This invention relates to a cooling system for an energy storage module, in particular for a module for storing electrical energy, such as an electrochemical energy storage module, providing electrical energy to an end user.
Stored electrical energy modules, or power units of various types are becoming increasingly common in many applications, in particular for use where there are environmental concerns relating to emissions in sensitive environments, or public health concerns. Stored electrical energy power units are typically used to provide electrical energy to operate equipment, to avoid emissions at the point of use, although that stored energy may have been generated in many different ways. Stored electrical energy may also be used to provide peak shaving in systems otherwise supplied from the grid, or from various types of power generation system, including diesel generators, gas turbines, or renewable energy sources. Aircraft, vehicles, vessels, offshore rigs, or rigs and other powered equipment in remote locations are examples of users of large scale stored electrical energy. Vehicle drivers may use the stored energy power unit in city centres and charge from an internal combustion engine on trunk roads, to reduce the harmful emissions in the towns and cities, or they may charge up from an electricity supply. Ferries which carry out most of their voyage relatively close to inhabited areas, or in sensitive environments are being designed with hybrid, or fully electric drive systems. Ferries may operate with stored energy to power the vessel when close to shore, using diesel generators offshore to recharge the batteries. In some countries the availability of electricity from renewable energy sources to use to charge the stored energy unit means that a fully electric vessel may be used, provided that the stored energy units are sufficiently reliable for the distances being covered, with no diesel, or other non-renewable energy source used at all. Whether hybrid, or fully electric, the stored energy units may be charged from a shore supply when docked. The development of technology to achieve stored energy units that are reliable enough for prolonged use as the primary power source must address certain technical issues.
In accordance with a first aspect of the present invention, an energy storage module cooling system comprises a source of cooling fluid; and a fluid conduit for supplying the cooling fluid to one or more energy storage modules; wherein each energy storage module comprises carriers for a plurality of energy storage devices; the carriers further comprising cooling channels forming a cooler for each energy storage device; one surface of each energy storage device being in thermal contact with the cooler; and another surface of the energy storage device being provided with a thermally insulating layer whereby heat transfer between adjacent energy storage devices is reduced.
The cooler may comprise a serpentine shaped channel coupled to the source of cooling fluid.
The cooler may comprise a plurality of channels in parallel coupled to the source of cooling fluid.
The cooling channels may comprise one of polyethene, polyamide, or thermoplastic.
The thickness of walls of the cooler channel may be chosen to not exceed 5 mm.
The cooling fluid may comprise one of water, or water glycol mixture.
The thermally insulating layer may comprise an inorganic silicate.
The thermally insulating layer may have a thickness in the range of 1 mm to 5 mm.
The carrier or cooler may be manufactured by 3-D printing, or additive manufacturing techniques.
The cooling unit, cooling fluid conduit and coolers, may comprise a closed, re-circulating system.
The energy storage devices may comprise electrochemical cells.
In accordance with a second aspect of the present invention, a power supply system may comprise one or more energy storage modules, each module comprising a plurality of energy storage devices electrically connected in series; and a cooling system according to the first aspect.
An example of cooling system and method according to the present invention will now be described with reference to the accompany drawings in which:
Electrical energy storage modules based on electrochemical cells, such as batteries are already in use, for example in hybrid, or electric vehicles. Early large scale batteries were lead acid, but more recently, lithium ion batteries have been developed for electrical energy storage for large scale applications. Li-ion batteries are typically pressurised and the electrolyte is flammable, so they require care in use and storage. A problem which may occur with Li-ion batteries is thermal runaway, which may be caused by an internal short circuit in a battery cell, created during manufacture. Other causes, such as mechanical damage, overcharge, or uncontrolled current may also cause thermal runaway, but the battery system design is typically adapted to avoid these. Manufacturing issues with the cells cannot be ruled out entirely, so precautions are required to minimise the effect should thermal runaway occur. In a large scale Li-ion battery system, the amount of energy that is released during a thermal runaway is a challenge to contain. A thermal event may increase temperatures in a single cell from a standard operating temperature in the range of 20° C. to 26° C. to as much as 700° C. to 1000° C. Safe operating temperatures are below 60° C., so this is a significant problem. There are strict regulations in the marine and offshore industries regarding risk to the vessel or rig, one requirement being that there should be no transfer of excess temperature from one cell to another. If overheating occurs, then it should be contained in a single cell and not allowed to spread. In addition, for marine and offshore applications, weight and volume of any equipment is severely restricted, leading to compact, lightweight systems being advantageous. It is a challenge to produce a compact, lightweight, system that achieves the required thermal isolation and cools the cell in which excess heating occurs, quickly and efficiently. Another problem is that in a thermal event there may also be release of a large amount of flammable gasses, which may self-ignite at elevated temperatures
The problem may be addressed by allowing whole modules to enter thermal runaway and simply control the resulting flames and fire with an external fire extinguishing system. In this case there are open flames in the battery space and controlling the resulting flames and fire does not ensure safe transportation and storage. A conventional approach is to use thick aluminium fins between each cell to provide the cooling, as the aluminium has good thermally conductivity and is able to conduct heat away effectively, but this adds weight and volume and still does not ensure safe transportation and storage because heat is conducted extremely well through aluminium (>300 W/mK) and will heat neighbouring cells quickly, if not cooled. During transport and storage, cooling may not be available. The problem of release of flammable gas may be handled by providing a pressure valve in the module casing, releasing the gas at a certain pressure, either into the battery space or into a separate exhaust system. However, conventional pressure release valves are designed to burst under pressure, which leads to other problems. In addition, active cooling may be provided in the exhaust outside the module to avoid self-ignition.
In a Li-ion battery system, it is very important that the temperature of the battery cells does not exceed the prescribed operating temperature and that the cell temperature in the entire system is uniform. Sustained operation outside the prescribed operating temperature window may severely affect the lifetime of the battery cells and increases the risk of thermal runaway occurring. The present invention addresses the problem of preventing thermal runaway from spreading to other cells, should it occur in one cell, as well as helping to increase the operating lifetime of a cell.
An energy storage module 4 typically comprises a stack of one or more energy storage devices (not shown), for example electrochemical cells, or batteries, each mounted in a carrier, or directly on a cooler, the cooler being either integral with, or separate from the carrier, or mount and the energy storage devices being electrically connected together in series with a neighbouring energy storage device in the next carrier, or on the next cooler. A module typically comprises between 10 and 30 cells, although more or fewer cells per module are possible. The module may further comprise a substantially gas tight enclosure, a part of which comprises a non-magnetic material. The cells are advantageously prismatic or pouch type cells to get a good packing density. A plurality of energy storage modules may be connected together in series by a DC bus 15 to form an energy storage unit 2, or cubicle. A single cell of a module may have a capacity between 20 Ah and 100 Ah, more commonly between 60 Ah and 80 Ah, although cells with a capacity as low as a couple of Ah, or over 100 Ah, may be used. In one example, there may be up to thirty energy storage devices per module 4 and up to nine modules per cubicle. Typically, the unit comprises between 9 and 21 modules, although this depends upon the application and may be up to 30, or 40, or as many as 50 modules per cubicle in some cases. Multiple cubicles may be installed on a vessel, or platform, or in any other installation.
Another surface of the cell may be provided with a thermally insulating layer, as illustrated in
In order to maintain compression of the cell by the carrier 20 to take account of expansion of the cell over time, there needs to be some flexibility to allow for the changes over time. This may be provided by the thermally insulating layer 10, or by a separate flexible layer 14 provided between one surface of the energy storage device and the cooler. The insulating layer or flexible sheet applies a low pressure, typically below 0.2 bar, on the cell wall to increase performance and lifespan and accepts swelling due to normal operation and degradation during the complete life of the cell. The carriers 20 are mounted on one another and fixed together via fittings, such as bolts in fittings 24, 25. Between each water inlet section 3 and outlet section 7 on each carrier 20, a spacer, or washer 29, 28 may be provided.
Cooling fluid flows from the inlet pipe 3 through the channels, or conduits 23 of the cooler 22, cooling the cell by thermal transfer from the surface of the cell through the thin tubing 23 to the cooling fluid. The cooling fluid channels or tubing may have a typical overall thickness in the range of 5 mm to 20 mm, with a wall thickness in the range of 1 mm to 5 mm and advantageously, no more than 3 mm for a polymer plastics material. The cooling fluid is carried away into the outlet pipe 7 and returned to the cooling unit 1 to be cooled again. The tubing 23 formed under plate 21 covers a substantial part of the cell surface on the side that it contacts, anything from 30% to 75% of the cell surface area on that side of the cell.
The overall design has a significantly reduced total material weight and cost by using the cooling liquid pipes to flow cooling fluid directly adjacent to the cell surface, instead of conventional cooler block, heat exchanger designs. In addition, this cooling is provided for normal operation, to keep the cell within a temperature range that is beneficial to performance and operational lifetime, rather than as a one off, only in the case of a thermal event. The water channels 23 may be formed in any suitable form, connected between the inlet and outlet pipes 3, 7 via the tubes 5, 6. Preferably, the cross section of the channels is square to maximise the contact and minimise the amount of plastics material between the cooling fluid and the energy storage device. However, other cross sections could be used, such as circular cross section tubing.
The cell is cooled directly by flowing cooling fluid through the cooling fluid channels in contact with a substantial part of the cell surface, with very little thermal resistance. Conventional cooling arrangements have suffered from hot spots for areas of the cell which were far away from the cooler block, or heat exchanger, but this laminated cooler and cell module avoids this problem. This has the effect of slowing down the aging process of the cell, so increasing its lifetime.
The thin tubing may take any suitable form, connected between the inlet and outlet tubes 5, 6, for example, a continuous serpentine 11 connected between the inlet and outlet tubes 5, 6, as shown in
The layer of thermal insulation 10 on the other side of the cell reduces heat transfer from a cell in the module to a neighbouring cell in the module of the energy storage unit 2 if the cooler is only in direct contact with the cell on one side. The cooling unit 1 provides a flow of cooling fluid around a circuit via pipes 3, 7 and inlet and outlet tubes 5, 6 of each energy storage module 4 then through the conduits 13 of coolers 9 of each energy storage device, or cell 8. Each module 4 is constructed by assembling a series of carriers incorporating the cooler, with a cell, insulation material, a thin flexible sheet to allow for cell expansion, if required, then repeating for multiple cells. The carriers of each cell connected in series provide the fluid supply pipes 3, 7 and are fixed together, for example by bolts running the length of the module through multiple carriers.
By contrast with a conventional cooling system, the combination of water cooling to keep each cell at an advantageous operating temperature with the use a light, compact, thermal insulation between individual cells of each module in the energy storage system to prevent propagation of heat from one cell to another results in an energy storage system which is more temperature stable and less prone to thermal runaway. The system may be operated without the need for any complex control system. The addition of the thermal insulation to inhibit transmission of heat between cells in the event of thermal runaway is achievable at a relatively low cost. The user is able to operate the energy storage system within an optimal temperature window, whilst reducing the possibility that, for an electrochemical cell, a thermal event in a module will develop into a thermal runaway.
Although the examples have been described with respect to electrochemical cells, such as batteries, which may suffer a thermal runaway and the need to prevent this propagating, other types of stored energy units, such as capacitors, supercapacitors, and fuel cells may suffer if the temperature of modules of the stored energy units regularly goes outside an advantageous operating range, reducing the overall lifetime and increasing maintenance costs, so the cooling system may also be beneficial for these. For a vessel, or system, relying on stored energy as its primary, or only power source, reliability is particularly important and optimising operating conditions is desirable. The detailed examples given are for batteries, or electrochemical cells, but the principle of the invention is applicable to other types of energy storage unit.
Number | Date | Country | Kind |
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1705512 | Apr 2017 | GB | national |
This application is the US National Stage of International Application No. PCT/EP2018/058142 filed Mar. 29, 2018, and claims the benefit thereof. The International Application claims the benefit of United Kingdom Application No. GB 1705512.0 filed Apr. 5, 2017. All of the applications are incorporated by reference herein in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/058142 | 3/29/2018 | WO | 00 |