Cooling and Heating Platform

Abstract

A cooling and heating platform is disclosed. An example cooling and heating platform includes an operating chamber with an operating liquid in the operating chamber. The example cooling and heating platform includes a heat exchanger in the operating chamber. The heat exchanger exchanges heat between the operating liquid and an application fluid in the heat exchanger to maintain the application fluid at a predetermined temperature for an application.

Description

BACKGROUND

Cooling and heating is provided for a wide array of different end-uses. These include, but are not limited in application to, the food industry (from farming, to food preparation, to food service), automotive, marine, and recreational vehicles, residential and commercial HVAC, manufacturing and fabrication, the military, and medical applications. Most cooling and heating systems involve heat transfer. That is, either heat is added or removed to provide the desired heating or cooling respectively.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic overview of an example cooling and heating platform.

FIG. 2 illustrates an example application configuration of the cooling and heating platform.

DETAILED DESCRIPTION

A cooling and heating platform is disclosed. In an example, the cooling and heating platform may be implemented as a cooling and heating platform that is inherently operating at a selected temperature, controlled via vacuum, hygroscopic, electrostatic system(s), and/or a heating element, e.g., in a combinatory manner. The cooling and heating platform may provide a scalable chilling and heating solution. The cooling and heating platform may be implemented in a wide variety of cooling, refrigeration, and/or heating applications.

In an example, the cooling and heating platform manages pressure within an operating chamber to maintain a steady operating temperature based on the boiling point of an “operating liquid.” In an example, the operating liquid is an inexpensive and environmentally friendly “refrigerant.”

By way of illustration, the refrigerant may be water-based and thus ecologically-friendly. An example water-based refrigerant includes, but is not limited to, distilled water. However, other operating liquids may also be implemented. Configurations utilizing a variety of other operating liquids can operate in different temperature ranges, allowing for heating and chilling solutions for an expanded range of applications.

Unlike standard refrigeration or ice, the example cooling and heating platform provides chilling to a specific temperature. The cooling and heating platform is not limited to extreme chilling that requires external control to achieve the desired temperature. This is a particularly important aspect in applications such as, but not limited to, physical therapy. In physical therapy, using too cold of a temperature (e.g., freezing) can have adverse health effects.

The cooling and heating platform is a viable replacement for many chilling/refrigeration devices that are based on the use of standard refrigerants (e.g., CFC's and their replacements). As such, cooling technologies based on the cooling platform may be implemented to reduce the climate impacts from world-wide use of CFC's and their replacements.

Before continuing, it is noted that as used herein, the terms “includes” and “including” mean, but is not limited to, “includes” or “including” and “includes at least” or “including at least.” The term “based on” means “based on” and “based at least in part on.”

The term “operating liquid” means any suitable matter to absorb energy via change of phase. The term “operating chamber” means any suitable partially or fully sealed vessel or container that houses a phase-change mechanism.

The term “heat exchanger” means a device used to transfer heat from one medium to another.

The term “application interface” means any mechanism that enables the transfer of thermal energy between the cooling/heating platform and an application that utilizes the heating/cooling provided by the platform. This may include but is not limited to an “application fluid” that physically transfers heat by flowing or circulating through a heat exchanger and the application.

In addition, the term “thermal battery” as used herein means any suitable device or matter to store thermal energy. A thermal battery, e.g. additional operating liquid, provides the ability to satisfy burst chilling/heating requirements that exceed the instantaneous capacity of the device.

The term “operating liquid supply” means a device that adds operating liquid to the operating chamber.

The term “hygroscopic material” means a material that adsorbs operating liquid vapor from the platform, e.g., from the operating chamber.

The term “electrostatic device” means a device that causes operating liquid vapor atoms/molecules to move in a desired path due to electrostatic fields, e.g., attracting ionized vapor to a anode or cathode for removal from the operating chamber.

The term “bypass switch” means a device that reroutes application fluid depending on the mode selected by the user.

The term “control system” means a system that monitors performance, maintains, displays and/or records the state, and controls the platform relative to a desired mode selected by the user.

The term “overpressure” means pressure above ambient atmospheric pressure.

FIG. 1 is a diagrammatic overview of an example cooling and heating platform 10. The example cooling and heating platform 10 includes a thermally isolated operating chamber 12. A thermal isolation layer 14 is provided around the operating chamber 12 and a heat exchanger 20. The operating chamber 12 includes a thermal battery 16 and an operating liquid 18.

The example cooling and heating platform 10 also includes an operating liquid supply 22. Example configurations of the cooling and heating platform 10 may include a total load of operating liquid 18, e.g., to sustain operation through a nominal operational period.

The operating liquid supply 22 may include a mechanism to reload and restart the device (e.g., open, refill, and then reestablish vacuum).

In another example, operating liquid 18 can be added during operation by introducing operating liquid 18 from the operating liquid supply 22 (e.g., an external source) directly into the operating chamber 12 without breaking vacuum.

Example implementations may include at least one sensor 24, e.g. temperature, pressure, or operating liquid level, on the interior of the operating chamber 12. A vapor removal mechanism 26 may be provided. A fluid circulating pump 28 may be provided to move the operating liquid 18 between the operating chamber 12 and an application 30. The pump 28 may also be implemented to move the application fluid through the heat exchanger 20.

The cooling and heating platform 10 may be configured with one or more connectors that provide access to heat exchanger 20. The connectors may be commercially available (e.g., standard water hose connection), or specifically designed to a particular application. A pressure management device 32, e.g. a vacuum pump, and an operating liquid recovery mechanism 52 may be provided.

Control connections may be provided to control the pressure management device and operating liquid recovery mechanism 52 based on feedback from at least one sensor 24 for the operating chamber 12 and/or for the application 30 to a control system 40 to orchestrate any/all elements of the platform.

The cooling and heating platform 10 can be incorporated into any application 30 that utilizes traditional chilling/refrigeration, and can also be configured to support a wide range of cooling and heating applications. The cooling and heating platform also supports many, if not most, everyday chilling/refrigeration applications 30 and a range of cooling and/or heating applications 30. Examples of applications 30 include, but are not limited to an in-line fluid cooler/heater and a portable cold storage device

An in-line fluid cooler/heater may have application to the following:

• • a. Liquor brewing (beer, whisky, etc.)—brewers struggle with cooling wort fast enough so as to mitigate wort loss and contamination.
  • b. Dairy farming—when cooling milk recovered during the dairy milking process, massive quantities of water are used to cool milk during delivery from collection to processing by pipes on the farm. The device eliminates all water waste by cooling collected milk before receipt by processing.
  • c. Breast milk processing—when breast milk is pumped, it must be cooled before refrigeration is allowed; current process takes longer than desired which risks contamination and loss. The device cools breast milk from body temperature to 40° F., ready for storage.
  • d. Food service (microbreweries, brew-pubs, restaurants)—Brew masters struggle with ways to improve the quality of the consumer's beer experience. Serving beer at the optimum temperature for taste is desirable but difficult. The device allows beer to be served at its intended or optimum temperature. In addition, in the fight for market share, breweries compete for a tap presence in restaurants, taverns, bars, etc. Other foods may require warming.

A portable cold storage device may have application to the outdoor recreation (boating, RV, hunting, camping, etc.) industry—Consumers want convenience and good products to enjoy their outdoor activities. During recreational activities, people are always running for more ice. Current built in boat coolers only hold ice for a few hours. With the cooling system retrofitted into an existing built-in cooler or incorporated into new cooler designs, purchasing a premium cooler will no longer be necessary.

A vacuum-based version as detailed above may have application to the following:

• • a. Commercial construction.
  • b. Residential construction.
  • c. Automotive (cars and RVs).

A version for manufacturing-based industries may have application to the following (e.g., for equipment and process cooling):

• • a. Plastics.
  • b. Foundries.
  • c. Printing.
  • d. Rubber.
  • e. Plating.
  • f. Machine Fabrication.

A food service version may have application to the following:

• • a. Residential refrigerators.
  • b. Food service walk-in coolers (restaurants, etc.).
  • c. Food retailers (grocery stores, wholesalers, liquor stores, etc.).

A medical or therapy-based version may have application to the medical (inpatient/outpatient, sports/physical therapy, etc.)—since the main premise in medicine is all about healing, the medical industry actively seeks faster recovery times in order to improve healing success rates. The device provides hot and cold therapy at therapeutic temperatures within specific limits determined to be medically safe.

A transportation-based version may have application to the following:

• • a. Medical (organ transport—ground or air).
  • b. Food (food transport—ground or air).

Example configurations of the cooling and heating platform 10 may be provided for different operating temperatures to support other chilling and/or heating applications. The operating liquid 18 may be selected based on design considerations, such as but not limited to, optimizing the ability to maintain the target operating temperature required for the application. Other considerations may include, but are not limited to, the pressure/vacuum and environmental/safety considerations of the operating liquid 18.

In an example, the cooling and heating platform 10 may be portable (e.g., hand carried), semi-portable (e.g., movable with the assistance of a hand truck, or similar), or fixed (e.g., requiring heavy equipment to be moved).

Example operation of the cooling and heating platform 10 is based on maintaining the pressure in a chamber or other vessel 12 containing the operating liquid 18 at a level of vacuum/overpressure (e.g., from pressure management device 32 and operating liquid recovery mechanism 52) such that the boiling point of the operating liquid 18 corresponds to the target chilling (or heating) temperature of the device or application 30. Chilling/refrigeration is provided by passing an application fluid to be chilled or heated (e.g., within return line 34) through a heat exchanger 20 (e.g., coils) immersed in the operating liquid 18 within the operating chamber 12 and to the application 30 (e.g., via supply line 38).

For the chilling configuration, having water as the operating liquid 18 in the operating chamber 12, the level of vacuum may be maintained by mechanical pumping and/or, for example, the use of hygroscopic materials, such as but not limited to these two, or similar mechanisms that remove water vapor from the operating chamber 12.

The chilling capacity of the cooling and heating platform 10 is determined primarily by the heat exchanger implementation and the capacity of the cooling and heating platform 10 for removing operating liquid vapor from the operating chamber 12. The platform may be configured to maintain the operating liquid in its liquid state in order to maximize the mixing effect of boiling, but configurations cause the operating liquid to change state to solid are also possible. Phase change of the subsequent solid form of the operating liquid back to liquid form (melting) and/or vapor (sublimation) may be incorporated into the operation of the platform.

For applications that require higher chilling capacities in bursts, the device may include a thermal battery 16 of additional operating liquid and/or other material(s) with suitable heat capacity that increases the heat capacity of the operating chamber 12 to the level desired to support the thermal load from burst chilling/heating. The normal chilling/heating function of the operating chamber 12 recharges the thermal battery 16 between bursts. The thermal battery may be located within the operating chamber 12 or externally.

The overall device behavior can be controlled with device control system 40 based on inputs from the device or application including, but not limited to, temperature, pressure, flow, and/or other sensors. The device control system 40 can operate attached devices, e.g., pressure management device 32, bypass switch 46, circulating pump 28, and operating liquid supply 22.

Operating chamber 12 is connected to pressure management device 32 through vacuum line 45.

For configurations where the operating chamber 12 is providing cooling, the heating bypass mechanism 46 can direct the application fluid to bypass the operating chamber 12 and pass through a heating element either integrated or external to heating bypass mechanism 46. This permits a single device to support heating and cooling applications separately or cyclically when alternating heating/cooling cycles are desired.

Before continuing, it should be noted that the examples described above for FIG. 1 are for purposes of illustration, and are not intended to be limiting. Other devices and/or device configurations may be utilized to carry out the operations described herein.

The example configuration of the cooling and heating platform 10 shown in FIG. 1 includes a thermally-isolated operating chamber 12. A thermal isolation layer 14 is provided around the operating chamber 12. The operating chamber 12 includes a thermal battery 16, an operating liquid 18, and a heat exchanger 20. The example cooling and heating platform 10 also includes a pressure management device 32 and an operating liquid supply 22.

In addition, the example cooling and heating platform 10 shown in FIG. 1 includes a vapor recovery system 50. The vapor recovery system 50 removes operating liquid 18 from vapor formed in the operating chamber 12 via operating liquid recovery mechanism 52. The operating liquid recovery mechanism 52 may include a mechanism to recycle operating liquid 18 by condensing the removed vapor (e.g., including any baked out of the hygroscopic material). The vapor recovery system 50 also returns the operating liquid 18 to an operating liquid supply 22 for return to the operating chamber 12.

In an example, the vapor removal system 50 includes hygroscopic material for removal of water vapor. Another example is where a vapor removal mechanism utilizes an electrostatic approach, similar to removing particulates from power plant and other exhausts (e.g., where the operating liquid 18 is not water-based).

Various configurations of the cooling and heating platform may permit recharging, reloading, and/or replacing vapor removal material in the vapor removal mechanism 50. The vapor removal material may include hygroscopic materials or their equivalent in non-water based configurations. An example vapor removal mechanism 50 may include the mechanical replacement of a “cartridge” containing the vapor removal material. Another example vapor removal mechanism 50 may include a mechanism to add additional fresh material to the liquid recovery system 52. An example vapor removal mechanism 50 may also include mechanism that seals a cartridge or other container of the liquid recovery system 52 from the operating chamber 12. The vapor removal material may be exposed to the atmosphere and then dried (e.g., via a heater, or some other method that is tailored to the specific material used in the configuration).

The operations shown and described herein are provided to illustrate example implementations. It is noted that the operations are not limited to the ordering shown. Still other operations may also be implemented.

FIG. 2 is diagram 100, illustrating an application configuration of the example cooling and heating platform (e.g., shown in FIG. 1). In this example, the cooling and heating platform is implemented as a cycling chiller/heater platform 110 and can be applied to a physical therapy application 130.

In an example, the physical therapy application 130 may include a therapy wrap (e.g., to be placed on a body, such as an ankle wrap). The cycling chiller/heater platform 110 may be operatively associated with a controller 102 for the therapy wrap. The controller may include control electronics and/or software to implement a thermal control and circulating pump.

The cycling chiller/heater platform 110 may receive feedback 104 from the controller 102. The feedback can be utilized to control temperature to the therapy application 130. Fluid output lines 106a-b deliver the temperature controlled application fluid to the physical therapy application 130 (e.g., the ankle wrap). Fluid return or input lines 108a-b return the application fluid to the chiller platform 110 to maintain the desired temperature.

Of course, the example shown and described with reference to FIG. 2 is only illustrative of an example implementation of the cooling and heating platform disclosed herein. Still other applications 130 are contemplated as being within the scope of this disclosure, whether specifically called out or not, as will be readily understood by those having ordinary skill in the art after becoming familiar with the teachings herein.

It is noted that the examples shown and described are provided for purposes of illustration and are not intended to be limiting. Still other examples are also contemplated.

Claims

1. A cooling and heating platform, comprising: an operating chamber;an operating liquid in the operating chamber, the operating liquid maintaining a desired temperature or a range of temperatures; anda heat exchanger in the operating chamber, the heat exchanger exchanging heat between the operating liquid and an application interface.

2. The cooling and heating platform of claim 1, further comprising an application fluid as the application interface, with the application fluid passing through the heat exchanger to maintain the application fluid at a predetermined temperature or range of temperatures for an application.

3. The cooling and heating platform of claim 1, further comprising an operating chamber that is both pressure isolated and temperature isolated.

4. The cooling and heating platform of claim 1, further comprising a thermal battery in the operating chamber.

5. The cooling and heating platform of claim 1, further comprising a thermal battery that is external to the operating chamber and available to the application interface.

6. The cooling and heating platform of claim 1, wherein the operating chamber is pressure isolated from the ambient environment and/or application.

7. The cooling and heating platform of claim 1, wherein the operating chamber is temperature isolated from the ambient environment and/or application.

8. The cooling and heating platform of claim 1, further comprising a supply for the operating liquid.

9. The cooling and heating platform of claim 1, further comprising at least one sensor for the operating chamber.

10. The cooling and heating platform of claim 1, further comprising a pressure management device to apply a vacuum or overpressure to the operating chamber.

11. The cooling and heating platform of claim 1, further comprising at least one vapor removal mechanism, e.g., hygroscopic material, to remove vapor from the operating chamber.

12. The cooling and heating platform of claim 1, further comprising a circulating pump to move the application fluid between the operating chamber and the application.

13. The cooling and heating platform of claim 1, further comprising a control system to acquire signals from at least one sensor that may be part the device or part of an external application.

14. The cooling and heating platform of claim 1, further comprising a control system to control one or more of the components of the device.

15. The cooling and heating platform of claim 1, further comprising a control system to acquire, display, and store information for later analysis.

16. The cooling and heating platform of claim 1, further comprising a control system that incorporates algorithms to further control and/or optimize the device.

17. The cooling and heating platform of claim 1, further comprising a liquid recovery mechanism to return operating liquid to an operating liquid supply and/or directly to the operating chamber.

18. A system that operates under partial vacuum utilizing hygroscopic materials to remove operating liquid vapor to reduce the absolute pressure in the system in order to maintain, or assist in maintaining, a specified operating liquid temperature or a range of temperatures.

19. The cooling and heating platform of claim 1, further comprising a hygroscopic material to control operating liquid temperature in the operating chamber per claim.

20. A system that operates under partial vacuum utilizing an electrostatic system to remove operating liquid vapor to reduce the absolute pressure in the system in order to maintain, or assist in maintaining, a specified operating liquid temperature or a range of temperatures.

21. The cooling and heating platform of claim 1, further comprising an electrostatic system to control operating liquid temperature in the operating chamber per claim 19.

22. A system that operates under partial vacuum utilizing a condensing Peltier device to remove operating liquid vapor to reduce the absolute pressure in the system in order to maintain, or assist in maintaining, a specified operating liquid temperature or a range of temperatures.

23. The system of claim 22, further comprising a condensing Peltier device to control operating liquid temperature in the operating chamber.

24. The system of claim 22, further comprising a thermal battery in the operating chamber or external to the operating chamber but available to the operating interface.

25. The system of claim 22, further comprising at least one sensor providing data on the platform and/or application.

26. The system of claim 22, further comprising a pressure management device to apply a vacuum and/or overpressure to the operating chamber.

27. The system of claim 22, further comprising a circulating pump to move the application fluid between the operating chamber and the application.

28. The system of claim 22, further comprising control connections to control the pressure management device and liquid recovery based on feedback from at least one sensor on the operating chamber and/or an application.

29. The system of claim 22, further comprising a liquid recovery chamber to return operating liquid to the operating chamber.

30. The system of claim 22, further comprising a mechanism to control absolute total pressure in the operating chamber.

31. A cooling and heating method, comprising: maintaining a desired temperature or range of temperatures of an operating liquid in the operating chamber by managing the absolute pressure in the operating chamber; andexchanging heat between the operating liquid and an application interface to maintain the application interface at a predetermined temperature for an application.