The present invention relates to cold thermal energy storage systems as well as using such systems to optimize and reduce energy consumption of a building. In particular, this invention relates to a novel modular evaporator and thermal energy storage system for chillers.
Improving the energy efficiency of building comfort systems has become increasingly more important due to rising energy costs, as well as increased awareness and concern over global warming as a result of humanity's rising consumption of carbon fuels for electrical energy generation, direct burn heating, and domestic hot water appliances. One area where these concerns can be addressed is through improving the efficiency of solar-based HVAC systems by generating ice during hours of sunshine for later use during the night or cloud cover when solar radiation is inadequate. In traditional HVAC system this can also be beneficial through leveling demand by shifting some of the load during peak hours of a day to off-peak times, thereby eliminating the need to build and run expensive and inefficient peak generator turbines (peakers).
Demand control and increased efficiency is primarily accomplished by shifting the burden of cooling from the hottest time of the day to the nighttime when ambient temperatures, as well as demand, are considerably lower. Refrigeration equipment efficiency increases when the temperature lift requirement decreases. The difference in temperature lift between a hot day and a cool night can often be as high as 50%, thereby resulting in a massive drop in refrigeration equipment lift requirements and a corresponding efficiency increase. The demand for cooling is usually highest during peak hours when outside temperatures and solar radiation are at their highest levels which results in increased electrical consumption. In order to prevent strain on the power grid, utilities are often forced to use gas turbine peak generators for only a few of the hottest hours of the year. The efficiency of these generators is typically 40 to 50% lower than steam turbines which generate most of our electricity. An alternative to peak generation is Thermal Energy Storage (TES) technology.
While there are different types of thermal storage systems on the market the most common designs are based on cold water or two-phase ice/water storage. In recent years the ice storage systems have increased in popularity due to a considerably higher energy storage density. Currently ice storage systems are commonly used in large buildings and campuses. These systems will generally contain chillers which cool a secondary heat transfer media (such as an ethylene-glycol solution) to below the freezing point of water and circulate it through the heat exchangers of ice storage tanks.
Ice storage tanks are usually comprised of rectangular or cylindrical water-filled vessels containing heat exchangers. The heat exchangers are primarily made of circular copper or plastic tubing. The cooling solution flows through the heat exchanger thereby freezing the water. Examples of such systems are disclosed in U.S. Pat. No. 4,831,831 to Carter et al. and U.S. Pat. No. 6,247,522 to Kaplan et al.
These types of systems have several shortcomings. First they occupy a considerable amount of floor space for the chiller and the ice storage tanks Secondly, the solutions used as the heat transfer media are generally expensive, toxic, and have inferior heat transfer properties to water which increases the required pumping energy. And finally, the ratio of ice volume to the full volume of the storage tank is not very high due to the heat exchanger coil occupying a considerable amount of the tank's volume.
The process of calculating the growth of freezing water around multiple tubes is complicated and costly thereby making it impractical for commercial markets. The heat exchanger design is usually accomplished through an experimental approach which is expensive, time consuming and rarely produces satisfactory results. Pockets of water can be encapsulated by ice, then, when these pockets freeze, expansion can generate very high pressures which can damage the tubes and/or the shell. This problem is generally solved by restricting the entire tank water volume from freezing solid which in turn further reduces the average ice storage density and increases the size and weight of the tank required for meeting the cooling demand.
Another example of an approach used for ice-based thermal energy storage systems is disclosed in U.S. Pat. No. 7,124,594 to McRell. The thermal energy storage apparatus is comprised of a tank filled with water and a heat exchanger consisting of a multitude of spiral copper tubing coils connected to upper and lower headers. During the ice generating mode these coils are filled with liquid refrigerant provided by a condensing unit which evaporates and freezes the surrounding water. During cooling mode the liquid refrigerant is pumped into cooling coils inside the air conditioning equipment where it evaporates and is fed into the ice storage tank coils, surrounded by a slurry of ice and water, and is cooled and condensed back into liquid.
These systems are complicated and expensive. Also the density of ice storage is relatively low due to the fact that some of the water must remain unfrozen to ensure proper water circulation at the beginning of the cooling mode and to prevent coil damage due to the high pressures generated by the expansion of freezing ice.
U.S. Pat. No. 6,079,481 to Lowenstein et al. discloses a thermal energy storage system where the heat exchanger assembly is made of substantially flat profile boards disposed in a rectangular tank filled with water. A cooling medium with a low freezing temperature flows from a chiller through the boards and freezes the water, and then this solution flows through the load and back through the boards thawing the ice. While this design is potentially capable of increasing thermal energy storage density, it still requires separate spaces for the chiller and the thermal storage unit and requires a heat transfer medium with a freezing temperature below that of water.
Medium capacity chillers usually have direct expansion, tubes-in-shell evaporators. The refrigerant flows through the tubes and the water (or another heat transfer medium) circulates through the shell. Refrigerant is injected in the tubes and evaporates to cool the water. Each evaporator is designed for a specific load, so a chiller manufacturer must carry multiple models of evaporators with a wide range of capacities. Another shortcoming of tubes-in-shell evaporators is the necessity to prevent the heat transfer fluid from freezing on the tubes which would lead to reduction of their heat transfer properties and even their damage.
According to preferred embodiments of the present invention, a modular evaporator which can be assembled from a number of standard modules is provided. Depending on the requirements, the modular evaporator can be assembled to meet a wide range of design cooling loads. Additionally, the modular evaporator is capable of generating and holding ice for thermal storage purposes, eliminating the need for external ice storage tanks. Furthermore, the heat transfer and thermal storage fluid for the evaporator can simply be water which considerably simplifies the system, lowers the cost, and increases the efficiency of the heat transfer loop.
According to a preferred embodiment the modular evaporator and thermal energy storage apparatus comprises of a number of rectangular modules and two end plates. Cold plates are located between adjacent modules. Modules contain manifolds for distribution of water and refrigerant. All modules and end plates are compressed together forming a water tight vessel that is filled with water. Liquid refrigerant is distributed through the refrigerant manifolds and headers and is injected into the cold plates where it evaporates thereby cooling the cold plates and is then removed from the suction headers and manifolds by the chiller compressor. Water can be pumped into the modular evaporator through water supply manifolds and headers to jet-generating nozzles. In cooling mode, the jets thaw the ice and/or transfer heat to the cold plates.
Advantages of certain embodiments may include more compact thermal energy storage systems, simplification and reduction in the cost of production of chillers and thermal energy systems, and a considerable increase in the energy efficiency and comfort level of the conditioned environment.
Other advantages will be readily apparent to one skilled in the art from the following figures, descriptions, and claims. Moreover, while specific advantages were enumerated above, various embodiments can include some additional advantages while others may be absent.
A preferred embodiment of a modular evaporator 100 incorporating the principles of the present invention is depicted in
An assembled modular evaporator 100 is depicted in
A method of determining this event is provided in U.S. Pat. No. 7,832,217 to Reich, which is herein incorporated by reference in its entirety.
It is to be understood that gasket 410 prevents water leakage from the modular evaporator when all the modules are compressed together by the rods 205. Preferably, the periphery of each module 101 is covered with thermal insulation 401.
The vertical cross section B-B of the two modules 101 side-by-side is depicted in
An alternative preferred design of the module 101 is depicted in
The refrigerant when injected in the liquid sections of the header 608 flows through the ports of the extrusions 610 down to the bottom header 604 which provide fluidic communication among all the extrusions of the cold plate. Then the refrigerant flows through the ports of the extrusions 609 to the suction section of the header 608. It is possible to reverse the liquid and suction manifolds. The design can be also implemented with any numbers of liquid and suction headers (for example, one liquid and two suction).
An alternative preferred design of the cold plates is shown in the
Another alternative preferred design of the cold plate is presented in
The connection of the modular evaporator in the refrigerant and water loops is shown in
The water loop of the system can be arranged in several configurations. In a preferred embodiment, it comprises of a main circulating pump 1007 which circulates water through the modular evaporator 100 and the main loop 114. Local pumps 1012 circulate water through loads 1008.
The system of
In the chiller mode the compressor 1001 and water pumps 1007 and 1012 are on. The refrigerant's suction pressure is kept at a point corresponding to a temperature above the freezing point of water by modulating the expansion valve. The water pump 1007 injects warm water from the loads 1008 into the evaporator 100, flows through the manifolds 402, vertical headers 502 and into the nozzles 403 and 404. The nozzles generate water jets directed at the surfaces of the cold plates which facilitate the heat transfer from the water to the cold plates causing the liquid refrigerant to evaporate. The cooled water leaves the modular evaporator through drain slots 405 and return manifolds 406 and is injected in the main water loop 1014. The pumps 1012 extract the required quantity of cold water from the main loop 1014 to feed the loads 1008. The warm water from the load is injected back into the main loop 1014.
The water supply temperature 1011 is measured by the controller 1005. When the supply water temperature 1011 drops to the set point (which is above the freezing temperature of water) the controller 1005 turns the compressor off. When the supply water temperature rises to the set point plus a dead band the compressor is turned back on. A large volume of water in the modular evaporator minimizes cycling of the compressor. The other way of controlling the supply water temperature is by modulating the output capacity of the compressor.
The preferred embodiment of the module depicted in
In ice generating mode the compressor 1001 is on and the pumps 1007 and 1012 are off. The ice grows on both sides of the cold plates 104. Ice is a relatively good thermal insulator by comparison with water in the presence of convection. Therefore the heat transfer rate from the freezing water to the refrigerant drops during the process of ice growth. As a result of this process the suction pressure also drops as shown in graph 1101 on
Another way of controlling the suction pressure is having multiple modular evaporators connected in parallel as shown in
One of the major advantages of the flat cold plate heat exchanger is the predictability of the process of ice growth. The outside surface of the ice slab is approximately parallel to the plate. When the water freezes it expands and squeezes out excess water between the ice slabs to the sides preventing excessive pressure build up. The method of calculating the ice thickness is disclosed in the U.S. Pat. No. 7,832,217 to Reich. Using measurements of the refrigerant in the suction line from the pressure sensor 1009 and the temperature sensor 1010, the controller 1005 calculates an integral starting from the moment when ice accumulation begins (refrigerant saturation temperature Tr drops below freezing point of water):
I(t)=∫Tr(T)*dτ
where Tr is changing with time t. The thickness of the ice on one side of a cold plate is calculated using the following formula:
where Ui is the thermal conductance of ice, ρi is the density of ice, Ci is the latent heat of ice, and K is a correction coefficient associated with the design parameters of the heat exchanger (experimentally derived). When the thickness of the ice reaches the desired value or the half distance between adjacent cold plates (whichever is greater) the process of ice growth is stopped by turning off the compressor.
In the ice harvesting mode the compressor is turned off and the water pumps are turned on. The warm water coming from the loads 1008 are fed to the nozzles 403 and 404 which generate warm water jets and thaw the ice. Cold water is supplied to the loads 1008 by pumps 1007 and 1012.
In hybrid mode the compressor 1001, as well as the water pumps 1007 and 1012, are on. The temperature of the cold plates 104 are allowed to drop below the freezing point of the water. Ice grows on the surfaces of the cold plates. Simultaneously warm water jets generated by the nozzles 403 and 404 thaw the ice. When the heat load drops, the quantity of ice increases. Conversely, when the load increases, the quantity of accumulated ice decreases. As a result the sum of the latent heat of the thawed ice and the refrigeration cycle match the cooling load. This mode allows for a reduction in the installed capacity of the whole refrigeration system. In other words, a smaller compressor and condensing unit could be utilized. It should be understood that instead of water other heat transfer liquids can be used, as an example, a solution of ethylene glycol in water.
While this invention has been described in conjunction with the various exemplary embodiments outlined above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the exemplary embodiments of the invention, as set forth above, are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the invention.
The present application is related to and claims priority from prior provisional application Ser. No. 61/365,443, filed Jul. 19, 2010, entitled Modular Evaporator and Thermal Energy Storage for Chillers, the contents of which are incorporated herein by reference.
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Number | Date | Country | |
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20110162400 A1 | Jul 2011 | US |
Number | Date | Country | |
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61365443 | Jul 2010 | US |