JP6213712B2 - Injection system - Google Patents

Description

  The present invention relates to an injection system. More specifically, the present invention relates to a liquid injection system mounted on a vehicle.

  Conventionally, as an “apparatus for injecting a battery,” an electrolyte injecting apparatus used in a battery manufacturing process for the purpose of shortening an injecting time has been proposed (see Patent Document 1).

  This electrolyte solution injection device stores a power generation element having a positive electrode and a negative electrode laminated via a separator in a reduced pressure injection tank, and injects the electrolyte solution into a battery case having an opening. This is an electrolyte solution injection device. And this electrolyte solution injection apparatus adjusts the atmospheric pressure of the electrolyte solution supplied by the electrolyte solution supply means that supplies the electrolyte solution into the injection tank, and the electrolyte solution supplied by the electrolyte solution supply means to the atmospheric pressure in the solution injection tank And a degassing means for degassing the electrolyte solution that has passed through the electrolyte pressure adjusting means with a gas permeable membrane. The liquid is injected into the inside.

JP 2011-222221 A

  However, Patent Document 1 does not describe anything about mounting an electrolyte solution injection device on a vehicle. Therefore, no study has been made on the application of a battery injected by an electrolytic solution injection device mounted on a vehicle.

  The present inventors made it a new problem to be solved to provide a liquid injection system capable of starting a battery when necessary and capable of extending the cruising distance of a vehicle. That is, an object of the present invention is to provide a liquid injection system that can start a battery when necessary and can increase the cruising range of a vehicle.

The inventors of the present invention have made extensive studies in order to achieve the above object. As a result, a liquid supply channel that is applied to a predetermined in-vehicle battery system and connects the storage container and the liquid injection type auxiliary battery, one or a plurality of valves disposed in the liquid supply channel, and a valve and the valve control means for controlling, a valve control means, such as by a configuration in which the valve open state in order to start the supply of the liquid to the liquid injection type auxiliary battery from the storage container, the object is achieved The present inventors have found that this can be done and have completed the present invention.

That is, the liquid injection system of the present invention can be used for charging and discharging a main battery that can be charged and discharged and that can operate a motor for driving a vehicle. And a single or a plurality of liquid injection molds that are formed by supplying a liquid stored in at least one storage container that stores a liquid for preparing an electrolytic solution, and that have one or a plurality of electrode structures. The present invention is applied to a battery system including an auxiliary battery. The liquid injection system of the present invention includes a liquid supply channel that connects the storage container and the liquid injection type auxiliary battery, one or more valves disposed in the liquid supply channel, and a valve control that controls the valve. and means, and valve control means, and the like which the valve open state in order to start the supply of the liquid to the liquid injection type auxiliary battery from the storage container.

According to the present invention, a main battery that can be charged and discharged and that can operate a motor for driving a vehicle, a main battery that can be used for charging the main battery, and an electrolysis A single or a plurality of liquid injection type auxiliary batteries established by supplying a liquid stored in at least one storage container storing a liquid for preparing a liquid, and having one or a plurality of electrode structures; Applied to a battery system comprising: a liquid supply channel connecting a storage container and a liquid injection type auxiliary battery; one or more valves disposed in the liquid supply channel; and valve control means for controlling the valve When provided with a valve control means and the like which the valve open state in order to start the supply of the liquid to the liquid injection type auxiliary battery from the storage container. Therefore, it is possible to provide a liquid injection system that can start the battery when necessary and can increase the cruising range of the vehicle.

FIG. 1 is a schematic configuration diagram of a liquid injection system according to the first embodiment. FIG. 2 is a schematic configuration diagram of the liquid injection system according to the second embodiment. FIG. 3 is a schematic configuration diagram of the liquid injection system according to the third embodiment. FIG. 4 is a schematic configuration diagram of the liquid injection system according to the fourth embodiment. FIG. 5 is a cross-sectional view showing an outline of the supply amount adjusting structure channel in FIG. FIG. 6 is a longitudinal sectional view showing an outline of the supply amount adjusting structure channel in FIG. FIG. 7 is a schematic configuration diagram of a liquid injection system according to the fifth embodiment. FIG. 8 is a cross-sectional view showing the outline of the supply amount adjusting structure flow path in FIG. FIG. 9 is a longitudinal sectional view showing an outline of the downstream branch liquid supply passage in FIG. FIG. 10 is a schematic configuration diagram of a liquid injection system according to the sixth embodiment. FIG. 11 is a schematic configuration diagram of a liquid injection system according to the seventh embodiment. FIG. 12 is a schematic configuration diagram of a liquid injection system according to the eighth embodiment. FIG. 13 is a schematic configuration diagram of a liquid injection system according to the ninth embodiment. FIG. 14 is a schematic configuration diagram of an injection system according to the tenth embodiment. FIG. 15 is a flowchart for explaining an example of the flow of availability of the injection-type auxiliary battery.

  Hereinafter, an injection system according to an embodiment of the present invention will be described in detail with reference to the drawings. In addition, the dimension ratio of drawing quoted with the following forms is exaggerated on account of description, and may differ from an actual ratio. In the drawings cited in the following forms, data related to control is transmitted (received) between the control unit and other components, and the mode is divided into Roman numerals for the control and other components. Is shown in addition. Data transmission (reception) is performed between corresponding Roman numerals.

<First form>
First, the liquid injection system according to the first embodiment will be described in detail with reference to the drawings. FIG. 1 is a schematic configuration diagram of a liquid injection system according to the first embodiment. As shown in FIG. 1, the liquid injection system 1 is applied to a battery system 100 including a main battery 110 and a liquid injection type auxiliary battery 120. In the battery system 100, the main battery 110 is connected by the electric circuit a via the driving motor 130 and the power converter 132 of the driving motor 130, and is connected by the liquid injection type auxiliary battery 120 by the electric circuit b. Yes.

  Here, in the present invention, as the main battery, for example, a secondary battery such as a lithium ion secondary battery is preferably applied from the viewpoint of high energy density and excellent cycle characteristics. However, the battery is not limited to this as long as it is a chargeable / dischargeable battery, and a conventionally known secondary battery can be applied.

  Further, in the present invention, the injection-type auxiliary battery has a single internal electrode structure as long as it is established by supplying a solvent that is a liquid for preparing an electrolytic solution or the electrolytic solution itself. Even if there are a plurality of them, there is no particular limitation. Furthermore, it is preferable to apply an air battery from the viewpoint that the liquid injection type auxiliary battery has a high energy density per volume and is suitably mounted on a vehicle as the auxiliary battery.

  Although not shown, the electrode structure in the present invention is, for example, a structure in which a separator is sandwiched between a positive electrode and a negative electrode, and a liquid for preparing an electrolytic solution is supplied between the positive electrode and the negative electrode. A so-called single cell is formed by holding the electrolytic solution. In addition, when an air battery is applied as a liquid injection type auxiliary battery, the electrode structure is a structure in which a separator is sandwiched between a positive electrode and a negative electrode, and the surface of the positive electrode is opposite to the surface on the separator side. It is necessary to further have an oxygen-containing gas supply channel through which an oxygen-containing gas such as air flows.

  Thereby, at the normal time, the main battery can operate the drive motor of the vehicle (not shown).

  Moreover, in the liquid injection system 1, the liquid injection type auxiliary battery 120 has a plurality (two in this case) of storage containers 10A and 10B for storing the liquid L for preparing the electrolytic solution, and valves 30A and 30B. , 30C and a liquid 40 having an upstream branch liquid supply channel 21 branched corresponding to the storage containers 10A and 10B on the upstream side in the liquid supply flow direction, in which the pump 40 which is an example of a liquid quick supply means is disposed They are connected by a supply channel 20.

  The liquid injection system 1 includes a control unit C that functions as a valve control unit C1 that controls the valve. The valve control unit C1 supplies the liquid L from the storage containers 10A and 10B to the liquid injection type auxiliary battery 120. In order to start the supply, the valves 30A, 30B, 30C are opened. In normal times, the valves 30A, 30B, and 30C are closed. Moreover, the control unit C starts the pump 40 as needed.

  Thereby, the injection type auxiliary battery can be used for charging the main battery. Therefore, the main battery can be activated when necessary, and the cruising range of the vehicle can be increased.

  In addition, although not shown in figure, it is good also as a structure which comprises a some injection type auxiliary battery. Details will be described later.

  Moreover, although not shown in figure, it is good also as a structure which has one storage container. In addition, when mounting a liquid injection system in a vehicle, it is preferable to set it as the structure which has a some storage container from a viewpoint that the freedom degree of arrangement | positioning in the vehicle of a storage container can be raised.

  Further, although not shown, a single valve may be provided. In addition, as a valve, it is not limited to a two-way valve, According to the position arrange | positioned in a liquid supply flow path, conventionally well-known valves, such as a three-way valve, can be utilized suitably.

  Further, although not shown in the drawings, the liquid quick supply means may not be provided as long as the liquid can be supplied by, for example, free fall. Although not shown, the storage container may have a liquid quick supply means. By having the liquid quick supply means, the degree of freedom of arrangement of the storage container can be increased, and for example, even when the viscosity of the liquid is high, the liquid can be quickly supplied to the liquid injection type auxiliary battery. .

  Further, when the liquid is a solvent, although not shown, a supporting salt for preparing the electrolytic solution may be held in the air battery in advance. And although mentioned later in detail, it is good also as a structure which stores a supporting salt separately.

  In addition, either or both of the storage container and the liquid supply flow path may have one or both of a heating device disposed adjacent to the storage container and a heating device disposed in the vicinity thereof. It is preferable from the viewpoint that the liquid in the storage container is heated and hardly freezes below freezing point or is easily thawed even when frozen. Further, since the liquid is heated, the power generation amount in the liquid injection type auxiliary battery can be improved. Furthermore, since the liquid is heated, the liquid injection type auxiliary battery can be activated even at low temperature activation. As the heating device, for example, a driving motor, a power conversion device for the driving motor, a main battery, or a device that generates heat when the vehicle according to any combination thereof is used can be used. Use of these is preferable because it is not necessary to provide a separate heating device. For example, a storage container 10A that stores a liquid L for preparing an electrolytic solution in the case of using a drive motor, a power converter for the drive motor, and a main battery as a heating device is shown by a one-dot chain line in FIG. Although not shown, the storage container indicated by the alternate long and short dash line is connected to the predetermined liquid supply flow path.

<Second form>
Next, the liquid injection system according to the second embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 2 is a schematic configuration diagram of the liquid injection system according to the second embodiment. As shown in FIG. 2, in the liquid injection system 1 </ b> A, the remaining electric capacity detecting unit 112 that detects the remaining electric capacity of the main battery 110 and the result detected by the remaining electric capacity detecting unit 112 are used. The configuration including the control unit C functioning as the chargeability determination means C2 for determining whether or not the battery can be charged is different from the liquid injection system according to the first embodiment described above.

  In the liquid injection system 1A, when the chargeability determination unit C2 determines that the main battery 110 can be charged by the liquid injection type auxiliary battery 120, the valve control unit C1 stores the storage containers 10A and 10B. Then, the valves 30A, 30B, and 30C are opened to start the supply of the liquid L to the liquid injection type auxiliary battery 120. In normal times, the valves 30A, 30B, and 30C are closed. Moreover, the control unit C starts the pump 40 as needed.

  Here, as the remaining electric capacity detection means, for example, a voltmeter for measuring the open-end voltage of the main battery can be applied. However, the remaining electric capacity detecting means is not particularly limited as long as it can detect the remaining electric capacity of the main battery, and a conventionally known one can be appropriately used.

  In addition, as the chargeability determination means, when used together with the voltmeter, a device that determines chargeability based on data indicating the relationship between the open-circuit voltage of the main battery and the remaining electric capacity can be applied. However, as the chargeability determination means, any conventionally known one can be appropriately used as long as it can determine whether the main battery can be charged based on the result detected by the remaining electric capacity detection means. . Further, for example, as a criterion for determination, it is possible to determine in advance that charging is performed when the remaining electric capacity becomes less than 20%. Moreover, it is preferable to apply what determines whether charging is possible by adding the travelable distance of the vehicle and the positions of the vehicle and the charging station to the determination criteria. Furthermore, it is preferable to apply a battery that determines whether or not charging is possible in addition to the operating condition of the main battery. This is because if the battery is further charged while the main battery is operating, the main battery is deteriorated. Also, if the rechargeable capacity is smaller than the electric capacity of the liquid injection type auxiliary battery, such as when the remaining electric capacity of the main battery exceeds 80%, it is determined that the main battery cannot be charged. May be.

  Although not shown, the chargeability determination unit may have a separate configuration as long as it can cooperate with the valve control unit.

  Thereby, at the normal time, the main battery can operate an electric motor for driving a vehicle (not shown), and when necessary, the liquid injection type auxiliary battery can be used for charging the main battery. Is possible. And a main battery can be started when needed and the cruising range of a vehicle can be expanded. As will be described in detail later, a case where the remaining electric capacity of the main battery exceeds 80% or a case where the main battery is operating may be determined as a case where the main battery cannot be charged.

<Third embodiment>
Next, the liquid injection system according to the third embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 3 is a schematic configuration diagram of the liquid injection system according to the third embodiment. As shown in FIG. 3, in the liquid injection system 1 </ b> B, the remaining electric capacity detecting unit 112 that detects the remaining electric capacity of the main battery 110 and the result detected by the remaining electric capacity detecting unit 112 are used. Based on the results detected by the control unit C functioning as the chargeability determination means C2 for determining whether or not the battery can be charged, the specification detection means 122 for detecting the specifications of the injection type auxiliary battery 120, and the specification detection means 122, A control unit C that functions as a supply amount determination unit C3 that determines a predetermined liquid supply amount to be supplied to the liquid injection type auxiliary battery 120, and a liquid supply channel 20 that is an example of a supply amount measurement unit that measures the supply amount of the liquid L. And the supply amount of the liquid L measured by the mass flow meter 50 which is an example of the supply amount measuring means. The liquid injection system according to the first embodiment described above includes a control unit C that functions as supply amount determination means C4 that determines whether or not the predetermined liquid supply amount determined by the amount determination means C3 has been reached. Is different.

  In the liquid injection system 1B, when the chargeability determination unit C2 determines that the main battery 110 can be charged by the liquid injection type auxiliary battery 120, the valve control unit C1 stores the storage containers 10A and 10B. The valve 30A, 30B, 30C is opened to start the supply of the liquid L to the liquid injection type auxiliary battery 120, and the supply amount determination means C4 is measured by the mass flow meter 50 which is an example of the supply amount measurement means. When it is determined that the supply amount of the liquid L that has reached the predetermined liquid supply amount, the valve control means C1 uses the valve to stop the supply of the liquid L from the storage containers 10A and 10B to the liquid injection type auxiliary battery 120. 30A, 30B, and 30C are closed. In normal times, the valves 30A, 30B, and 30C are closed. Moreover, the control unit C starts the pump 40 as needed.

  Here, as the specification detection means, for example, a sensor that detects a predetermined liquid supply amount of the injection-type auxiliary battery based on a difference in the outer structure of the battery can be applied. However, the usage detecting means is not particularly limited as long as it can detect the predetermined liquid supply amount of the injection-type auxiliary battery, and conventionally known ones can be appropriately used. For example, an image of a battery exterior or an IC tag can be cited as a detection target of an available sensor.

  Further, as the supply amount determining means, when used together with the above sensor, a device that determines the predetermined liquid supply amount based on the data indicating the relationship between the exterior structure of the injection type auxiliary battery and the predetermined liquid supply amount may be applied. it can. However, as the supply amount determining means, a conventionally known one is appropriately used as long as the predetermined liquid supply amount to be supplied to the injection type auxiliary battery can be determined based on the result detected by the specification detecting means. Can be used. That is, an arithmetic processing unit that stores map data indicating the relationship between the detection target data of the sensor and the predetermined liquid supply amount can be appropriately used.

  Further, as the supply amount judging means, a means for judging by comparing a liquid supply amount measured by a supply amount measuring means described later with a predetermined liquid supply amount determined by the above-mentioned supply amount determining means is applied. Can do. That is, it is possible to appropriately use an arithmetic processing device that takes in and calculates the supply amount data sent from the supply amount measuring means and the predetermined liquid supply amount sent from the supply amount determining means.

  Further, the supply amount measuring means is not limited to the mass flow meter. For example, as long as the supply amount of liquid from the storage container to the injection type auxiliary battery can be measured, for example, the injection type auxiliary Conventionally known ones such as a weigh scale for measuring a change in the weight of the battery or the storage container, a voltmeter for measuring a change in the open end voltage of the liquid injection type auxiliary battery can be applied. Although not shown, when applied to a battery system having a plurality of liquid injection type auxiliary batteries, the change in the open end voltage of the liquid injection type auxiliary battery with the least liquid distribution may be measured. . Here, the liquid distribution tendency can be appropriately determined in a preliminary experiment or the like.

  Although not shown, the chargeability determination unit, the supply amount determination unit, and the supply amount determination unit may be configured separately if they can cooperate with the valve control unit.

  Thereby, at the normal time, the main battery can operate an electric motor for driving a vehicle (not shown), and when necessary, the liquid injection type auxiliary battery can be used for charging the main battery. Is possible. And a main battery can be started when needed and the cruising range of a vehicle can be expanded. Further, as described above, when the remaining electric capacity of the main battery exceeds 80% or when the main battery is in operation, it may be determined that the main battery cannot be charged. Furthermore, since a required amount of liquid can be supplied to the liquid injection type auxiliary battery, liquid leakage due to oversupply can be prevented.

<4th form>
Next, a liquid injection system according to a fourth embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 4 is a schematic configuration diagram of the liquid injection system according to the fourth embodiment. FIG. 5 is a cross-sectional view showing an outline of the supply amount adjusting structure channel in FIG. Further, FIG. 6 is a longitudinal sectional view showing an outline of the supply amount adjusting structure channel in FIG. The arrows in FIG. 5 and FIG. 6 indicate the liquid supply flow direction. As shown in FIGS. 4 to 6, the liquid injection system 1 </ b> C is applied to the battery system 100 including the liquid injection type auxiliary battery 120 having a plurality of electrode structures 124 </ b> A and 124 </ b> B, and supplies liquid as a liquid supply channel. The configuration in which the liquid supply flow path 20 having the supply amount adjustment structure flow path 22 for adjusting the supply amount of the liquid L supplied to the electrode structures 124A and 124B is provided at the downstream end portion in the flow direction is as described above. This is different from the liquid injection system according to the third embodiment.

  Further, as shown in FIGS. 5 and 6, the supply amount adjusting structure flow path 22 has a plate-like body 221 that divides the inside thereof vertically. The plate-like body 221 has a plurality of through holes α. Then, the liquid supplied to the supply amount adjusting structure flow path 22 circulates in the upper space of the plate-like body 221. Further, the plate-like body 221 has a diffuser 222 for making the flow velocity uniform on the upper side surface thereof. And the liquid which distribute | circulated the upper side space flows down to the lower side space of the plate-shaped body 221 through the through-hole (alpha). Further, the supply amount adjusting structure flow path 22 has a supply port β capable of supplying liquid to the electrode structures 124A and 124B, and the liquid flowing through the lower space passes through the supply port β to each electrode. It is supplied to the structures 124A and 124B. The supply amount adjusting structure flow path 22 has a gasket 223 for preventing liquid leakage at the connection portion with each electrode structure 124A, 124B.

  Here, the supply amount adjusting structure channel is not particularly limited as long as the supply amount of the liquid supplied to each electrode structure can be adjusted. For example, a plate-like body having a plurality of through holes can also prevent the liquid supplied to each electrode structure from flowing back into the liquid supply channel. In addition, the plate-like body having a plurality of through holes can alleviate that the additionally supplied liquid is vigorously supplied to each electrode structure. In addition, the supply amount adjusting structure channel can be formed by drilling or pressing using various materials such as resin and metal.

  Although not shown in the drawings, in the case where the region for supplying the liquid in the electrode structure is wide, a configuration including a liquid supply channel having a supply amount adjusting structure channel even if there is one electrode structure. It can be.

  Thereby, at the normal time, the main battery can operate the electric motor for driving the vehicle (not shown), and can inject all electrode structures in a short time when necessary. A liquid injection type auxiliary battery having a plurality of electrode structures can be used for charging the main battery. And a main battery can be started when needed and the cruising range of a vehicle can be expanded. Further, as described above, when the remaining electric capacity of the main battery exceeds 80% or when the main battery is in operation, it may be determined that the main battery cannot be charged. Furthermore, since a required amount of liquid can be supplied to the liquid injection type auxiliary battery, liquid leakage due to oversupply can be prevented.

<5th form>
Next, a liquid injection system according to a fifth embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 7 is a schematic configuration diagram of a liquid injection system according to the fifth embodiment. FIG. 8 is a cross-sectional view showing an outline of the supply amount adjusting structure channel in FIG. Further, FIG. 9 is a longitudinal sectional view showing an outline of the downstream branch liquid supply channel in FIG. The arrows in FIG. 8 and FIG. 9 indicate the liquid supply flow direction. As shown in FIGS. 7 to 9, the liquid injection system 1D is applied to a battery system 100 including a plurality of liquid injection type auxiliary batteries 120A and 120B having a plurality of electrode structures 124A and 124B. Downstream liquid supply flow paths 23A and 23B branched in correspondence with the respective liquid injection type auxiliary batteries 120A and 120B, and downstream branch liquid supply flow paths 23A and 23B. Are respectively provided with valves 30C and 30D, and supply amount adjusting structure flow paths 22A and 22B for adjusting the supply amount of the liquid supplied to the electrode structures 124A and 124B at the downstream end in the liquid supply flow direction, respectively. The configuration including the liquid supply flow path 20 and the specification detection means 122A corresponding to each of the injection-type auxiliary batteries 120A and 120B (however, the one corresponding to 120B is not shown) The third is different from the liquid injection system according to the form and.

  Although not shown, the liquid injection type auxiliary battery may have one electrode structure.

  Thereby, at the normal time, the main battery can operate the electric motor for driving the vehicle (not shown), and can inject all electrode structures in a short time when necessary. A plurality of liquid injection type auxiliary batteries having a plurality of electrode structures can be used for charging the main battery. And a main battery can be started when needed and the cruising range of a vehicle can be expanded. Further, as described above, when the remaining electric capacity of the main battery exceeds 80% or when the main battery is in operation, it may be determined that the main battery cannot be charged. Furthermore, since a required amount of liquid can be supplied to a plurality of liquid injection type auxiliary batteries, leakage due to oversupply can be prevented.

<Sixth form>
Next, a liquid injection system according to a sixth embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 10 is a schematic configuration diagram of a liquid injection system according to the sixth embodiment. As shown in FIG. 10, a liquid injection system 1E is applied to a battery system 100 including a plurality of liquid injection type auxiliary batteries 120A and 120B, and each liquid injection system 1E is disposed downstream of the liquid supply flow direction as a liquid supply flow path. The liquid supply passage 20 having downstream branch liquid supply passages 23A and 23B branched corresponding to the liquid auxiliary batteries 120A and 120B, and the valves 30C and 30D are respectively provided in the downstream branch liquid supply passages 23A and 23B. Based on the results detected by the specification detection means 122A and 122B, the control unit C functioning as the predetermined supply amount determination means C3, the predetermined mass flow meters 50A, 50B and 50C, and the predetermined supply amount determination means C4. The structure provided with the control unit C functioning as is different from the liquid injection system according to the third embodiment described above.

  Here, the predetermined supply amount determination means C3 determines a total predetermined liquid supply amount or a plurality of predetermined liquid supply amounts to be supplied to the liquid injection type auxiliary batteries 120A and 120B.

  The predetermined mass flow meters 50A, 50B, 50C are examples of supply amount measuring means for measuring the total supply amount of the liquid L supplied to the liquid injection type auxiliary batteries 120A, 120B, or liquid injection type auxiliary. This is an example of supply amount measuring means for measuring each supply amount of the liquid L supplied to the batteries 120A and 120B.

  Further, the predetermined supply amount determination means C4 is the supply amount determination means based on the total supply amount of the liquid L supplied to the injection type auxiliary batteries 120A and 120B measured by the supply amount measurement means 50A (or 50B and 50C). Each supply of the liquid L supplied to the liquid injection type auxiliary batteries 120A and 120B measured by the supply amount measuring means 50B and 50C is determined whether or not the total predetermined liquid supply amount determined by C3 has been reached. It is determined whether or not the amount has reached each predetermined liquid supply amount determined by the supply amount determination means C3.

  In the liquid injection system 1E, when the chargeability determination unit C2 determines that the main battery 110 can be charged by the liquid injection type auxiliary batteries 120A and 120B, the valve control unit C1 includes the storage container 10A. , 10B, the valves 30A, 30B, 30C, 30D are opened in order to start the supply of the liquid L from the injection type auxiliary batteries 120A, 120B.

  Further, in this liquid injection system 1E, the supply amount determination means C4 has (1-1) the total supply amount of the liquid L supplied to the liquid injection type auxiliary batteries 120A and 120B measured by the supply amount measurement means 50A. When it is determined that the total predetermined liquid supply amount has been reached, or (1-2) of each supply amount of the liquid L supplied to the injection type auxiliary batteries 120A, 120B measured by the supply amount measuring means 50B, 50C. When it is determined that all have reached the respective predetermined liquid supply amounts, the valve control means C1 stops the supply of the liquid L from the storage containers 10A, 10B to the liquid injection type auxiliary batteries 120A, 120B. , 30B, 30C, 30D are closed. Alternatively, in the liquid injection system 1E, the supply amount determination unit C4 (2) sets the supply amount of the liquid L supplied to the liquid injection type auxiliary batteries 120A and 120B measured by the supply amount measurement units 50B and 50C. When it is determined that at least one of the corresponding predetermined liquid supply amounts has reached at least one, the valve control means C1 moves to one of the liquid injection type auxiliary batteries 120A and 120B determined from the storage containers 10A and 10B. In order to stop the supply of the liquid L, one of the valves 30C and 30D corresponding to the liquid injection type auxiliary batteries 120A and 120B may be closed. In normal times, the valves 30A, 30B, 30C, and 30D are closed. Moreover, the control unit C starts the pump 40 as needed.

  Although not shown, the chargeability determination unit, the supply amount determination unit, and the supply amount determination unit may be configured separately if they can cooperate with the valve control unit.

  Thereby, at the normal time, the main battery can operate an electric motor for driving a vehicle (not shown), and when necessary, the liquid injection type auxiliary battery can be used for charging the main battery. Is possible. And a main battery can be started when needed and the cruising range of a vehicle can be expanded. Further, as described above, when the remaining electric capacity of the main battery exceeds 80% or when the main battery is in operation, it may be determined that the main battery cannot be charged. Furthermore, even when a plurality of liquid injection type auxiliary batteries are provided, the required amount of liquid can be supplied to the liquid injection type auxiliary battery, so that leakage due to oversupply can be more reliably prevented. .

<Seventh form>
Next, a liquid injection system according to a seventh embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 11 is a schematic configuration diagram of a liquid injection system according to the seventh embodiment. As shown in FIG. 11, the liquid injection system 1F can be used for charging the main battery 110, and the support stored in the storage container 12A that stores the support salt SE for preparing the electrolytic solution. A battery including a liquid injection type auxiliary battery 120 that is formed by supplying the electrolyte prepared by supplying the salt L to the liquid L stored in the storage container 10A that stores the liquid L for preparing the electrolyte. Applied to the system 100, a support salt addition channel 24 connecting the storage container 12A and the liquid supply channel 20, and a valve disposed at the downstream end of the support salt addition channel 24 in the support salt addition flow direction The configuration provided with 32B is different from the liquid injection system according to the first embodiment described above.

  In this liquid injection system 1F, the valve control means C1 opens the valves 30A and 30C to start the supply of the liquid L from the storage container 10A to the liquid injection type auxiliary battery 120, and the storage container In order to start the addition of the supporting salt SE from 12A to the liquid supply channel 20, the valve 32B is opened. In normal times, the valves 30A, 32B, and 30C are closed. Moreover, the control unit C starts the pump 40 as needed.

  Here, as the support salt addition flow path and the valve disposed therein, the same liquid supply flow path as described above or the valve disposed therein may be applied. You may use what is suitable for addition. Although not shown, the supporting salt addition channel may be configured to be connected to the storage container.

  Thereby, at the normal time, the main battery can operate an electric motor for driving a vehicle (not shown), and when necessary, the liquid injection type auxiliary battery can be used for charging the main battery. Is possible. And a main battery can be started when needed and the cruising range of a vehicle can be expanded. Further, since the supporting salt can be stored separately, a homogeneous electrolyte can be supplied as compared with the case where the electrolyte is prepared in the injection type auxiliary battery. Further, there is an advantage that the configuration of the liquid injection type auxiliary battery can be simplified.

<Eighth form>
Next, an injection system according to an eighth embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 12 is a schematic configuration diagram of a liquid injection system according to the eighth embodiment. As shown in FIG. 12, the injection system 1G can be used for charging the main battery 110, and the support stored in the storage container 12A that stores the support salt SE for preparing the electrolytic solution. A battery including a liquid injection type auxiliary battery 120 that is formed by supplying the electrolyte prepared by supplying the salt L to the liquid L stored in the storage container 10A that stores the liquid L for preparing the electrolyte. Applied to the system 100, a support salt addition channel 24 connecting the storage container 12A and the liquid supply channel 20, and a valve disposed at the downstream end of the support salt addition channel 24 in the support salt addition flow direction 32B, a control unit C functioning as an addition amount determination means C5 for determining a predetermined support salt addition amount to be supplied to the injection type auxiliary battery 120 based on a result detected by the specification detection means 122, and a support Whether or not the addition amount measuring means 12a for measuring the addition amount and the addition amount of the support salt measured by the addition amount measurement means 12a has reached the predetermined support salt addition amount determined by the addition amount determination means C5. The configuration including the control unit C functioning as the addition amount determination means C6 for determination is different from the liquid injection system according to the third embodiment described above.

  In the liquid injection system 1G, when the chargeability determination means C2 determines that the main battery 110 can be charged by the liquid injection type auxiliary battery 120, the valve control means C1 is injected from the storage container 10A. The valves 30A and 30C are opened to start the supply of the liquid L to the liquid auxiliary battery 120, and the valve 32B is used to start the addition of the supporting salt SE from the storage container 12A to the liquid supply flow path 20. When the addition amount determination means C6 determines that the addition amount of the support salt SE measured by the addition amount measurement means 12a has reached the predetermined support salt addition amount, the valve control means C1 In order to stop the addition of the supporting salt SE from 12A to the liquid supply channel 20, the valve 32B is closed, and the supply amount determination means C4 is measured by the mass flow meter 50 which is an example of the supply amount measurement means. When it is determined that the supply amount of the liquid L has reached the predetermined liquid supply amount, the valve control means C1 uses the valves 30A, 30A to stop the supply of the liquid L from the storage container 10A to the liquid injection type auxiliary battery 120. 30C is closed. In normal times, the valves 30A, 32B, and 30C are closed. Moreover, the control unit C starts the pump 40 as needed.

  Here, the addition amount determination means determines a predetermined support salt addition amount to be supplied to the injection type auxiliary battery based on the result detected by the specification detection means. That is, an arithmetic processing device that stores map data indicating the relationship between the detection target data of the sensor and the predetermined support salt addition amount can be used as appropriate.

  The addition amount measuring means can measure the addition amount of the supporting salt from the storage container to the injection type auxiliary battery, and as shown in the figure, a weighing scale for measuring the change in the weight of the storage container is used. Although it is applicable, it is not limited to this. For example, although not shown, a conventionally known mass flow meter may be disposed in the support salt addition flow path.

  Furthermore, the addition amount judgment means judges whether or not the addition amount of the support salt measured by the addition amount measurement means has reached a predetermined support salt addition amount determined by the addition amount determination means. That is, it is possible to appropriately use an arithmetic processing device that takes in and calculates the addition amount data sent from the addition amount measuring means and the predetermined support salt addition amount sent from the addition amount determining means.

  Although not shown in the drawings, the chargeability determination means, the supply amount determination means, the supply amount determination means, the addition amount determination means and the addition amount determination means can be configured separately if they can cooperate with the valve control means. Good.

  Thereby, at the normal time, the main battery can operate an electric motor for driving a vehicle (not shown), and when necessary, the liquid injection type auxiliary battery can be used for charging the main battery. Is possible. And a main battery can be started when needed and the cruising range of a vehicle can be expanded. Further, as described above, when the remaining electric capacity of the main battery exceeds 80% or when the main battery is in operation, it may be determined that the main battery cannot be charged. Furthermore, as described above, since a necessary amount of liquid can be supplied to the injection-type auxiliary battery, leakage due to oversupply can be prevented. Further, as described above, since the supporting salt can be stored separately, it is possible to supply a homogeneous electrolytic solution as compared with the case where the electrolytic solution is prepared in the liquid injection type auxiliary battery. Furthermore, as described above, there is also an advantage that the configuration of the liquid injection type auxiliary battery can be simplified.

<Ninth Embodiment>
Next, a liquid injection system according to a ninth embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 13 is a schematic configuration diagram of a liquid injection system according to the ninth embodiment. As shown in FIG. 13, the liquid injection system 1H includes a remaining electric capacity detection unit 112 that detects the remaining electric capacity of the main battery 110, a specification detection unit 122 that detects the specification of the liquid injection type auxiliary battery 120, and a specification detection. Based on the result detected by the means 122, the control unit C functioning as the supply amount determining means C3 for determining the predetermined liquid supply amount to be supplied to the injection type auxiliary battery 120, and the liquid storage amounts of the storage containers 10A and 10B. Storage amount measuring unit 10a, 10b to measure and storage amount for determining whether the storage amount of the liquid L measured by the storage amount measuring unit 10a, 10b reaches a predetermined liquid supply amount determined by the supply amount determining unit The control C functioning as the judging means C7, the result judged by the storage amount judging means C7 and the result detected by the remaining electric capacity detecting means 112. Based on the control unit C functioning as chargeability determination means C2 for determining whether or not the main battery 110 can be charged, and the operation availability information of the liquid injection type auxiliary battery 120 based on the result determined by the chargeability determination means C2. The configuration including the information display means 200 for displaying is different from the liquid injection system according to the first embodiment described above.

In the liquid injection system 1H, when the chargeability determination unit C2 determines that the main battery 110 can be charged by the liquid injection type auxiliary battery 120, the valve control unit C1 stores the storage containers 10A and 10B. In order to start the supply of the liquid L to the liquid injection type auxiliary battery 120, the valves 30A, 30B, 30C are opened, and the charge availability determination means C2 can charge the main battery 110 by the liquid injection type auxiliary battery 120. The valve control means C1 closes the valves 30A, 30B, 30C in order not to start the supply of the liquid L from the storage containers 10A, 10B to the liquid injection type auxiliary battery 120, and the information The display means 200 displays operation availability information. In normal times, the valves 30A, 30B, and 30C are closed. Moreover, the control unit C starts the pump 40 as needed.

  Here, the storage amount measuring means is capable of measuring the amount of liquid stored in the storage container. As shown in the figure, a storage meter or sensor for measuring the change in the weight of the storage container or the change in the liquid level is used. Although it is applicable, it is not limited to this. For example, although not shown, a conventionally known mass flow meter may be disposed in the support salt addition flow path.

  The storage amount determination means determines whether the liquid storage amount measured by the storage amount measurement means reaches a predetermined liquid supply amount determined by the supply amount determination means.

  Although not shown, the chargeability determination unit, the supply amount determination unit, the supply amount determination unit, and the storage amount determination unit may be configured separately if they can cooperate with the valve control unit.

  Thereby, at the normal time, the main battery can operate the drive motor of the vehicle (not shown). The liquid injection type auxiliary battery can be used for charging the main battery. Therefore, the main battery can be activated when necessary, and the cruising range of the vehicle can be increased. Further, even when necessary, if the amount of liquid stored in the storage container is less than the predetermined liquid supply amount, the operation of the liquid injection type auxiliary battery can be stopped. Charging of the main battery in a stable operating state can be avoided.

<Tenth embodiment>
Next, a liquid injection system according to a tenth embodiment will be described in detail with reference to the drawings. In addition, about the thing equivalent to what was demonstrated in said form, the code | symbol same as them is attached | subjected and description is abbreviate | omitted. In addition, a configuration example described without being illustrated may be applied as it is or appropriately modified as long as it is applicable to the present embodiment, and the description thereof is omitted. FIG. 14 is a schematic configuration diagram of an injection system according to the tenth embodiment. As shown in FIG. 14, the liquid injection system 1I includes a storage amount measuring unit 10a, 10b that measures the liquid storage amount of the storage containers 10A, 10B, and a storage amount of the liquid L that is measured by the storage amount measuring units 10a, 10b. Is provided with the control C functioning as the storage amount determination means C7 for determining whether or not the predetermined liquid supply amount determined by the supply amount determination means has reached the liquid injection system according to the sixth embodiment described above. It is different.

  In this liquid injection system 1I, when the chargeability determination means C2 determines that the main battery 110 can be charged by a liquid injection type auxiliary battery (for example, 120A), the valve control means C1 The corresponding valves 30A, 30B, 30C are opened in order to start the supply of the liquid L from the storage containers 10A, 10B to the corresponding liquid injection type auxiliary battery 120A, and the operation availability display means 200 has another note. Information indicating whether or not the liquid auxiliary battery 120B can be operated (in this case, the operation is impossible) is displayed, and the supply amount determining means C4 is supplied to the liquid injection type auxiliary battery 120A measured by the supply amount measuring means. When it is determined that the supply amount of the liquid L has reached the corresponding predetermined liquid supply amount, the valve control means C1 supplies the liquid L to the injection type auxiliary battery 120A determined from the storage containers 10A and 10B. Corresponding valves 30A to poured-type auxiliary battery 120A to stop the feed, 30B, and 30C to the closed state. In normal times, the valves 30A, 32B, 30C, and 30D are closed. Moreover, the control unit C starts the pump 40 as needed.

  Needless to say, there may be a plurality of liquid injection type auxiliary batteries that can be determined to be capable of charging the main battery.

  Although not shown, the chargeability determination unit, the supply amount determination unit, the supply amount determination unit, and the storage amount determination unit may be configured separately if they can cooperate with the valve control unit.

  Thereby, at the normal time, the main battery can operate the drive motor of the vehicle (not shown). The liquid injection type auxiliary battery can be used for charging the main battery. Therefore, the main battery can be activated when necessary, and the cruising range of the vehicle can be increased. Furthermore, even when necessary, if the amount of liquid stored in the storage container is less than the predetermined liquid supply amount, the operation of some of the liquid injection type auxiliary batteries can be stopped. Charging of the main battery in an unstable operation state of the liquid type auxiliary battery can be avoided.

  Here, an example of the flow of availability of the injection type auxiliary battery will be described with reference to the drawings. FIG. 15 is a flowchart for explaining an example of the flow of availability of the injection-type auxiliary battery.

  As shown in FIG. 15, when the driver gives an instruction to start power generation (discharge) of the liquid injection type auxiliary battery, the flow is started.

  In step 1 (denoted as “S1” in the figure, the same applies hereinafter), the battery specification is confirmed (capacity and number). Since the liquid supply amount depends on the amount of negative electrode metal, the predetermined liquid supply amount determined from the electric capacity is indicated in the battery specification display. In addition, since the amount of liquid supply may vary depending on the type of metal or the type of electrolyte, a specific instruction for the supply amount is given in consideration of this. This is performed for all the batteries mounted on the vehicle, and the process proceeds to S2.

  In S2, it is determined whether or not the liquid storage amount reaches a predetermined liquid supply amount of all the batteries mounted on the vehicle. If not, the process proceeds to S3. On the other hand, when it reaches, it progresses to S4.

  In S3, the combination of (1) the number of injection-type auxiliary batteries that can be operated and (2) specifications is determined, and the process proceeds to S4.

  In S4, (1) specifications and number of on-board batteries, (2) information such as liquid storage amount, (3) information on liquid injection type auxiliary batteries that can be operated (number of liquid injection type auxiliary batteries, individual specifications Information on whether one of the high capacity or two of the low capacity can be operated, etc. is provided to the driver, and the flow is terminated.

  As mentioned above, although this invention was demonstrated with some forms, this invention is not limited to these, A various deformation | transformation is possible within the range of the summary of this invention.

  For example, the configuration described in each embodiment described above is not limited to each embodiment. For example, a storage container, a storage container, a liquid supply channel, a support salt addition channel, a valve, a liquid injection type auxiliary battery, etc. The configuration can be changed, or the configuration of each mode can be changed to a combination other than each mode described above.

  Moreover, in the said form, although the lithium ion secondary battery was illustrated as a suitable example of a main battery, it is not limited to this, Conventionally well-known secondary batteries, such as another alkaline secondary battery and a metal air secondary battery, are not limited to this. The present invention can also be applied to secondary batteries.

  Furthermore, in the said form, although the air battery was illustrated as a suitable example of a liquid injection type auxiliary battery, it is not limited to this, It can apply also to a conventionally well-known liquid injection type battery.

DESCRIPTION OF SYMBOLS 1 Injection system 10A, 10B Storage container 20 Liquid supply flow path 21 Upstream branch liquid supply flow path 30A, 30B, 30C Valve 40 Pump 100 Battery system 110 Main battery 120 Injection liquid type auxiliary battery 130 Electric motor 132 for drive Power converter C (C1) Controller (valve control means)
L Liquid a, b Electric circuit

Claims (16)

A main battery that can be charged and discharged and that can operate a motor for driving a vehicle, and can be used for charging the main battery, and for preparing an electrolyte. A battery comprising: one or a plurality of liquid injection type auxiliary batteries that are formed by supplying the liquid stored in at least one storage container that stores the liquid, and that have one or a plurality of electrode structures. Applied to the system,
A liquid supply flow path connecting the storage container and the liquid injection type auxiliary battery;
One or more valves disposed in the liquid supply flow path;
Valve control means for controlling the valve;
Residual electric capacity detection means for detecting the residual electric capacity of the main battery;
Based on the result detected by the remaining electric capacity detection means, chargeability determination means for determining whether the main battery can be charged;
One or more specification detection means for detecting the specifications of the injection type auxiliary battery;
A supply amount determining means for determining a predetermined liquid supply amount to be supplied to the liquid injection type auxiliary battery based on a result detected by the specification detecting means;
One or a plurality of supply amount measuring means for measuring the supply amount of the liquid;
A supply amount determination means for determining whether or not the supply amount of the liquid measured by the supply amount measurement means has reached a predetermined liquid supply amount determined by the supply amount determination means;
With
When the chargeability determination unit determines that the main battery can be charged by the liquid injection type auxiliary battery, the valve control unit is configured to transfer the liquid from the storage container to the liquid injection type auxiliary battery. Open the valve to start feeding,
When the supply amount determining means determines that the liquid supply amount measured by the supply amount measuring means has reached the predetermined liquid supply amount, the valve control means is configured to remove the liquid injection mold from the storage container. pouring system that is characterized in that the closed state of the valve to stop the supply of the liquid to the auxiliary battery. A main battery that can be charged and discharged and that can operate a motor for driving a vehicle, and can be used for charging the main battery, and for preparing an electrolyte. A battery system comprising: a plurality of injection-type auxiliary batteries that are formed by supplying the liquid stored in at least one storage container that stores the liquid, and that have one or a plurality of electrode structures. Applied,
A liquid supply that connects the storage container and the liquid injection type auxiliary battery, and has a downstream branch liquid supply channel branched in correspondence with each liquid injection type auxiliary battery on the downstream side in the liquid supply flow direction. A flow path;
One or more valves disposed in the liquid supply flow path;
Valve control means for controlling the valve;
Residual electric capacity detection means for detecting the residual electric capacity of the main battery;
Based on the result detected by the remaining electric capacity detection means, chargeability determination means for determining whether the main battery can be charged;
A plurality of specification detecting means for detecting the specifications of the injection type auxiliary battery;
A supply amount determining means for determining a total predetermined liquid supply amount or a plurality of predetermined liquid supply amounts to be supplied to the injection type auxiliary battery based on a result detected by the specification detection means;
One or a plurality of supply amount measuring means for measuring the total supply amount of liquid supplied to the liquid injection type auxiliary battery, or a plurality of supply amounts for measuring each supply amount of liquid supplied to the liquid injection type auxiliary battery Measuring means;
It is determined whether or not the total supply amount of the liquid supplied to the injection type auxiliary battery measured by the supply amount measuring means has reached the total predetermined liquid supply amount determined by the supply amount determination means. Each supply amount of the liquid supplied to the injection type auxiliary battery measured by the supply amount determination means or the supply amount measurement means has reached each predetermined liquid supply amount determined by the supply amount determination means. Supply amount judgment means for judging whether or not,
With
When the chargeability determination unit determines that the main battery can be charged by the liquid injection type auxiliary battery, the valve control unit is configured to transfer the liquid from the storage container to the liquid injection type auxiliary battery. Open the valve to start feeding,
When the supply amount determining means determines that the total supply amount of the liquid supplied to the injection type auxiliary battery measured by the supply amount measuring means has reached the total predetermined liquid supply amount, or When it is determined that all of the supply amounts of the liquid supplied to the liquid injection type auxiliary battery measured by the supply amount measuring means have reached the predetermined liquid supply amounts, the valve control means The liquid that is supplied to the liquid injection type auxiliary battery that is closed by the valve to stop the supply of the liquid from the storage container to the liquid injection type auxiliary battery or that is measured by the supply amount measuring means When the valve control means determines that at least one of the respective supply amounts has reached at least one of the corresponding predetermined liquid supply amounts, the valve control means supplies the liquid injection type auxiliary battery determined from the storage container. Stop supplying the liquid Pouring system that is characterized in that the valve corresponding to the infusion solution form the auxiliary battery to the closed state. A main battery that can be charged and discharged and that can operate a motor for driving a vehicle, and can be used for charging the main battery, and for preparing an electrolyte. An electrolytic solution prepared by supplying the supporting salt stored in at least one storage container for storing the supporting salt to the liquid stored in at least one storage container for storing the liquid for preparing the electrolytic solution And a single or a plurality of liquid injection type auxiliary batteries having one or a plurality of electrode structures, and applied to a battery system,
A liquid supply flow path connecting the storage container and the liquid injection type auxiliary battery;
A supporting salt addition flow path connecting the storage container and at least one of the storage container and the liquid supply flow path;
One or more valves disposed in the liquid supply flow path;
One or more valves disposed at the downstream end of the support salt addition flow path in the support salt addition flow direction;
Valve control means for controlling the valve;
With
The valve control means opens the valve to start the supply of the liquid from the storage container to the liquid-injecting auxiliary battery, and from the storage container to the storage container and the liquid supply flow path. pouring system that is characterized in that the valve in the open state in order to start the addition of the supporting salt to at least one. The liquid injection system includes a remaining electric capacity detecting means for detecting the remaining electric capacity of the main battery,
Based on the result detected by the remaining electric capacity detection means, chargeability determination means for determining whether the main battery can be charged;
One or more specification detection means for detecting the specifications of the injection type auxiliary battery;
A supply amount determining means for determining a predetermined liquid supply amount to be supplied to the liquid injection type auxiliary battery based on a result detected by the specification detecting means;
Based on the result detected by the specification detection means, an addition amount determination means for determining a predetermined support salt addition amount to be supplied to the injection type auxiliary battery,
One or a plurality of supply amount measuring means for measuring the supply amount of the liquid;
One or more addition amount measuring means for measuring the addition amount of the supporting salt;
It is measured by a supply amount determination means for determining whether or not the supply amount of the liquid measured by the supply amount measurement means has reached a predetermined liquid supply amount determined by the supply amount determination means, and by the addition amount measurement means. Addition amount judgment means for judging whether or not the addition amount of the support salt has reached a predetermined support salt addition amount determined by the addition amount determination means;
Further comprising
When the chargeability determination unit determines that the main battery can be charged by the liquid injection type auxiliary battery , the valve control unit is configured to transfer the liquid from the storage container to the liquid injection type auxiliary battery. Opening the valve to start supply, opening the valve to start adding the supporting salt from the storage container to at least one of the storage container and the liquid supply flow path,
When the addition amount determination means determines that the addition amount of the support salt measured by the addition amount measurement means has reached the predetermined support salt addition amount, the valve control means is configured to store the storage salt from the storage container. Closing the valve to stop the addition of the supporting salt to at least one of the container and the liquid supply channel;
When the supply amount determining means determines that the liquid supply amount measured by the supply amount measuring means has reached the predetermined liquid supply amount, the valve control means is configured to remove the liquid injection mold from the storage container. The liquid injection system according to claim 3 , wherein the valve is closed in order to stop the supply of the liquid to the auxiliary battery. A main battery that can be charged and discharged and that can operate a motor for driving a vehicle, and can be used for charging the main battery, and for preparing an electrolyte. A battery comprising: one or a plurality of liquid injection type auxiliary batteries that are formed by supplying the liquid stored in at least one storage container that stores the liquid, and that have one or a plurality of electrode structures. Applied to the system,
A liquid supply flow path connecting the storage container and the liquid injection type auxiliary battery;
One or more valves disposed in the liquid supply flow path;
Valve control means for controlling the valve;
One or more specification detection means for detecting the specifications of the injection type auxiliary battery;
A supply amount determining means for determining a predetermined liquid supply amount to be supplied to the liquid injection type auxiliary battery based on a result detected by the specification detecting means;
A storage amount measuring means for measuring a liquid storage amount of the storage container;
A storage amount determination means for determining whether or not the liquid storage amount measured by the storage amount measurement means reaches a predetermined liquid supply amount determined by the supply amount determination means;
Residual electric capacity detection means for detecting the residual electric capacity of the main battery;
Chargeability determination means for determining whether or not the main battery can be charged based on the result determined by the storage amount determination means and the result detected by the remaining electric capacity detection means;
Information display means for displaying operation availability information of the injection-type auxiliary battery based on the result determined by the charge availability determination means;
With
When the chargeability determination unit determines that the main battery can be charged by the liquid injection type auxiliary battery, the valve control unit is configured to transfer the liquid from the storage container to the liquid injection type auxiliary battery. Open the valve to start feeding,
When the chargeability determination unit determines that the main battery cannot be charged by the liquid injection type auxiliary battery, the valve control unit supplies the liquid from the storage container to the liquid injection type auxiliary battery. The liquid injection system is characterized in that the valve is closed so as not to start the operation, and the information display means displays operation availability information. The battery system includes a plurality of the injection type auxiliary batteries,
The liquid supply flow path has a downstream branch liquid supply flow path branched in correspondence with each of the injection type auxiliary batteries on the downstream side in the liquid supply flow direction,
The liquid injection system includes a plurality of the specification detection means,
The supply amount determining means determines a total predetermined liquid supply amount or a plurality of predetermined liquid supply amounts to be supplied to the liquid injection type auxiliary battery based on a result detected by the specification detection means,
Whether the storage amount determination means reaches the total predetermined liquid supply amount or each of the plurality of predetermined liquid supply amounts determined by the supply amount determination means, as determined by the supply amount determination means. To judge,
The liquid injection system includes one or a plurality of supply amount measuring means for measuring the total supply amount of liquid supplied to the liquid injection type auxiliary battery, or each supply amount of liquid supplied to the liquid injection type auxiliary battery. A plurality of supply measuring means for measuring;
It is determined whether or not the total supply amount of the liquid supplied to the injection type auxiliary battery measured by the supply amount measuring means has reached the total predetermined liquid supply amount determined by the supply amount determination means. Each supply amount of the liquid supplied to the injection type auxiliary battery measured by the supply amount determination means or the supply amount measurement means has reached each predetermined liquid supply amount determined by the supply amount determination means. Supply amount judgment means for judging whether or not,
Further comprising
When the chargeability determination means determines that the main battery can be charged by the one liquid injection type auxiliary battery, the valve control means moves from the storage container to the corresponding liquid injection type auxiliary battery. The corresponding valve is opened to start the supply of the liquid, and the information display means displays availability information of the other injection type auxiliary battery, and the supply amount determination means When the total supply amount of the liquid supplied to the liquid injection type auxiliary battery measured by the supply amount measuring unit has reached the total predetermined liquid supply amount, or measured by the supply amount measuring unit When it is determined that all of the supply amounts of the liquid supplied to the liquid injection type auxiliary battery have reached the predetermined liquid supply amounts, the valve control means transfers the liquid injection from the storage container. Supply of the liquid to the auxiliary battery In order to stop, the valve is closed, or at least one of the supply amounts of the liquid supplied to the liquid injection type auxiliary battery measured by the supply amount measuring means corresponds to each of the predetermined liquid supplies. When it is determined that at least one of the quantities has been reached, the valve control means causes the liquid injection type auxiliary battery to stop supplying the liquid to the liquid injection type auxiliary battery determined from the storage container. 6. The liquid injection system according to claim 5, wherein the corresponding valve is closed. A main battery that can be charged and discharged and that can operate a motor for driving a vehicle, and can be used for charging the main battery, and for preparing an electrolyte. A battery comprising: one or a plurality of liquid injection type auxiliary batteries that are formed by supplying the liquid stored in at least one storage container that stores the liquid, and that have one or a plurality of electrode structures. Applied to the system,
A liquid supply flow path connecting the storage container and the liquid injection type auxiliary battery;
One or more valves disposed in the liquid supply flow path;
Valve control means for controlling the valve;
With
The storage container is, have at least one heating device arranged in the vicinity of the heating device and the accumulating container disposed adjacent to the accumulating container,
Pouring system above valve control means, characterized <br/> to the valve open state in order to start the supply of the liquid to said liquid injection type auxiliary battery from the storage container. A main battery that can be charged and discharged and that can operate a motor for driving a vehicle, and can be used for charging the main battery, and for preparing an electrolyte. A battery comprising: one or a plurality of liquid injection type auxiliary batteries that are formed by supplying the liquid stored in at least one storage container that stores the liquid, and that have one or a plurality of electrode structures. Applied to the system,
A liquid supply flow path connecting the storage container and the liquid injection type auxiliary battery;
One or more valves disposed in the liquid supply flow path;
Valve control means for controlling the valve;
With
The valve control means opens the valve in order to start supplying the liquid from the storage container to the liquid injection type auxiliary battery.
An injection system,
The liquid supply system has at least one of a heating device disposed adjacent to the liquid supply channel and a heating device disposed in the vicinity of the liquid supply channel as the liquid supply channel. pouring system that is characterized by comprising a flow path. The note according to claim 7 or 8 , wherein at least one selected from the group consisting of the driving motor, a power converter for the driving motor, and the main battery is used as the heating device. Liquid system. The said storage container has at least one of the heating apparatus arrange | positioned adjacent to this storage container, and the heating apparatus arrange | positioned in the vicinity of this storage container, The any one of Claims 1-6 characterized by the above-mentioned. Infusion system according to one of the sections. The liquid supply system has at least one of a heating device disposed adjacent to the liquid supply channel and a heating device disposed in the vicinity of the liquid supply channel as the liquid supply channel. The liquid injection system according to any one of claims 1 to 6, further comprising a flow path. 12. The note according to claim 10 or 11, wherein at least one selected from the group consisting of the driving motor, a power converter for the driving motor, and the main battery is used as the heating device. Liquid system. The battery system includes a plurality of liquid injection type auxiliary batteries having one or a plurality of electrode structures as the liquid injection type auxiliary battery,
The liquid injection system includes, as the liquid supply flow path, a liquid supply flow path having a downstream branch liquid supply flow path branched in correspondence with each liquid injection type auxiliary battery on the downstream side in the liquid supply flow direction. ing
The liquid injection system according to any one of claims 1, 3 to 5, and 7 to 9. The battery system comprises one or more liquid injection type auxiliary batteries having a plurality of electrode structures as the liquid injection type auxiliary battery,
The liquid having the supply amount adjusting structure channel for adjusting the supply amount of the liquid supplied to each electrode structure at the downstream end in the liquid supply flow direction as the liquid supply channel. Has a supply channel
The liquid injection system according to any one of claims 1 to 9, wherein The liquid injection system according to any one of claims 1 to 14, wherein the storage container has a liquid quick supply means. The liquid injection system according to any one of claims 1 to 15, wherein the liquid injection system includes a liquid supply flow path having a liquid quick supply means as the liquid supply flow path.

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