As a threshold temperature is a maximum temperature of the water or mittle ^¬ re temperature of the water can be determined, wherein the time ^¬ Liche averaging is performed for example over a night and / or day. The collection of discrete measured values of tem- temperature during the night and / or during the day is seen ^¬.

Advantageously, the arrangement of the

Heat exchanger within the water allows an approximately time lately continuous cooling of the battery under favorable conditions. Heating the body of water so that its temperature is too strongly above the limit temperature, a cooling of the battery through the lead of Elect ^¬ rolytflüssigkeit is not provided to the heat exchanger, so that optionally have to be made classic of cooling. As a body of water, a river or a lake can be used.

According to an advantageous embodiment of the invention, the line of the electrolyte liquid is regulated to the heat exchanger by means of a control unit, wherein the control unit for regulating at least takes into account the temperature of the heat sink. In particular, further physical variables which are present in ^¬ example by means of light sensors or mass flow sensors provided for. In other words, the control unit is used for determining and evaluating the externa ^¬ ßeren conditions of the battery. If the external conditions of the battery low, that is, the temperatures of the heat sink is at least less than or equal to the threshold temperature, as is done by the control unit a Regelsig ^¬ nal which a line of electrolyte fluid to

Heat exchanger and consequently causes a direct cooling of the electrolyte liquid.

Preferably, the control unit takes into account the price for an electric energy which is electrical energy used for operating a cooling device in the control where the ^¬ at the cooling device, for example for cooling

Heat exchanger, the electrolyte fluid and / or the Bat ^¬ terie is used if the price is less than a marginal price.

In other words, a classic cooling device is used for cooling, if the price of the electrical energy Ener ^¬, which is required for the use of the cooling device is sufficiently small. As a sufficiently small price here is a price that is less than a marginal price. Typically, the cost of electrical energy during the night is less than the day, so the

Limit price can be set such, for example, as the average price at night, so that the additional cooling by means of the cooling device takes place only during the night. This cost and energy can be saved so that advantageously the efficiency and Energiebi ^¬ lance the battery is improved.

As a cooling device, a fan, a cooler

and / or a refrigerator may be provided. In particular, the said cooling devices are used exclusively when an excess of electrical energy to Available. In other words, the price of electrical energy for operating the cooling devices mentioned is comparatively low. According to an advantageous embodiment of the invention, a mass flow of the electrolyte liquid is regulated to the heat exchanger.

Advantageously, the control of the mass flow of the electrolyte liquid to the heat exchanger by means of the control ^¬ unit. To control the mass flow mass flow sensors and / or valves may be provided.

For conducting the electrolyte liquid to the heat exchanger at least one pumping device is provided, wherein the pumping device is designed to pump the electrolyte liquid to the heat exchanger. In particular, the mass flow of the electrolyte liquid can be adapted to the needs of cooling or to the required cooling. If, for example, a greater cooling of the electrolyte liquid is to be achieved, this can be brought about by an increased mass flow of the electrolyte liquid to the heat exchanger. Further advantages, features and details of the invention follow from the ^¬ described in the following embodiments and from the drawings. Here show schematically: Figure 1 a liquid battery, which is fluidly coupled via a first electric ^¬ lytflüssigkeit with a heat exchanger, wherein the heat exchanger transfers heat a ^trailing the first electrolyte liquid to a ^¬ To bient; 2 shows a liquid battery, which is fluidly coupled via a first electric ^¬ lytflüssigkeit with a heat exchanger, wherein the heat exchanger order ^¬ bient transmits a ^trailing heat the first electrolyte liquid at one and the heat exchanger is cooled with ^¬ means of a fan;

3 shows a liquid battery, which is fluidly coupled via a first electric ^¬ lytflüssigkeit with a heat exchanger, said heat exchanger in a

Soil is arranged; and

4 shows a liquid battery, which is fluidly coupled via a first electric ^¬ lytflüssigkeit with a heat exchanger, said heat exchanger in a

Water is arranged.

Similar elements may be provided in the figures with the same reference numerals.

Figure 1 schematically shows a battery 2, which is formed as a liquid ^¬ battery 2 and a first and second electric ^¬ lytflüssigkeiten 4, comprising. 6 Furthermore, FIG. 1 shows a heat exchanger 8, which uses the first electrolyte liquid 4 as the working medium. The liquid battery 2 further comprises the second electrolyte liquid 6, wherein the first electrolyte liquid 4 and the second electrolyte liquid 6 are electrochemically coupled within a reactor 24 by means of a non ^{dargestell ¬} th membrane. The first and second electrolyte liquids 4, 6 circulate within the liquid battery 2 in a first and second circuit 31, 32. Furthermore, the liquid battery 2 comprises at least two containers 20, wherein the first and second electrolyte liquids 4, 6 respectively in one of the containers 20 at least Part are arranged. The circuits 31, 32 each comprise Wenig ^¬ least a pump 19. The circulation directions of the first and second electrolyte liquid 4, 6 within the first and second circuits 31, 32 are illustrated by arrows.

For example, the first and second Elektrolytflüssig- can ness 4, 6, vanadium (V) are based, so that the first Elect ^¬ rolytflüssigkeit V ^{3 +} and V ^2+, and the second electrolyte liquid ^¬ ness 6 V0 ²⁺ and VC> ₂ ⁺ ions comprising , When the liquid battery 2 is charged, the V0 ²⁺ ions of the second electrolyte liquid 6 are electrochemically oxidized to V0 ₂ ⁺ ions at the anode of the liquid battery 2. The V ³⁺ ions to V ²⁺ ions reduced at the cathode of Flüssigbatte ^¬ rie. 2 When discharging the liquid battery 2, for example by means of a Ver ^¬ brauchers that VC> ₂ ⁺ ions redu ^¬ sheet at the cathode to V0 ^2+, and V ²⁺ ions at the anode to oxidize V ³⁺ ions.

The first electrolyte liquid 4 is fluidly coupled to a liquid outside the battery 2 is arranged ^¬ heat exchanger 8 by means of a further circuit. Here, the first electrolyte liquid 4 is conducted at a first temperature 41 by means of a pump 18 to the heat exchanger 8. The first electrolyte liquid 4 is here by means of

Heat exchanger 8 thermal energy 10 (waste heat) to a surrounding the heat exchanger 8 air 121 (heat sink) from, if a temperature of the surrounding air 121 is less than or equal to a threshold temperature. As a result, the first electrolyte liquid 4 cools to a second temperature 42, which is reduced compared to the first temperature 41, the first electrolytic liquid 4, which is now cooled, being returned to the container 20 of the first circuit 31. Thereby, the first electrolyte 4, the Flüssigbatte ^¬ rie 2 is cooled as a whole. An appropriate cooling of the second Elect ^¬ rolytflüssigkeit 6 may be provided.

The line of the first electrolyte liquid 4 for

Heat exchanger 8 and consequently the cooling of the first electrolyte liquid 4 takes place when the temperature of the surrounded the air 121 is less than or equal to a predetermined limit temperature. Is as limit temperature an average night temperature ^¬ tur set, that is an average temperature of the vice ^¬ reproduced air 121 during the night, so cooling is sawn relationship, the line of the first electrolytic liquid 4 to the heat exchanger 8 during the night. In particular, in this case the predetermined threshold temperature, i.e., the mitt ^¬ sized night temperature of the surrounding air 121, lower than an average daily temperature, that is, as the mean temperature of the ambient air 121 during the day. As a result, the cooling of the liquid battery 2 or of the electrolyte liquid 4 takes place exclusively at night and thus under advantageous conditions, that is to say under the lowest possible temperature of the heat sink 121.

Discharge and / or loading 22 of the liquid battery 2 is typically during the day. By cooling flues ^¬ sigbatterie 2 during the night, the first Elektrolytflüs ^¬ sigkeit 4 is pre-cooled in such a way so that during operation the day, i.e. during the loading and / or unloading 22

Liquid battery 2 during the day, at best no ^{further ¬} re cooling of the liquid battery 2 and the first electrolyte liquid 4 must be made. In Figure 2 a liquid battery 2 according to Figure 1 is Darge ^¬ provides, in addition to Figure 1, a cooling of the

Heat exchanger 8 is effected by means of a fan 16.

In this case, Figure 2 shows the same elements as Figure 1. In other words, in Figure 2, the cooling of the first electrolyte liquid 4 via the heat exchanger 8 and the discharge of waste heat 10 to the surrounding air 121 supported by the fan 16. Preferably, the additional cooling of the heat exchanger 8 by means of the fan 16 takes place when sufficient electrical energy is available, that is, a price for the electrical energy as possible. ring is. This advantageously improves the cooling and the efficiency of the liquid battery 2.

Advantageously, the cooling of the liquid battery 2 takes place during the night, in particular exclusively during the

Night, so that in addition the cooling by means of the fan 16, due to the reduced temperature of the surrounding air 121 during the night, is improved. As a result, the efficiency of the liquid battery 2 is further improved.

Figure 3 shows a similar schematic structure of a liquid battery 2 as already Figure 1 and / or figure 2. Here, the liquid battery 2 comprises the same elements as the liquid already be ^¬ battery 2 in Figure 1 and / or FIG. 2

In the embodiment of the invention shown in FIG. 3, the cooling of the first electrolyte liquid 4 takes place by means of the line of the first electrolyte liquid 4 to a heat exchanger 8, which is arranged within a soil 122 (heat sink). In other words, the heat exchanger 8 is introduced into the soil 122. Advantageously, thus an approximately continuous cooling of the liquid battery 2 can be carried out under favorable conditions, since a (mean) temperature of the soil 122 during the day and during the night is approximately constant. Insbeson ^¬ particular, the temperature of the soil 122 - at a suitable depth - less than the maximum temperature of the surrounding air 121 a day. In Figure 3, the line of the first electrolytic liquid ^¬ ness 4 is carried to the heat exchanger 8 by means of a pump 18, if the detected (average) temperature of the soil 122 is ge ^¬ ringer than a predetermined limit temperature. The first electrolyte liquid 4 is conducted at a first temperature 41 to the heat exchanger 8 and gives at least a portion of its thermal energy 10 (waste heat) to the soil 122nd from. The thus cooled to a temperature 41 opposite the first lower second temperature 42 first Elektrolytflüs ^¬ sigkeit 42 is again returned to the container 20 of the first circuit 31st As a result, a total cooling of the first electrolyte liquid 4 and consequently the liquid ^¬ battery 2 is possible. A corresponding cooling of the second electrolyte liquid 6 can be provided.

FIG. 4 diagrammatically shows a further embodiment of the invention, the liquid battery 2 now being cooled by means of a body of water 123. In other words, the heat exchanger 8 is disposed outside of the liquid battery 2 and within ^¬ half of the water body 123 and surrounded by this at least partially. The water 123 may be a river or a lake.

In this case, the liquid battery 2 in FIG. 4 comprises the same elements as the liquid battery 2 in the preceding ^FIGS . 1 to 3.

As in Figure 3, the temperature of the water body 123 is substantially independent of day and night, so that a cooling of the first electrolyte liquid 4 can be made approximately kon ^¬ continuously. Here, the (mean) temperature of the water body 123 is less than or equal to the predetermined one

Limit temperature. In other words, cooling of the first electrolyte liquid 4 takes place only if the (average) temperature of the water body 123 is suitable for this, that is, the determined (average) temperature of the water body 123 is lower than a predetermined limit temperature. The temperature limit here is to determine such a way so that a mög ^¬ lichst efficient operation of the battery liquid becomes possible. 2 In general, for the line of the first electrolytic liquid ^¬ ness 4 to the heat exchanger 8 corrosion-resistant lines For example, lines that include plastic, ceramic and / or aluminum oxides provided. This is advantageous because, according to the prior art known Elektrolytflüs ^¬ fluids are corrosive. Care must be taken that the lines or the materials used for the lines additionally have a good thermal conductivity, so that the best possible heat transfer from the first electrolyte liquid 4 to the heat sink 121, 122, 123 is made possible. Furthermore, the method according to the invention can be used for other types of batteries known from the prior art, for example lithium-ion batteries.

Although the invention has been further illustrated and described in detail by the preferred embodiments, the invention is not limited by the disclosed examples, or other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims

claims

1. A method for cooling a battery (2), in which at least one electrolyte liquid (4) of the battery (2) for cooling to a heat exchanger (8) passed, a waste heat (10) of the electrolyte liquid (4) via the heat exchanger ( 8) is transferred to a heat sink (121, 122, 123) and in which a temperature of the heat sink (121, 122, 123) is determined, characterized in that the line of the electrolyte lytflüssigkeit (4) to the heat exchanger (8) if the determined temperature of the heat sink (121, 122, 123) is less than or equal to a predetermined limit temperature.

2. The method according to claim 1, characterized in that the line of the electrolyte liquid (4) to the heat exchanger

(8) takes place exclusively in the idle state of the battery (2).

3. The method according to claim 1 or 2, characterized in that as the heat sink (121, 122, 123) a heat exchanger (8) surrounded air (121) is used, wherein as Grenztempe ^¬ temperature a night temperature of the surrounding air (121) during the night is fixed.

4. The method according to claim 3, characterized in that the limit temperature is less than a daytime temperature of the surrounding air (121), wherein a daytime temperature, a temperature of the surrounding air (121) is set during the day.

5. The method according to any one of the preceding claims, characterized in that a Erd ^¬ rich (122) is used as a heat sink (121, 122, 123).

6. The method according to any one of the preceding claims, characterized in that a Ge ^¬ water (123) is used as a heat sink (121, 122, 123).

7. The method according to any one of the preceding claims, characterized in that the line of the electrolyte liquid

(4) to the heat exchanger (8) is regulated by means of a control unit, wherein the control unit for controlling at least the temperature of the heat sink (121, 122, 123) takes into account.

8. The method according to claim 7, characterized in that the heat exchanger (8) by means of a cooling device (16) is cooled, if a berücksich ^¬ tigte by the control unit price for an electrical energy, which electrical energy is used to operate the cooling device klei ^¬ ner is equal to a marginal price.

9. The method according to claim 8, characterized in that as a cooling device (16), a fan (16), a cooler and / or a refrigerator are used.

10. The method according to any one of the preceding claims, character- ized in that a mass flow of the electrolyte ^¬ liquid to the heat exchanger (8) is controlled.

11. Device comprising a battery (2) with at least one electrolyte liquid (4), a heat exchanger (8), wherein the heat exchanger (8) by means of the electrolyte liquid ^¬ speed (4) is fluidically coupled to the battery (2), a unit for determining a temperature of a with

Heat exchanger (8) thermally coupled heat sink (121, 122, 123) and a control unit, characterized in that the control unit is formed a line of

Electrolyte liquid (4) to cause the heat exchanger (8), if the determined temperature of the heat sink (121, 122, 123) is less than or equal to a predetermined limit temperature.

12. The device according to claim 11, characterized in that at least a part of the heat exchanger (8) in a soil (122) is arranged.

13. The apparatus according to claim 11 or 12, characterized in that at least a part of the heat exchanger (8) in a body of water (123) is arranged.

14. Device according to one of claims 11 to 13, with a cooling device (16), which is used for cooling the

Heat exchanger (8) is formed.

15. Device according to one of claims 11 to 14, with we ^¬ least one pumping device (18), wherein the Pumpeinrich- device (18) is adapted to pump the electrolyte liquid (4) to the heat exchanger (8).