The present invention is related to regenerative electrocaloric cooling devices and, in particular, regenerative electrocaloric cooling devices using rotating electrocaloric material rings.
Most conventional heat pumps, refrigerators, air conditioning, and climate control devices achieve cooling through a mechanical vapor compression cycle (VCC). Such systems are known to suffer from low efficiency and air conditioning is a major contributor to electric utility peak loads. Another related problem with today's VCC cooling technology is the adverse environmental impact of the refrigerant gases employed, which are strong greenhouse gases. These factors necessitate a search for new cooling technologies for air-conditioning, refrigeration, heat pumps, and climate controlling devices that possess improved energy efficiency, low cost and are environmentally friendly.
The electrocaloric effect (ECE) is a result of a direct coupling between thermal properties (such as entropy and temperature) and electric properties (such as electric field and polarization) in an insulation dielectric material. In this type of material, a change in the applied electric field induces a corresponding change in polarization, which in turn causes a change in the dipolar entropy Sp as measured by the isothermal entropy change ΔS in the dielectrics. If the field change is carried out in an adiabatic condition, the dielectric material will experience an adiabatic temperature change ΔT. Recently, a large electrocaloric effect has been discovered and developed (Xinyu Li, Xiao-shi Qian, S. G. Lu, Jiping Cheng, Zhao Fang and Q. M. Zhang. Tunable Temperature Dependence of Electrocaloric Effect in Ferroelectric Relaxor P(VDF-TrFE-CFE) Terpolymer. Appl. Phys. Lett. 99, 052907 (2011); Xinyu Li, Xiao-shi Qian, Haiming Gu, Xiangzhong Chen, S. G. Lu, Minren Lin, Fred Bateman, and Q. M. Zhang. Giant electrocaloric effect in ferroelectric poly(vinylidenefluoride-trifluoroethylene) in copolymers near a first-order ferroelectric transition, Appl. Phys. Lett. 101 132903(2012)) in modified polar-fluoropolymers such as poly(vinylidene fluoride-trifluoroethylene-chlorofluoroethylene) (P(VDF-TrFE-CFE)) terpolymer and polymer blends. In the EC polymers, a temperature change of ΔT as large as ˜28° C. can be induced near room temperature under an applied field change of 180 MV/m (see
A key component of a cooling device is the transportation of entropy from the cold end to the hot end. The objective is to transport entropy from one temperature level to another temperature level in a reversible manner. This requires a substance whose entropy depends on properties other than temperature. In the cooling devices of this invention, this substance is the electrocaloric (EC) material, whose entropy and/or temperature can be changed by external electric fields.
All steady state converters must be cyclic since the entropy carrying substance is not consumed.
COP=Tc(Th−Tc) (1)
In the cooling cycles of
Moreover, a comparison of devices in
Even though the EC materials have great potential for cooling devices with high cooling power and high cooling efficiency, the current ECE cooling device designs are not convenient for practical operation and cannot fully utilize the superior performance of the EC materials. Therefore, new cooling system design and now cooling control method are highly desirable to achieve high cooling power and high efficiency.
A regenerative electrocaloric (EC) device is provided. The regenerative EC device uses a special configuration to expand the temperature span Th−Tc, thereby increasing the cooling power and improving the efficiency thereof. One embodiment of the EC regenerative cooling device of the instant invention includes two electrocaloric effect (ECE) elements/rings in direct thermal contact with each other. The two rings rotate in opposite directions and are divided into multiple sections with an electric field or electric fields applied to every other region/section and an electric field or electric fields removed from remaining sections.
The regenerative EC device can include a first EC ring and a second EC ring, the first EC ring rotating in an opposite direction to the second EC ring and in sliding contact therewith. The EC device has a hot end and a cold end, and an electrical power supply (or supplies) in communication with the two EC rings. The electrical power supply produces an electric field across a portion of the first EC ring, the electric field reducing an entropy of the subjected portion of the first EC ring. The reduced entropy results in an increase in temperature of the selected portion of the first EC ring such that the portion with the electric field thereacross has a higher temperature than another portion of the EC ring which does not have the electric field thereacross. The cold end of the regenerative EC device absorbs heat from an outside source of heat and the hot end of the EC device transfers or expels heat to a heat sink. In addition, rotation of the first EC ring relative to the second EC ring pumps heat from the cold end to the hot end via the rotation and applied electrical field and thereby provides a regenerative EC cooling device.
The first EC ring has a first ring high electric field region (HEFR) and a first ring low electric field region (LEFR), and the second EC ring has a second ring HEFR and a second ring LEFR. The regenerative EC device is arranged and operates such that the first ring HEFR is oppositely disposed from and in direct sliding thermal contact with the second ring LEFR. Also, the first ring LEFR is oppositely disposed from and in sliding contact with the second ring HEFR. During operation of the regenerative EC device, heat passes from the first ring HEFR to the second ring LEFR and from the second ring HEFR to the first ring LEFR.
In some instances, the regenerative EC device includes a frame and the first EC ring and the second EC ring rotate relative to the frame. In such instances, the first ring HEFR, first ring LEFR, second ring HEFR, and second ring LEFR are stationary relative to the frame and the first EC ring and second EC ring have portions that rotate into and out of their respective HEFR and LEFR.
The first EC ring can have a plurality of first ring segments, a first subset of the first ring segments located within the first ring HEFR and a second subset of the first ring segments located within the first ring LEFR. In addition, the second EC ring can have a plurality of second ring segments, a first subset of the second ring segments located within the second ring HEFR and a second subset of the second ring segments located within the second ring LEFR. Similarly as stated above, rotation of the first EC ring and/or the second EC ring affords for a ring segment of the first subset of the first ring segments to travel from the first ring HEFR into the first ring LEFR as a ring segment of the second subset of the first ring segment travels or passes from the first ring LEFR into the first ring HEFR. The same can be true for the second ring, that is as one ring segment of the second EC ring passes or travels into the second ring HEFR, another ring segment passes or enters into the second ring LEFR.
The segments of the first EC ring and/or second EC ring are naturally made from an EC material and are divided from each other with a low thermal conductivity divider. In this manner, heat conduction within a given ring from Th to Tc can be reduced since the heat conduction is proportional to the thermal conductivity of the material between Th and Tc. Stated differently, the low thermal conductivity dividers cause a low thermal conductivity of the ring. Also, the overall thermal conductivity of the ring between Th and Tc should be less than 0.3 W/mK and most plastics have thermal conductivity <0.3 W/mK and thus can be selected for the dividers.
A process for removing heat from a heat source is also included, the process including providing a regenerative EC device as disclosed herein and contacting the cold end of the EC device with an object having heat and contacting the hot end of the regenerative EC device with a heat sink. The cold end of the regenerative EC device absorbs heat from the object, the EC device pumps the heat to the hot end of the regenerative EC device, and the hot end expels the heat to the heat sink as the first EC ring rotates in an opposite direction to the second EC ring. In this manner, a cooling device is provided to remove heat from heat sources or objects such as electronic devices, engine components, a room, cold chamber of a refrigerator and the like.
Reference is made to the attached drawings, wherein elements having the same reference numeral designations represent similar elements throughout.
The following terminology and definitions are used throughout the specification and are provided here for clarity.
Th (TH): Temperature of the heat sink (hot end) of the EC cooling device.
Tc (TL): Temperature of the cold load (cold end) of the EC cooling device.
EH (Eh): The maximum electric field applied to a cooling device of an embodiment of the present invention.
EL (or EL=0): The low electric field applied to an EC cooling device of an embodiment of the present invention (EH>EL, and in some cases, EL=0).
ΔE=EH−EL is the change of electric field.
EC ring: A ring shaped EC module of outer-diameter (OD), inner diameter (ID) and thickness d, with multiple EC segments separated by gaps consisting of low thermal conductivity (k<0.2 W/mK).
Regions with or without electric fields: Regions fixed in the space. As the EC rings rotate, the EC segments will leave a region without electric field and enter a region with electric field and vice versa.
Thermal diffusion length: δ=√{square root over (2α/ω)}, where co is the angular frequency and α=k/(ρc) is the thermal diffusivity.
The heat exchange layer: consisting of high thermal conductivity segments (such as Al, with thermal conductivity >100 W/mK) and low thermal conductivity segments filling the spaces between the high thermal conductivity segments. The high thermal conductivity segments are in thermal contact with the EC rings at Th and Tc areas to exchange heat between the EC rings and external heat sink and cold load,
Aligned position of the two EC rings: the EC segments and gaps in one ring overlapped (aligned) with the EC segments and gaps in the other ring, respectively.
The present invention provides a regenerative electrocaloric (EC) cooling device. As such, the invention has use for refrigeration or cooling of devices, objects, rooms (e.g. air conditioning), etc.
The regenerative EC device includes two EC material rings that rotate in opposite directions of each other. The two EC rings are also in direct thermal contact with each other. In this manner, heat flows between the two EC rings and affords for regeneration thereof. In addition to the two EC rings, an electrical power supply affords for applying an electrical field across at least a portion of one of the EC rings. As such, the portion of the EC ring that has the electrical field applied thereacross exhibits a rearrangement of dipolar states, i.e. from a disordered dipolar state to an ordered dipolar state. In addition, and with an adiabatic system, the ordering of the dipolar states reduces the entropy and increases the temperature of the material. Likewise, the removal of the electric field from the portion of the EC material results in a disordered dipolar state and an associated increase in entropy and decrease in temperature.
With the electrical field applied across a portion of at least one of the EC rings, in combination with rotation of the two EC rings, the regenerative EC device has a cold end and a hot end. In addition, the cold end absorbs heat from an object having heat, and which is desired to be cooled, and the EC device pumps the heat to the hot end where it is expelled to a heat sink.
It is appreciated that when a given EC ring portion has an electric field applied thereacross, the corresponding and oppositely disposed portion of the other ring does not have an electric field applied thereacross. As stated above, the temperature of the EC ring portion with the electric field applied thereacross increases due to the ordering of the dipolar states and reduction in entropy, and this portion has a higher temperature than the corresponding and oppositely disposed EC ring portion without the electric field. As such, heat is transferred from the EC ring having the electric field applied thereacross to the oppositely disposed EC ring that does not have the EC ring applied thereto. In this manner, the cooling device is regenerated.
In some instances, a pair of oppositely disposed and oppositely rotating EC rings are in thermal contact with each other and each ring has a plurality of EC material segments separated by gaps of low thermal conductivity material. Also, each of the rings has a high electric field region and a low electric field region. The high electric field region of one ring is oppositely disposed and in thermal contact with a low electric field region of the other ring. It is appreciated that a given ring can have more than one high electric field region and more than one low electric field region. In such cases, the corresponding and oppositely disposed ring would likewise have more than one high electric field region and low electric field region.
In order to apply the electric field across a portion of an EC ring, electrodes are in contact therewith. In addition, each EC material segment can have one electrode thereacross or, in the alternative, have more than one electrode thereacross. Finally, a regenerative EC device can have a plurality of EC rings stacked on top of each other in order to increase the cooling efficiency and/or cooling power of the device.
Turning now to the figures, one embodiment of an EC device 70 is schematically illustrated in
As illustratively shown in the
The top EC ring 700 and bottom EC ring 705 are made from a plurality of EC material segments 710 and 730, respectively. Also, and in a first example of the invention, an electric field (E=EH) is applied to half of the ECE segments 710 in top EC ring 700 as indicated by the cross-hatching on six of the segments 710 on the top EC ring 700. Also, the other half of the EC ring segments 710 have no field electric field applied thereto (E=0).
The region under the electric field region for the top ring 700 is 180 degrees apart from the region under electric field for the bottom ring 705. Stated differently, there is no electric field (or lower electric field) in the EC segments 730 of the bottom ring 705 when the corresponding (right above) EC segments 710 of the top ring 700 are under electric field (EH). Furthermore, as the top ring 700 rotates clockwise 780, EC segments 710 near Th (high temperature end) move from the region of no-electric-field (E=0) or low field (E=EL) to the region of high-electric-field EH. Such rotation causes an entropy reduction and heat ejection from the EC segments that have “crossed-over” from the no-electric-field or low-electric-field region to the high-electric-field region. Likewise, as the bottom EC ring 705 rotates counter-clockwise 790, EC segments 730 near Th move from the no-electric-field (E=0) or low-electric-field EL to high field EH and eject heat.
At Tc, the EC segments 710, 730 of the top ring 700 and bottom ring 705, respectively, move from high-electric-field regions to no-electric-field or low-electric-field regions, thereby affording an entropy increase in the EC segments, a reduction in temperature and heat absorption from the cold end. Therefore, as the top ring rotates clockwise from Th to Tc (along the path Th-B-Tc) in the EH region, the temperature of the EC segments will decrease from Th to Tc. At the same time, the bottom ring rotates counter-clockwise from Tc to Th in the no-field (or low field) region (along the path Tc-B-Th), the temperature of EC segments will increase from Tc to Th. Through the heat exchange between the two rings, a regenerative process occurs via heat flow from the EC segments 710 in the top ring 700 to EC segments 730 in the bottom ring 705 as indicated by the arrows pointing “up” and “down” along the z-direction.
In the other half-rings, i.e. the half rings shown on the right hand side of the figure, heat flows from the EC segments 730 in the bottom ring 705 to the EC segments 710 in the top ring 700.
In a steady state operation, as the EC segments 710 in the top ring 700 enter the EH region, the ECE causes a temperature increase, resulting in heat ejection to a heat sink (not shown) at Th. Also, as the EC segments 710 in the top ring 700 rotate clockwise 780 from Th towards Tc, the EC elements 730 in the bottom ring 705 rotate counterclockwise 790 from Tc towards Th. The heat transfer between the EC elements 710 from the top ring 700 under high-electric-field to the EC elements 730 of the bottom ring 705 under no- or low-electric-field as indicated by the vertically oriented arrows in
A similar process occurs in the other half of the rings with the functions of top and bottom rings are reversed. In particular, and referring to the ring halves shown on the right-hand-side of
When an EC segment moves near Tc, the electric field for the EC segment is reduced from EH to EL, the entropy of the segment increases, the temperature of the EC segment decreases, and the EC segment absorbs heat at the cold end and thereby affords cooling of heat source (not shown). In order for the cooling device in
Looking now at
Regarding the specific diagrams in
Although the two EC rings rotate in opposite directions, a temperature distribution will not change with time once a steady state condition is reached. The temperature gradient from Th to Tc along the plane of the rings, hereafter referred to as the φ-direction, causes heat conduction from the Th end to the Tc end. Such heat conduction along the φ-direction is a heat loss and lowers the cooling power and cooling device efficiency. Therefore, it is important to reduce or eliminate the thermal conduction along the φ-direction.
In order to reduce the thermal conductivity of the EC rings along the φ-direction, the EC rings are divided into segments as illustrated in
From the above discussion, it is appreciated that the EC rings of the cooling device should have a high thermal conductivity along the z-direction and a low thermal conductivity along the φ-direction. For the cooling device of
The width of the gaps 720, 740 is generally small compared to the overall width and/or length of the EC segments. For example, the gaps 720, 740 can be less 5%, less than 10% or less than 15% of the corresponding length of an EC segment. In addition, the width of the gaps 720, 740 can determined by or be a function of a device performance or cost parameter such as cooling power, temperature span Th-Tc, COP, manufacturing cost, etc. Finally an EC ring structure is easily fabricated.
Typical dimensions of an EC ring be on the order of a 5 cm diameter and a 0.2 mm thick. In addition, such a ring can be fabricated into at least two segments using conventional fabrication techniques. For example, the top EC ring 700 and bottom EC ring 705 shown in
Not being bound by theory, the EC properties of EC rings can be used to derive the performance of an EC device such as the one illustrated in
In addition, although the cooling device with two rings rotating at a constant angular speed can work, a variable angular velocity, such as a stepwise rotation, can be used to reduce conduction heat loss between the hot and cold ends and thereby improve the heat exchange and regenerative process between the two rings along the z-direction. Naturally, improving heat exchange between the two rings improves the cooling power and efficiency of an EC device.
Referring to
Given the above, it is desirable that the time period which the two EC rings 700, 705 are in an unaligned position be reduced to as low or little as practically possible. As such, another embodiment of the present invention rotates the two EC rings 700, 705 opposite to each other, but not at constant angular velocity. Instead, drivers rotate the two EC rings 700, 705 such a transient time (ttrans) during which the two rings are unaligned with each other is less than (
As mentioned above, step motors drive or move the two EC rings such that the transient time (ttrans) during which the two rings are in unaligned position is much shorter than the stationary time tstat, during which the two rings are in the aligned position. In particular,
Although two EC rings of an EC device rotate in opposite directions, a temperature profile of the device does not change with time once a steady state condition is established. Such a feature or aspect of the inventive EC device disclosed herein makes easily affords for an external thermal load to exchange heat with the EC segments at both the hot and cold ends. For example, direct contact of an aluminum (Al) plate (kAl=205 W/mK at room temperature) with EC rings affords heat exchange between the rings and external thermal loads as schematically shown in
It is another embodiment, heat exchange plate(s) are stationary do not rotate with the EC rings. The heat exchange plate(s) are in direct thermal contact with the EC rings at the hot end and cold end in order to provide effective heat exchange between the EC segments and cold load Tc at the cold end and between EC segments and heat sink at the hot end Th. The remaining areas between the two high thermal conductivity heat exchange plates can have a low thermal conductivity layer 930 thereon in order to prevent the heat conduction loss.
Friction due to rotation of the two rings 700, 705 in the EC device 70 shown in
As stated above, the EC segments can be made from EC polymer composites. Such ECE composites have an EC response of ΔT=9 K and Qc=24.3 J/cm3 under an electric field change of 100 MV/m at 300 K.
The EC segments in two EC rings can also be an EC ceramic, e.g. Ba(Ti0.8Zr0.2)TiO3 and other EC ceramics with high EC responses induced by a change of electric field. Such ceramics can have an EC response of |ΔT|>5 K and Qc=15.4 J/cm3 under an electric field change of less than 20 MV/m at room temperature.
Such relatively high thermal conductivity EC ceramics (k=6 W/mK) make it possible to operate an EC device illustratively shown in
Taking into consideration the brittleness of a ceramic EC segment, the thickness of a ceramic EC ring needs to be greater than the thickness of a polymer EC ring, e.g. 0.4 mm for a ceramic ring compared to 0.2 mm for a polymer ring. Such an increase in thickness will reduce the lower limit of the cooling power to 23 W/cm3. However, it should be appreciated that this is still a high cooling power. By reducing the lateral dimensions and assembling the EC segment using polymer and epoxy to bond the small ceramic sections of EC elements into large area EC cooling elements, one can improve the fracture resistance of the ceramic EC segments.
A plurality of two EC ring units or pairs can be stacked together to form a bulk cooling device (or heat pump) as illustrated in
A method, apparatus and/or embodiment for increasing the cooling power of the cooling device of
The heat exchange of the device shown in
In general, the number of applied electric field regions depends on the size of the device. The cooling device in
In another embodiment, a method of increasing the cooling power of an EC device is provided. In particular, if the rings of the cooling devices of
By using the inner space, i.e. the space within the inner diameter, with rings of smaller outer diameter, the total cooling power per unit volume is increased. In such a cooling device design, the large and small diameter rings can rotate at the same angular velocity and the number of segments at each ring and number of regions of applying and removing electric field are optimized to achieve high performance in terms of the cooling power density, coefficient of performance, and temperature span between Th and Tc. In the alternative, the small diameter rings do not rotate at the same angular velocity and/or do not have the same number of ring segments as the larger diameter outer rings.
In general, reducing the cooling power will increase the temperature span Th−Tc. In the adiabatic condition, i.e., there is no heat exchange between the EC devices with external load and heat sinks at Th and Tc, Th−Tc then will be totally determined by the thermal conduction heat loss through the devices (from Th and Tc) and by the operation temperature range of EC material. For the current designs of the cooling devices using the EC materials in consideration, a Th−Tc>40 K can be obtained.
In the cooling devices illustrated in the figures, an electric field is applied to the EC segments and as EC rings rotate into and out of the region of high electric field temperature changes of the EC segments occur. In order to apply an electric field to EC segments, the EC segments are coated with thin films of an electrical conductor material in order to form or serve as an electrode. Such electrodes can be made from a thin layer of Al or gold (Au) have a typical thickness of less than 10 nm, less than 20 nm, less than 30 nm, less than 40 nm, less than 50 nm . . . less than 1 micron.
Turning now to
However, each EC segment can be further divided into two or more electric sections as illustrated in
As the top ring rotates, the EC section U1a will enter the field region ½ EH, and then EH, at this time, U1b will enter ½ EH, etc. A smaller field increment, in this case, ½ EH, will improve the EC cooling device reliability and also the efficiency. In general, it is preferred that the electrode at each EC segment is divided into N sections, with N>1, and correspondingly, the electric field increment should also become EH/N when EL=0 or (EH−EL)/N when EL≠0. It is appreciated that the reduced electric field increment as the EC segment enters the high electric field region can improve the EC device performance since a large and sudden escalation of electric field will increase the probability of electric breakdown of the EC material.
In order to better embody the present invention but not limit its scope in any way, examples are provided below.
Using a device performance model, an EC ring having an anisotropic thermal conductivity is assumed. The thermal conductivity along and perpendicular to the z-direction are kZ and kφ, respectively. Also, by preparing EC polymers differently, the kZ and kφ can be varied. A base EC polymers having a thermal conductivity k=0.2 W/mK was assumed and the following two device parameters were used: Case (1): kz=0.5 W/mK and kφ=0.2 W/mK, and Case (2): kz=1 W/mK and kφ=0.2 W/mK.
For simulation purposes, an EC cooling device as illustrated in
The cooling device illustratively shown in
In Case (1), and considering the fact that there are two rings in the EC device, the cooling power at the cold end is Wc=2×8.11/0.5=12.5 W. In Case (2), the total cooling power is 25 W. Also, and considering the EC device has EC rings with dimensions of 0.4 mm ring thickness and 5.5 cm OD, the cooling device in
These modeling results have indeed been confirmed by a finite element simulation of a real device in which a temperature span Th−Tc=20 K, a cooling power >20 W/cm3, and a coefficient of performance (COP) larger than 9 (Carnot COP is 15) for k=1 W/mK for EC segments were obtained. The temperature gradient between Th and Tc will cause a heat conduction loss, which reduces the cooling power and efficiency. Hence the EC rings in the cooling device(s) illustrated in the figures are divided into segments with a low thermal conductivity gap between two neighboring segments.
It is appreciated that the disclosed examples and embodiments are presented for illustrative purposes only and are not meant to limit the scope of the invention. As such, it is the claims, and all equivalents thereof, that define the scope of the invention.
The present application claims priority to U.S. Provisional Application No. 61/860,452 filed on Jul. 31, 2013, which is incorporated herein in its entirety by reference.
Number | Date | Country | |
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61860452 | Jul 2013 | US |