The present disclosure is related to battery systems have adjustable energy storage capabilities. More particularly, a liquid temperature regulated battery pack configured to receive additional modular battery packs is disclosed herein.
Large lithium ion battery packs require that the individual battery cells within them be regulated in temperature during operation. Such battery packs may employ a cooling system having air cooled heat sinks (passive airflow or fan assisted). Other cooling systems use liquid cooling where the batteries are immersed in a liquid coolant and is circulated around the batteries. The liquid can also be heated to warm the batteries.
The devices, systems, and methods disclosed herein have several features, no single one of which is solely responsible for its desirable attributes. Without limiting the scope as expressed by the claims that follow, its more prominent features will now be discussed briefly. After considering this discussion, and particularly after reading the section entitled “Detailed Description of the Preferred Embodiments” one will understand how the features of the system and methods provide several advantages over traditional systems and methods.
In one embodiment, a modular low voltage battery pack for a vehicle is described. The battery pack includes a tray configured to receive a plurality of battery housings, a liquid path spaced away from the bottom surface and above the battery housings when the housings are inserted into the tray, and a circuit configured to provide a voltage difference between the tray and a positive terminal. The tray has a bottom surface for supporting the plurality of battery housings from below. The liquid path has an inlet flow path with a plurality of outlets coupleable to an inlet in at least one flow path in the plurality of battery housings and an outlet flow path with a plurality of inlets coupleable to an outlet in the at least one flow path in the plurality of battery housings.
The tray may include a plurality of receiving spaces separated by upwardly extending walls, each receiving space configured to receive one or more battery housings. The liquid path may include a substantially straight conduit extending from the inlet flow path and terminating at a distalmost outlet coupleable to a distalmost inlet in at least one flow path in the plurality of battery housings. The liquid path may include a substantially straight conduit extending from the proximalmost inlet flow path and terminating at a proximalmost outlet coupleable to a proximalmost outlet in at least one flow path in the plurality of battery housings. The circuit may include a parallel bus bar configured to electrically connect at least two terminals on the top side of each of the battery housings.
The battery pack may further include the plurality of battery housings disposed within the tray. Each battery housing of the plurality of battery housings may include a common flow channel in thermal contact with non-electrically conductive portions of two sets of electrochemical cells. The common flow channel may extend in a direction that is normal to the bottom surface of the tray. The electrochemical cells may be cylindrical battery cells that are oriented normal to the flow channels within each battery housing. The electrochemical cells in each housing may be connected by two circuits on opposite sides of the flow channel, the circuits being positioned parallel to the flow channel.
In another embodiment, a method of adding a battery module to a modular low voltage battery pack of a vehicle is described. The method includes disconnecting a bus bar from a terminal post of a first battery module secured within a tray of the battery pack, uncoupling a coolant conduit from a coolant inlet of the first battery module, placing a second battery module into the tray, electrically connecting the bus bar to the terminal post of the first battery module and a terminal post of the second battery module, and coupling the coolant conduit to the coolant inlet of the first battery module and a coolant inlet of the second battery module. Adding the second battery module to the battery pack increases the energy storage capacity of the battery pack.
The first battery module and the second battery module may be electrically connected in parallel. Adding the second battery module to the battery pack may not increase the maximum open circuit voltage of the battery pack. The method may further include placing a third battery module into the tray, securing the third battery module to the tray, electrically connecting the bus bar to the terminal post of the third battery module, and coupling the coolant conduit to the coolant inlet of the third battery module.
In another embodiment, a modular low voltage battery pack for a vehicle is described. The battery pack includes at least one battery module having a positive terminal post, a coolant inlet, and a coolant outlet, circuitry configured to electrically connect the positive terminal post to a low voltage vehicle load, a cooling system configured to supply coolant to the at least one battery module at the coolant inlet and receive coolant from the at least one battery module at the coolant outlet, and a tray secured to and at least partially surrounding the at least one battery module. The cooling system comprises at least one conduit. The tray is configured to receive at least one additional battery module to increase the energy storage capacity of the battery pack.
The circuitry may include a conductive metallic bus bar configured to be removably electrically connected to one or more positive terminal posts. The bus bar may include a plurality of apertures, each aperture sized and shaped to receive the positive terminal post of a battery module. Each battery module may further include a negative terminal post, at least a portion of the tray may include an electrically conductive metal, and the negative terminal post of each of the plurality of battery modules may be electrically connected to the electrically conductive metal. The cooling system may be configured to supply coolant to the at least one additional battery module at a coolant inlet and receive coolant from the at least one additional battery module at a coolant outlet.
The cooling system may include a coolant supply conduit having a plurality of fluid supply connectors and a coolant return having a plurality of fluid return connectors. Each fluid supply connector may be configured to be removably connected to a coolant inlet. Each fluid return connector may be configured to be removably connected to a coolant outlet. Each fluid supply connector may be configured to prevent coolant from flowing out of the coolant supply conduit while not connected to a coolant inlet. Each fluid return connector may be configured to prevent coolant from flowing out of the coolant return conduit while not connected to a coolant outlet.
The following is a brief description of each of the drawings. From figure to figure, the same reference numerals have been used to designate the same components of an illustrated embodiment. The drawings disclose illustrative embodiments and particularly illustrative implementations in the context of connecting a plurality of electrochemical cells. They do not set forth all embodiments. Other embodiments may be used in addition to or instead. Conversely, some embodiments may be practiced without all of the details that are disclosed. It is to be noted that the Figures may not be drawn to any particular proportion or scale.
Disclosed herein is battery pack having at least one cooling channel disposed therein. The cooling channel may be formed by two cooling plates that are spaced apart by a gap. The cooling plate may form a wall of an enclosure. The remaining walls of the enclosure may be formed of material that is not as thermally conductive as the cooling plate. For example, the cooling plate may include aluminum and the remaining portions of the enclosure may include a plastic. The enclosure may house a plurality of electrochemical cells, such as, for example, lithium ion battery cells. Other types of electrochemical cells are also contemplated. Liquid coolant may be circulated through the channel. Thus, the channel may have an inlet and an outlet and the liquid coolant may flow from the inlet to outlet. In some aspects the channel includes a flow divider. The fluid may be configured to flow in a U-shape-like path from the inlet to the outlet.
Typical electric vehicles almost exclusively draw their power from one high capacity, high voltage battery system. The high capacity, high voltage battery system is used to power the motors that propel the vehicle and is stepped down with one or more DC-DC converters to power other electrically powered systems. When the high capacity, high voltage battery system is not engaged, for example, when the vehicle is parked, a lower capacity, lower voltage battery may be relied upon. This second battery may function as a typical automobile battery and may be used to start the vehicle and power other components such as, for example, the windows, door locks, and stereo when the high capacity, high voltage battery is disengaged. The second battery is typically recharged by the high capacity, high voltage battery when the vehicle is driving and/or when the high voltage battery system is engaged.
The high voltage battery system may be configured to power the vehicle components that require relatively high voltages. For example, the high voltage battery system may be configured to power one or more electric motors that are used to propel the vehicle. The low voltage battery system may be configured to power the vehicle components that require relatively lower voltages in comparison to the high voltage battery system. For example, the low voltage battery system may be configured to power the cabin HVAC system(s), the windows, the locks, the doors, the audio and entertainment systems, infotainment systems, wireless modems and routers, touch screens, displays, navigation systems, automated driving systems, and the like. Low voltage systems or components may generally refer to systems or components that require less voltage than the motors that propel the vehicle.
A vehicle with at least two separate high capacity energy storage systems can have several advantages. For one, the low voltage system can power vehicle systems for long periods of time without engaging the high voltage battery system. Energy is lost when electric power is moved between battery systems. For example, DC-DC converters are not perfectly efficient and energy is lost when a DC-DC converter is operated. Thus, if the low voltage system has sufficient storage capabilities, it can be used to power systems other than the propulsion motors for longer periods of time and the need for recharging the low voltage system and/or the need to draw power from the high voltage system, may be reduced or eliminated.
A relatively high capacity, low voltage battery may require a heating and/or cooling system. At very low temperatures, the electrochemical cells in the high capacity, low voltage battery pack may not be capable of powering the required loads. High temperatures may cause battery failure and/or fire.
The following description is directed to certain implementations for the purpose of describing the innovative aspects of this disclosure. However, a person having ordinary skill in the art will readily recognize that the teachings herein can be applied in a multitude of different ways.
As used herein, the term “electric vehicle” can refer to any vehicle that is partly or entirely operated based on stored electric power, such as a pure electric vehicle, plug-in hybrid electric vehicle, or the like. Such vehicles can include, for example, road vehicles (cars, trucks, motorcycles, buses, etc.), rail vehicles, wheeled robots, or the like.
In some implementations, the word “battery” or “batteries” will be used to describe certain elements of the embodiments described herein. It is noted that “battery” does not necessarily refer to only a single battery cell. Rather, any element described as a “battery” or illustrated in the Figures as a single battery in a circuit may equally be made up of any larger number of individual battery cells and/or other elements without departing from the spirit or scope of the disclosed systems and methods.
Reference may be made throughout the specification to a “12 volt” power systems or sources. It will be readily apparent to a person having ordinary skill in the art that the phrase “12 volt” in the context of automotive electrical systems is an approximate value referring to nominal 12 volt power systems. The actual voltage of a “12 volt” system in a vehicle may fluctuate as low as roughly 4-5 volts and as high as 16-17 volts depending on engine conditions and power usage by various vehicle systems. Such a power system may also be referred to as “low voltage” battery systems. Some vehicles may use two or more 12 volt batteries to provide higher voltages. Thus, it will be clear that the systems and methods described herein may be utilized with low voltage battery arrangements in at least the range of 4-34 volts without departing from the spirit or scope of the systems and methods disclosed herein.
The present disclosure may be implemented to achieve one or more advantages other traditional battery cooling systems. In some aspects, the amount of coolant that is required is minimized. For example, by utilizing the disclosed geometry, the channel can allow the liquid to cool two physically separated sets of battery cells at the same time.
In certain aspects, the present system may be less expensive to manufacture than previous systems. For example, certain aspects achieve the desired heat conduction properties while primarily relying on components made of low cost plastics. Manufacturing time may also be reduced and/or simplified. For example, two halves of the housing may be substantially similar and include only one conductive surface each. These two halves may be joined in one step to form a cooling channel in between the two halves.
Such enclosures can also be configured as modular battery packs having the desired electrical characteristics. The modular packs may be added and/or removed as needed. For example, if a user desires extra battery lifetime, additional packs may be easily added to the system. In some aspects, the modular packs may be connected to a cooling system that is also used to cool/heat the higher voltage batteries that are used to power the vehicles propulsion motors and/or drivetrain. Thus, additional pumps, fans, heat exchangers, and the like may not be required. In some aspects, the inlet and the outlet for coolant are located on the same side of the housing such that connection to coolant lines is simplified. In some implementations, the outlet is located at a high point such that air bubbles may be more readily expelled from the coolant path.
The one or more high voltage loads 140 may include an electric motor 140a. The electric motor 140a may be configured to propel the vehicle 100. The electric motor 140a may be an interior permanent magnet motor. One or more inverters may also be provided. It should be appreciated that while the motor 140a is an electrical machine that can receive electrical power to produce mechanical power, it can also be used such that it receives mechanical power which it converts to electrical power. Additional loads 140b-n may also be electrically connected to the first battery system 110. The additional loads 140b-n may include, for example, additional motors, power train components, and the like.
As shown in
The second battery system 120 may be electrically connected to one or more low voltage loads 150. The second battery system 120 may include one or more batteries connected in series and/or in parallel. The second battery system 120 may be controlled by one or more battery controllers (not shown).
The one or more low voltage loads 150 may include an HVAC 150a. The HVAC 150a may be configured to heat, cool, and/or circulate air through the vehicle's passenger cabin. The HVAC 150a may include various types of heating, cooling, and ventilation components. For example, the HVAC 150a may include one or more heating elements, seat heaters, floor heaters, defrosters, deicers, fans, filters, air conditioners, compressors, and the like.
Additional loads 150b-n may also be electrically connected to the second battery system 120. The additional loads 150b-n may include, for example, additional motors (e.g. for windows, door locks, sun roofs, compartments), audio system components, infotainment system components, computers, navigation system components, mobile phones, electrical outlets, refrigerators, and the like. A battery management system (not shown) may also be used to regulate the voltage/current that is supplied to the one or more low voltage loads 150a-n.
As shown in
A DC-DC converter 200 may be used to connect the first and second battery systems. Switches 500a-e may be provided. A switch 500c in the open position is shown between the second battery system 120 and the DC/DC converter 200. Thus, current I2 does not flow from the second battery system 120 to the one or more high voltage loads 140a-n nor to the first battery system 110. While switches 500a-e are shown in
In some aspects, the electric vehicle 100 may include a third battery system 130. The battery system 130 may have a capacity that is less than the capacity of both the first and the second battery system. The third battery system 130 may be used to power one or more battery control systems, switches, contactors, essential low voltage components and the like. In some aspects, the third battery system 130 is configured analogously to a standard starting, lighting, and ignition automobile battery. The third battery system 130 may be used, for example, to engage and/or disengage the first and/or second battery systems 110, 120. In some aspects, the third battery system 130 is included in a standard electric vehicle and the second battery system 120 is provided as an add-on feature. The third battery system 130 may be used to power the one or more switches 500a-e. The third battery system 130 may be re-charged by the first 110 and/or second battery system 120.
Turning to
The cells 300 may be cylindrical in shape and have two circular ends that are opposite one another. The side of the cells 300, visible in
Referring again to
The cross-sectional views in
As will be understood, at least one side of the cells 300 may be placed into thermal contact with the plates 401a, 401b. Preferably, the side of the cell placed into thermal contact with the plates 401a, 401b is the side that is opposite to the side of the cell 300 that includes the positive and negative terminal. The cells 300 may be secured into place with an adhesive. Preferably, the adhesive is an epoxy having a high thermal heat transfer coefficient. In this way, heat generated from the cells 300 may flow from the cells 300 to the plate 401a, 401b and into the coolant that flows through the channel 400. In some aspects, when the temperature of the cells 300 is below the desired operating temperature, the coolant may be heated and heat may flow from the coolant to the plates 401a, 401b in order to heat the cells 300.
The cross-section view of
The coolant flow configuration depicted in
The housing may be manufactured according to the following method. While the steps are described in a particular order, other ordering of the steps is possible.
As shown in
In other implementations, the cell cover wall 230a, 230b, inner cell retaining wall 235a, 235b, and plate 401a, 401b are formed in a single step. For example, the cell cover wall 230a, 230b, inner cell retaining wall 235a, 235b, and plate 401a, 401b may be formed by injecting molding over a metal plate 401a, 401b. In other implementations, the outer retaining wall 225a, 225b, cell cover wall 230a, 230b, inner cell retaining wall 235a, 235b, and plate 401a, 401b are formed in a single step by injecting molding over a metal plate 401a, 401b.
Cells may be inserted into the cell carriers 240 of the inner retaining walls 235. An adhesive may be used to bond the cells to the plate 401a, 401b and/or the inner cell retaining wall 235a, 235b. The adhesive preferable has a high thermal heat transfer coefficient. The cell carriers 240 and/or the inner retaining walls 235a, 235b may thus form a support for at least a portion of the cells and inhibit the movement of the cells in at least the longitudinal, lateral, and/or transverse direction.
Battery cell connection circuits 305a, 305b may be provided to electrically couple the battery cells 300 (not shown in
Various electrical connections may be made with the assembled housing 200 at the terminals 310a, 310b, 315a, 315b. For example, in some implementations it may be desired to produce electrical power at the voltage provided by the cells contained in a single housing part 201a, 201b, and the parts 201a, 201b may be connected in parallel with a negative or ground connection coupled to both negative terminals 310a, 310b and a positive connection coupled to both positive terminals 315a, 315b. In some implementations it may be desired to produce electrical power at twice the voltage provided by the cells contained in a single housing part 201a, 201b, and the parts 201a, 201b may be connected in series by electrically coupling either the left negative terminal 310a with the right positive terminal 315b or the left positive terminal 315a with the right negative terminal 310b. The uncoupled negative terminal 310a or 310b can then be connected to a negative or ground connection, and the uncoupled positive terminal 315a or 315b can be connected to a positive connection. Electrical connections external to a battery housing 200 will be discussed in greater detail below with reference to
With reference to
As such, the housing 200 includes two sets of batteries that are cooled by an internal common channel. The electrochemical cells are thus positioned such that the non-electric terminal ends are facing inward and are in thermal contact with the channel and the electric terminal ends are facing outward and electrically connected by cell connection circuits 305a, 305b positioned on either side of the housing 200. The end cover walls 245a, 245b may physically protect and electrically insulate the connection circuits 305a, 305b. The cell connection circuits 305a, 305b may be configured to connect the cells in parallel or in series and provide a voltage difference between the positive terminals 315a, 315b and the negative terminals 310a, 310b. The cell connection circuits 305a, 305b may be disposed on opposite sides of, and parallel to, the common coolant channel. The common coolant channel may be oriented vertically within the housing 200 so as to facilitate fluid circulation through the channel and mitigate cavitation that may occur within the coolant in the channel.
The housing 200 depicted in
In some embodiments, a plurality of battery housings 200 can be combined to provide greater energy storage capacity and/or higher voltage. Referring now to
In some embodiments, a printed circuit board (PCB) and/or other circuitry (not shown) may be included, such as for monitoring the status and/or performance of the battery pack or one or more individual battery modules 200. For example, a PCB may be located in any suitable location adjacent to or near each battery module 200, such as on top of or below the parallel bus bar 335. The parallel bus bar 335 may support and/or secure the PCB, which may be attached in its location by connection to one or more of a battery module 200, parallel bus bar 335, series bus bar 320, or other structure of the battery pack. The PCB may be electrically connected to other circuitry of one or more battery modules 200, such as cell connection circuits 305a, 305b, one or more thermistors or other temperature sensors (not shown) located within the module 200, or other monitoring circuitry. Accordingly, each PCB may be used for monitoring and/or control of one or more battery modules 200. For example, a PCB may monitor an open circuit voltage of a battery module 200 or half module 201a, 201b, a voltage difference between components within a battery module 200 or half module 201a, 201b such as between two or more battery cells or groups of cells connected in series, a current flowing into or out of a battery module 200 or half module 201a, and/or temperature data obtained from temperature sensors (not shown) within a battery module 200.
As will be understood, the disclosed coolant path may provide a temperature control system that allows for a more uniform and parallel cooling/heating than other systems. The disclosed coolant pathway may also reduce the number of liquid connections in order to reduce the likelihood of leakage. For example, liquid coolant may be pumped into the inlet/outlet 250 on the left hand side of
In some aspects, the tray 600 is configured to be positioned in a vehicle in a direction that extends laterally with respect to a vehicle. That is to say, the tray 600 may be sized and shaped to extend along all or a portion of the width of a vehicle (e.g. in a direction extending from a front right wheel to a left front rear well). In some aspects, the tray 600 is configured to be secured an area that is easily accessible to a user or mechanic. For example, the tray may be located in a front or rear trunk area. In this way, the battery housings 200 may be easily accessed and removed and/or inserted into the tray as needed.
With reference to
The foregoing description and claims may refer to elements or features as being “connected” or “coupled” together. As used herein, unless expressly stated otherwise, “connected” means that one element/feature is directly or indirectly connected to another element/feature, and not necessarily mechanically. Likewise, unless expressly stated otherwise, “coupled” means that one element/feature is directly or indirectly coupled to another element/feature, and not necessarily mechanically. Thus, although the various schematics shown in the Figures depict example arrangements of elements and components, additional intervening elements, devices, features, or components may be present in an actual embodiment (assuming that the functionality of the depicted circuits is not adversely affected).
The methods disclosed herein comprise one or more steps or actions for achieving the described method. The method steps and/or actions may be interchanged with one another without departing from the scope of the claims. In other words, unless a specific order of steps or actions is specified, the order and/or use of specific steps and/or actions may be modified without departing from the scope of the claims.
It is to be understood that the implementations are not limited to the precise configuration and components illustrated above. Various modifications, changes, and variations may be made in the arrangement, operation, and details of the methods and apparatus described above without departing from the scope of the implementations.
Although this invention has been described in terms of certain embodiments, other embodiments that are apparent to those of ordinary skill in the art, including embodiments that do not provide all of the features and advantages set forth herein, are also within the scope of this invention. Moreover, the various embodiments described above can be combined to provide further embodiments. In addition, certain features shown in the context of one embodiment can be incorporated into other embodiments as well.
Any and all applications for which a foreign or domestic priority claim is identified in the Application Data Sheet as filed with the present application are hereby incorporated by reference under 37 CFR 1.57. This application claims the benefit of U.S. Provisional Application No. 62/317,137, filed Apr. 1, 2016, entitled “LIQUID TEMPERATURE REGULATED BATTERY PACK FOR ELECTRIC VEHICLES.” This application is also related to attorney docket number FARA.059A1, filed on the same day as the present application, and also claiming priority to U.S. Provisional Application No. 62/317,137. Each of the above-identified applications are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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62317137 | Apr 2016 | US |