Active crystallisation control in phase change material thermal storage systems

Abstract

The present invention relates to phase-change materials (PCM) which store and release thermal energy by undergoing melt/crystallisation cycles. More particularly, there is described a thermal storage system where sub-cooled phase change material (PCM) is nucleated via a controlled thermal region(s).

Claims

1. A thermal storage system where sub-cooled phase change material (PCM) is nucleated via a controlled thermal region(s), said heat storage system comprising: a containment vessel; phase change material located in the containment vessel; a heat exchanger located inside the containment vessel and immersed in the phase change material, the heat exchanger having an input and an output; and a maintained cold spot that actively keeps some nucleating agent below its deactivation temperature when the PCM is above or near the deactivation temperature such that the PCM does not exhibit sub-cooling upon discharge, wherein the nucleating agent is a specific hydrate and wherein a deactivation process of the nucleating agent is dehydration or melting, and wherein nucleating PCM via a controlled thermal region within the containment vessel results in control of nucleation resulting in consistent, predictive and selectable crystallisation of the PCM.

2. A thermal storage system according to claim 1, wherein the controlled thermal region is the cold spot that actively protects the nucleating agent by keeping it below its thermally driven deactivation process temperature at all times and is maintained by thermal conductive pathway to an area of lower temperature than the PCM.

3. A thermal storage system according to claim 2, wherein the controlled thermal region of the thermal storage system comprises one or more of: (i) a heat spreader which comprises one of: a sheet of graphite, or a metal; (ii) a region of thermal contact with the ambient; (iii) a temperature sensor that provides information feedback; (iv) a compression vapor cycle device; (v) a heat pipe or a switchable heat pipe.

4. A thermal storage system according to claim 1, wherein the cold spot is maintained thermoelectrically, or by a compression vapor cycle, or by a heat pipe, or by a switchable heat pipe.

5. A thermal storage system according to claim 1, wherein the heat exchanger functions as a heat sink for the controlled thermal region of the heat storage system and the cold spot area is located towards the bottom of the containment vessel.

6. A thermal storage system according to claim 1, wherein within the controlled thermal region there is a thermal insulation area located within the containment vessel.

7. A thermal storage system according to claim 1, wherein the thermal storage system comprises a thermoelectric device which consists of one or more thermoelectric devices stacked, with heat spreaders between thermoelectric interfaces, a final cold face with a heat spreader with thermal insulator to create a cold concentrator.

8. A thermal storage system according to claim 7, wherein the final cold face is in contact with the PCM and a hot face is in thermal contact with any of: the ambient; a PCM heat exchanger; or another PCM storage system.

9. A thermal storage system according to claim 7, wherein an electrical store is charged by the thermoelectric device, the same thermoelectric device then utilises the same electrical store to generate cooling to function at a later time.

10. A thermal storage system according to claim 7, wherein the thermoelectric device is powered from an electrical store, where said electrical store is charged from local electrical supply.

11. A thermal storage system according to claim 7, wherein the thermoelectric device is controlled via pulse width modulation (PWM) or direct-drive.

12. A thermal storage system according to claim 1, wherein a temperature sensor provides information feedback.

13. A method for providing a cold spot in a thermal storage system where sub-cooled phase change material (PCM) is nucleated via a controlled thermal region (s), said method comprising: providing a containment vessel which has an input and an output; locating phase change material in the containment vessel; locating a heat exchanger inside the containment vessel and immersing the heat exchanger in the phase change material; wherein the phase change material does not exhibit sub-cooling upon discharge due to the presence of a maintained cold spot that actively keeps some nucleating agent below its deactivation temperature when the PCM is above/near the deactivation temperature, wherein the nucleating agent is a specific hydrate and wherein the deactivation process of the nucleating agent is dehydration or melting, and wherein nucleating PCM via a controlled thermal region within the containment vessel results in control of nucleation resulting in consistent, predictive and selectable crystallisation of the PCM, wherein the controlled thermal region is the cold spot and it provides an area for crystal growth, and wherein the cold spot actively protects the nucleating agent by keeping it below its thermally driven deactivation process temperature at all times and the cold spot is maintained by a heat pipe; or wherein the controlled thermal region is the cold spot that actively keeps some nucleating agent below its deactivation temperature when the PCM is above/near the deactivation temperature at all times and is maintained by thermal conductive pathway to an area of lower temperature than the PCM; and wherein the PCM system does not exhibit sub-cooling upon discharge due to the presence of the maintained cold spot that actively keeps some nucleating agent below its deactivation temperature when the PCM is above/near the deactivation temperature.

14. A method according to claim 13, wherein the PCM is housed in the containment vessel and where the heat exchanger located within the containment vessel which permits the transfer of heat or cooling (thermal energy) into/out of the PCM.

15. A method according to claim 13, wherein the heat exchanger located within the containment vessel functions as a heat sink for the heat storage system.

16. A method according to claim 13, wherein the power consumption of the cold spot is proportional to the heat transfer rate from the PCM to the cold spot and that therefore insulation is required between the cold spot with crystals and the PCM.

17. A method according to claim 16, wherein a cold thermoelectric face of the cold spot has a high thermal conductivity interface material comprising heat spreaders and insulation to act as a cold concentrator.

18. A method according to claim 17, wherein a thermal insulator covers the high thermal conductivity interface material apart from a small section which is left exposed and this concentrates the cooling towards the small section thus achieving a lower temperature or reducing the power consumption.

19. A method according to claim 18, wherein a hot side of a thermoelectric device comprises a heat sink to dissipate heat into the PCM itself, the internal heat exchanger of the PCM system or the ambient.

Description

DESCRIPTION OF THE FIGURES

(1) The invention will now be described with reference to the following figures in which:

(2) FIG. 1 is a representation of a heat storage system comprising a heat exchanger in PCM within a containment vessel which shows a cold shock set-up where the heat sink is the heat exchanger of the PCM containment system;

(3) FIG. 2 is a representation of a heat storage system comprising a heat exchanger in PCM within a containment vessel which shows a cold spot set-up where the heat sink is the ambient through a heat sink external to the containment vessel;

(4) FIG. 3 is a representation which shows the effect that the use of a cold spot achieves. It can be seen that the cooling curve of the system with a cold finger (solid line) goes through a crystallisation during cooling whereas the system with no cold spot (dashed line) does not, as represented by the lack of a crystallisation plateau. The effect of such is that the system with a cold spot has far superior energy storage capacity;

(5) FIG. 4 is a representation of a stacked thermoelectric device setup that can provide a cold shock; with thermoelectric devices (TEG, A), heat spreader (B) and insulation (C) to act as a cold concentrator;

(6) FIG. 5 is a representation of the use of a sub-cooled PCM store with cold shock activator. The PCM has cooled to ambient without crystallising; it remains at that temperature for a period of time; the cold shock is then activated; crystallisation begins and the PCM heats up and

(7) FIG. 6 is a representation of a cold spot with a single thermoelectric device (TEG, A), heat spreader (B) and insulation (C) to act as a cold concentrator.

DETAILED DESCRIPTION

(8) a. PCM Heat Storage Systems

(9) A method to use PCMs is to house the PCM in a containment vessel and to have a heat exchanger internally, to permit the transfer of heat or coolth (thermal energy) into/out of the PCM.

(10) FIG. 1 is a representation of a heat storage system 10 comprising a heat exchanger 18 located within a containment vessel 12. The heat exchanger 18 is immersed in PCM 11 which is contained within the containment vessel 12. The heat exchanger 18 has an input 14 and an output 16. The heat exchanger 18 functions to transfer heat in and/or out the heat storage system. Any number and type of heat exchangers may be used.

(11) FIG. 1 also shows a cold shock area set-up generally represented by the reference numeral 20. The cold shock area 20 has been expanded and is located at the top of the containment vessel 10. As shown in the expanded area there is a cold shock 22 located adjacent to thermoelectric devices (TEG) 24, 26 and a heat exchange pipe (HX pipe) 28. Electrical leads 30 are also shown attached to the thermoelectric devices 24, 26.

(12) FIG. 2 is a representation of a further heat storage system 100. The heat storage system 100 contains a PCM 111 within a containment vessel 112. A heat exchanger 118 is immersed in the PCM 111. The heat exchanger 118 has an input 114 and an output 116. The heat exchanger 118 functions to transfer heat in and/or out for the heat storage system 100. Any number and type of heat exchangers may be used.

(13) In the heat storage system 100 shown in FIG. 2 there is a cold shock area 120 located at the bottom of the containment vessel 112. The cold shock area 120 is expanded in size where it can be seen there is a cold spot 128. Near the cold spot 128 there is insulation areas 124, 126. Located under the insulation areas 124, 126 there is a heat sink 122.

(14) As shown in FIG. 2 in the heat storage system 100 the heat sink is the ambient through a heat sink external to the containment vessel 112.

(15) b. Thermoelectric Devices

(16) b1. Thermoelectric Devices Thermoelectric devices operate using the Peltier effect, and results in a heat pump type effect on a small, solid-state, scale. A thermoelectric device is typically a rectangular plate of thickness less than 10 mm, with a ceramic coating on the two large faces. When an electrical current is passed through the thermoelectric device, heat is generated on one face, and coolth on the other. Such a thermoelectric device is used in the heat storage system 10 shown in FIG. 1.

(17) b2. Compression Vapor Cycle Devices

(18) Compression vapor cycle devices utilise the boiling (or evaporation), of a fluid to provide cooling, generally in a closed loop where the reverse process (condensation) also occurs at a different location (or the same).

(19) b3. Heat Pipe, or a Switchable Heat Pipe

(20) A heat pipe, or a switchable heat pipe, are objects that have a liquid or gas inside them that are sealed and there is a change of phase when heat or cold is applied to one or more region of the object.

(21) In a switchable heat pipe added control is offered. The effect is an object that can show (optionally if switchable) high levels of thermal conductivity at certain temperatures or temperature ranges.

(22) c. Sub-Cooling

(23) For a PCM to sub-cool, the whole of the material must be molten, i.e. there must be no unmelted material, otherwise the unmelted material will be an area of crystal growth.

(24) This has the following ramification: the PCM must be fully melted if it is to sub-cool. If the material is not fully melted, then the material will not sub-cool.

(25) Sub-cooling can be passively avoided if a nucleating agent is used (an additive that prevents sub-cooling by providing an area/surface for crystal growth). The use of nucleating agents can be optimised by controlling where they are located and how they are contained, i.e. in a mesh or porous material.

(26) d. Cold Spot

(27) If a PCM has no known sufficient method (e.g. an additive) to ensure consistent nucleation, then that may prevent its use. A method to overcome that would be to design a containment that has a thermoelectrically driven “cold spot”, where crystals of the bulk PCM (or other relevant crystals) are kept in the unmelted state. This is a focus of the present application.

(28) The mass of these crystals can be very small—they are seed crystals that provide a point of growth. It is an advantage to keep this mass of crystals small. This mass of crystals requires to be continuously cooled when the bulk PCM is in the charged (molten) state, and so is preferably minimised.

(29) The technical effect of this is shown in FIG. 3. The effect that the use of a cold spot achieves is shown. It can be seen that the cooling curve of the system with a cold spot goes through a crystallisation during cooling whereas the system with no cold spot does not, as represented by the lack of a crystallisation plateau. The effect of such is that the system with a cold spot has far superior energy storage capacity and operates at a higher temperature (higher energy). This is one of the benefits of the present invention and the heat storage systems herein described.

(30) There are multiple methods to generate and maintain cold spots. These are described herein and are part of the present invention.

(31) (i) Implementation

(32) The power consumption of the cooling spot is proportional to the heat transfer rate from the bulk PCM to the cold spot—hence it has been found to be preferable to have a measure of insulation between the cold spot with crystals and the bulk of PCM.

(33) If too much insulation is used, then the response time of the cold spot is reduced. This is due to the need for a “thermal bridge” between the internal heat exchanger and the cold mass of crystals—this “thermal bridge” is a crystallisation pathway between the cold spot and the internal heat exchanger.

(34) An alternative is to use the cold spot to protect a nucleating agent, as opposed to the PCM. A nucleation additive used to prevent sub-cooling passively may lose its nucleator properties through a thermally driven ‘deactivation process’.

(35) One example of this is if a nucleator is required to be a specific hydrate, then this hydrate can melt/dehydrate. An actively controlled thermal region within the PCM containment can therefore be used to keep a nucleator functional.

(36) An advantage of this is the thermoelectric device, or a compression vapor cycle device, or a heat pipe, or a switchable heat pipe, does not need to run as often. This reduces running costs and extends lifetime, since the temperature of the cold spot is above the bulk temperature of the PCM.

(37) (ii) Optimisation As shown in FIG. 6 the cold thermoelectric face 316 has a high thermal conductivity interface material, labelled as heat spreaders 312 in FIG. 6. As shown in FIG. 6 there is a cold spot with a single thermoelectric device 310 (TEG, A), heat spreader 312 (B) and insulation 314 (C) to act as a cold concentrator. The heat spreader may be a sheet of graphite, or a metal, such as copper or aluminium. The insulator may be paste or adhesive based. The high thermal conductivity interface material 310 is supplemented by the use of a thermal insulator 310 to cover all of the high thermal conductivity interface material with the exception of a very small area which is left exposed (e.g. about 0.01 mm-5 mm, about 0.1 mm-2 mm about 0.1 mm-1 mm)—this concentrates the coolth towards one small section, thus achieving a lower temperature or reducing the power consumption (i.e. cold concentrator 316). The hot side 318 of the thermoelectric device(s) 310 requires a heat sink to dissipate heat. This may be: the PCM itself, the internal heat exchanger of the PCM system or preferably the ambient as shown in FIG. 2. FIG. 2 is a representation of a heat exchanger 118 in PCM 111 within a containment vessel 112. FIG. 2 shows a cold spot set-up where the heat sink is the ambient through a heat sink external to the containment vessel 112. An expansion of this is shown in FIG. 2 where the hot side of the thermoelectric device 118 is thermally connected to a second PCM store (the PCM or the internal heat exchanger, but preferably the heat exchanger). This has an additional benefit in that the thermal energy is conserved and is utilised to heat an adjacent heat store. This process can also be used to pump heat from one heat store to another heat store, which is covered in patent WO 2011/058383, which is incorporated herein by reference. A temperature sensor can be located near the interface of the thermoelectric device and PCM to determine the cooling requirements of the thermoelectric device. Alternatively, the temperature sensor can be internal to the thermoelectric device or form part of the heat interface material or within the insulating material.

(38) The optimisation is also applicable to a compression vapor cycle device.

(39) The optimisation is also applicable to a heat pipe, or a switchable heat pipe. The use of one or multiple of heat pipes on either the hot or cold side of a thermoelectric device (TEG or TED) further enhances the control over thermal regions.

(40) e. Battery Power

(41) There exist applications where it is advantageous to have a standalone system i.e. not connected to mains electricity, but instead any and all electrical power comes from an electrical storage device, such as a capacitor or electrical battery.

(42) When a thermoelectric device has a temperature differential between its two faces, it is possible to, “in effect”—run the thermoelectric device backwards and generate electricity from this temperature differential, rather than create a temperature differential from electricity. This can be used to charge said electrical store.

(43) (i) Implementation During the charging phase of the PCM the internal heat exchanger has a hot heat transfer fluid flowing through it. In applications where the thermoelectric system is attached to the heat exchanger this results in one side of the thermoelectric device(s) being hot whilst the other side is the temperature of, for example, the material—i.e. there exists a temperature differential. In applications where the thermoelectric system is thermally connected to the ambient, this results in one side of the thermoelectric device(s) being cold whilst the other side is the temperature of, for example, the material. The material may be at a temperature above ambient—i.e. there exists a temperature differential. A PCM store is fully melted and is hot. A thermoelectric device exists where one face is thermally connected to the ambient and one face is thermal connected to the PCM. Thus, there may exist a temperature differential. Furthermore, in instances where the material is going to be sub-cooled, the cooling effect from the electrical generation from the thermoelectric device is directed towards the PCM, which is going to cool to ambient regardless.

(44) (ii) Applications

(45) An example of an application where a standalone system is advantageous is provided below.

(46) A small, cold resistant, electrical store triggers a cold shock to a PCM that is integrated in a fuel cell vehicle which is being used in an ambient temperature that is not permissible towards the operation of a fuel cell. Hence, the fuel cell requires pre-heating before use. This can be accomplished by activating the PCM store via a cold shock.

(47) Alternatively, the fuel cell vehicle may be: an electric battery based system such as Li-ion batteries; a combustion engine; or an emergency heat source (survival suit).

(48) On, for example a vehicle, there is at times available an electrical supply, which can be used to charge a cold resistant electrical store. This electrical store can later, when there is no available electrical supply (e.g. the other systems cannot operate because they are below their minimum operating temperature ranges) be used to run the thermoelectric device(s) to initiate the PCM system which generates heat that can be transferred to other systems, rendering these other systems operational.

(49) f. Power Management

(50) Thermoelectric devices require a DC power supply. Generally, thermoelectric devices require a relatively high amperage, low voltage DC power supply. It can be beneficial to modulate the power of the thermoelectric device.

(51) (i) Implementation

(52) Two common methods are known for thermoelectric power modulation; pulse wave modification (PWM) or direct-drive. Direct drive is preferable for reduced power consumption.

(53) g. Integration of Thermoelectric Device, or a Compression Vapor Cycle Device, with PCM Thermal Store

(54) To prevent contamination of the internal electrical components of a thermoelectric device, or a compression vapor cycle device, it may be preferable to protect the electrical components of the thermoelectric device, or a compression vapor cycle device with a waterproof/PCM proof material. Non-limiting examples of such are: electrical potting compounds; silicone sealant; glues etc.

(55) Whilst specific embodiments of the present invention have been described above, it will be appreciated that departures from the described embodiments may still fall within the scope of the present invention.