Self-sustainable multiple-tank cooler with energy storage and chamber for temperature compensation

Abstract

Cooler composed by an outer tank, within which a cooling tank and a useful tank are housed, among which there is an array of thermal energy accumulators, and within the tank useful there are temperature compensation chambers.

Claims

1. A self-sustaining cooler of multiple tanks with thermal energy storage comprising: an outer tank within which a cooling tank and a useful tank are housed, where each tank is spaced with respect to each other, the useful tank being located within the cooling tank and said cooling tank within the outer tank, within the space between the cooling tank and the useful tank there is an array of thermal energy accumulators, said thermal energy accumulators being interconnected with each other and in contact with inner faces of the cooling tank and outer faces of the useful tank, wherein in the space between the cooling tank and the outer tank there is a thermal insulator, wherein an evaporator is formed by tubes which are in contact and distributed on outer faces of the cooling tank, where the evaporator tubes are covered and remain in contact with an aluminum layer which also contacts the outer faces of the cooling tank, wherein the useful tank comprises temperature compensation chambers and which are adjacent to anti-freezing spacers, wherein a lower anti-freezing spacer is aligned to a lower inner face of the useful tank, separated a distance and in proximity to each of four vertical inner faces of the useful tank, lateral anti-freezing spacers, located parallel to said walls and separated by a distance, said lower anti-freezing spacer and lateral anti-freezing spacers defining through holes; wherein at the lower part of the outer tank a machinery chamber, wherein a compressor, a continuous electric charge accumulator, a condenser, and a fan, are housed inside; wherein the useful tank comprises an array of LED lights located at an upper edge of a rear wall of the useful tank and connected to the electric charge accumulator; wherein at the top of the three tanks there is an upper cover having a pyrolytic film on an inner face of the upper cover; and wherein an electronic temperature controller is located inside a groove contained in the body of the outer tank.

2. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the evaporator tubes are arranged parallel to one another and longitudinally in vertical position on lateral outer faces of the cooling tank.

3. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 2, wherein the evaporator is formed by copper, steel or aluminum pipe.

4. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the cooler has a rectangular parallelepiped shape.

5. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the cover is hinged, manual sliding, or automatic sliding.

6. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the outer tank has wheels at the lower base.

7. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the outer tank is made of caliber 26 galvanized sheet, caliber, having an inner surface and an outer surface painted with expanded polyurethane.

8. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the cooling tank contains upper panels.

9. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the electronic temperature control has a temperature sensor placed inside the body of the outer tank.

10. The self-sustaining cooler of multiple tanks with thermal energy storage according to claim 1, wherein the thermal energy accumulators comprise a plastic container, preferably injected ABS, containing a eutectic solution therein with a glycol mixture.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 depicts an elevational view of the cooler and its main components.

(2) FIG. 2 depicts an elevational view of the array of the tanks comprising the cooler.

(3) FIG. 3 depicts a detail of the array of eutectic plates.

(4) FIG. 4 depicts an isometric view of the cooling tank (3) and the array of the evaporator tubes (6).

(5) FIG. 5 depicts a detail of the array of the cooling tank (3) and the evaporator tubes (6), the thermal energy accumulators (5) and the aluminum layer (39).

(6) FIG. 6 depicts a detail of the cooling tank (3) and the temperature compensation chambers (34) and (35).

(7) FIG. 7 depicts an isometric view of a lower anti freezing spacer (11) and the through holes (23).

(8) FIG. 8 depicts an isometric view of the useful tank (4) detailing additional components.

(9) FIG. 9 depicts an isometric view of the outer body or cabinet (2) and the useful tank (4).

(10) FIG. 10 depicts an isometric view of the sections (72), (73), (74) comprising the evaporator (6).

(11) FIG. 11 depicts an isometric view of the array of the thermal energy accumulators (5).

DETAILED DESCRIPTION OF THE INVENTION

(12) In accordance with FIGS. 1 and 2, the present invention discloses a self-sustaining multi-tank cooler (1) consisting of an outer tank or cabinet (2), into which a cooling tank (3) and a useful tank (4) are housed. Each tank is open at its top and spaced with respect to each other, that is, they are not in contact with the useful tank (4) being located inside the cooling tank (3), and said cooling tank (3) inside the outer tank (2).

(13) Inside the space between the cooling tank (3) and the useful tank (4) an array of thermal energy accumulators (5) is housed, forming a thermal wall in contact with the inner faces of the cooling tank (3) and the outer faces of the useful tank (4), thereby totally or partially covering said faces, as can be seen in FIGS. 1, 3 and 11.

(14) In all the space between the cooling tank (3) and the outer tank (2) a thermal insulator (30) is located, said insulator being an element of low thermal energy conductivity.

(15) It is an important part of the self-sustaining cooler of multiple tanks (1) of the present invention, an evaporator (6) formed by copper tubing, which is in contact and distributed over all the outer faces (7) of the cooling tank (3). On said outer faces (9), (10), (36), (37), the evaporator tubes (6) are arranged parallel to each other, forming a coil located longitudinally in a vertical position, such as it is shown in FIG. 4. In a preferred embodiment, as shown in FIG. 10, the evaporator (6) is comprised of different sections (72), (73), (74).

(16) An aluminum layer (39) covers and remains in contact with the evaporator tubes, said layer also contacts with the outer faces of the cooling tank (3).

(17) The useful tank (4) has anti-freezing spacers, wherein a lower anti-freezing spacer (11) is located in a parallel manner and near the lower inner face (12) of the useful tank, which while separated a distance (13) became the boundary of a temperature compensation chamber (34). In a similar manner, the useful tank (4) has in proximity to each of its four vertical inner faces (14), (15), (16), and (17) lateral anti-freezing spacers (18), (19), (20), and (21), correspondingly, located parallel to said walls and separated by a distance (27), generating the temperature compensation side chambers (35). The lower anti-freezing spacer (11), as well as the lateral spacers (18), (19), (20) and (21), contain through holes (23), distributed throughout the entire surface thereof, as shown in FIGS. 6 and 7.

(18) The self-sustaining multi-tank cooler (1) of the present invention contains in the lower part of the outer tank (2) a machinery chamber (24), wherein a compressor (25), a continuous electric charge accumulator (26), an electric charger (75), a condenser, and a fan (38), are housed inside.

(19) The useful tank comprises an array of LED lights (65) located at the upper periphery (32) of the rear wall (54) of the useful tank (4) connected to the continuous electric charge accumulator (26).

(20) In the upper part of the self-sustaining multi-tank cooler (1), a sliding upper cover (28) is located, which closes the cooler. Said upper cover being a set of glass slide caps, coated on its inner faces with a pyrolytic film (29).

(21) In the preferred embodiment, the self-sustaining multi-tank cooler (1) has a substantially rectangular parallelepiped shape, defined in this way by the outer tank (2) and the useful tank (4) which contains inside a cold chamber (8).

(22) Additionally, as shown in FIGS. 1 and 2, the outer tank (2) can have on its lower base portability means (76) to facilitate the transport of the cooler (1) of the present invention. Preferably, the portability means (76) are wheels, but other known elements that facilitate their transport can be used.

(23) In addition, FIG. 9 shows that the outer tank (2) has a groove (42) on either side thereof to house a dual temperature electronic control (43).

(24) The outer tank (2) is made of galvanized sheet, preferably caliber 26, having an inner surface and an outer surface painted with insulation by expanded polyurethane. Moreover, the present invention also contemplates the possibility that each wall of the outer tank (2) can have a double bottom that creates one or more intermediate wall cavities. In a preferred embodiment, the outer tank (2) also has moldings in corners and ridges, as well as insulating elements for a suitable finish of said tank.

(25) Preferably, the self-sustaining cooler of multiple tanks of the preferred embodiment illustrated, includes a ⅓ hp compressor at 115 V cooled with R134a gas, a 9 Watt fan motor at 115 V, a 8″ blade, a 10×10 spiral type condenser of 6-stages, and a copper contact evaporator, for example of 40 m.

(26) The cooling tank (3) has at least one cable cover for mounting electrical elements to some useful operation of self-sustaining multi-tank cooler (1).

(27) By way of example, in the preferred embodiment illustrated in FIG. 10, the evaporator (6) consists of different inter connected segments, such as the sections (72), (73), (74).

(28) In a preferred embodiment, the cooling tank (3) has profiles that allow to hold upper panels (82), (83), (84), (85).

(29) Moreover, the walls (52), (53), (54), (55) of the useful tank (4) have upper tabs (57), (58), (59), (60), for an adequate finishing of said useful tank (4), which allow to define the space between the cooling tank (3) and the useful tank (4). The useful tank has on its inner faces some leveling profiles (66) to divide the cold chamber (8) into one or more levels, to allow the accommodation of various products.

(30) Each thermal energy accumulator (5) comprises a plastic container, preferably ABS injected, which contains a eutectic solution therein with a melting point of −5° C. The eutectic solution of the thermal energy accumulator (5) is a glycol mixture.

(31) In accordance with FIG. 11, the distribution of the thermal energy accumulators (5) is defined by a front array (67), a first lateral array (68), a rear array (70), a second lateral array (69) and a bottom array (71). By way of example, for explanatory and non-limiting purposes, the front array (67) consists of nine accumulators (5), the lateral arrays (68) and (69) consisting of five accumulators (5), the rear array (70) consisting of thirteen accumulators (5) and the bottom array (71) consists of twelve accumulators. The configuration of the thermal energy accumulators (5) is in function of various factors, such as the operating temperature, the dimensions of the cooler, the type of products to be cooled, size and shape of the walls and bottom of the cooling tank (3), size and shape of the thermal energy accumulators (5), type of eutectic solution, capacity and components of the refrigeration system, heat transfer desired, type of intended use, outdoor climate, among others.

(32) Another of the most relevant aspects of the invention is illustrated in FIG. 9 and is an electronic temperature control (43). In the preferred embodiment of the invention, the electronic temperature control (43) controls the components of the refrigeration system to preferably provide an operating mode at an average temperature of 2 to 5° C. and an operating mode at freezing temperature of −5° C. Preferably, the electronic temperature control (43) has a selection element that allows the operating temperature to be defined, as well as one or more light elements indicating which type of temperature is operating the self-sustaining multi-tank cooler (1). In addition, the electronic temperature control (43) has the function of controlling the elements of the refrigeration system when said system is connected and operating. A temperature sensor positioned inside the cabinet body for measuring the temperature of the interior wall of the cabinet, not the internal air, whereby the electronic temperature control (43) sends a start signal to the compressor, so that it starts the refrigeration system. Finally, it should be understood within the scope of the present invention that the cooler (1) is adaptable to two or more operating temperatures, as defined and configured to the sensors and to the electronic temperature control.

(33) By way of example, for explanatory and non-limiting purposes, in the preferred embodiment of the invention, when the cooler (1) operates at medium temperature, the electronic temperature control (43) will stop the compressor once the sensor measures the temperature in the interior wall of the cabinet is 0° C.; and when the self-sustaining cooler (1) operates at freezing temperature, the electronic temperature control (43) will stop the compressor once the sensor measures the temperature in the interior wall of the cabinet is −5° C. For example, the temperature of the products in the geometric center of the cold chamber (8) will be between 2 and 4° C., with a lower temperature effect as the products are closer to the walls and/or the bottom, as well as of higher temperature as the products are closer to the upper door and further away from the walls, which tend to have up to 1° C. between the geometric center and the points farther away from it. In an alternative embodiment, the cooler (1) of the present invention may include an internal fan that homogenize the air and hence the temperature. For example, during the use of an embodiment of the invention, in the mode of operation at medium temperature, the product introduced into the cooler (1) with an average cold chain of 5° C. is placed in metal baskets (not shown) with an average spacing of 5 cm from the inner and bottom walls of the cold chamber, performing a thermal balance that maintains the product without reaching a freezing point that damages its characteristics and maintains the temperature defined between 2 to 5° C.

(34) By way of example, during the use of an embodiment of the invention, in the mode of operation at freezing temperature, it is recommended not to place product into the interior of equipment, until the eutectic plates reach a freezing point of a “full charge”, the freezing process of the thermal energy accumulators in a freezing temperature operating mode has a duration of between 8 and 10 hours, said accumulators thereafter arriving at their full charge freezing point. With the thermal energy accumulators charged, the system maintains a temperature at the point below the geometric center of the cabinet, contacting the bottom sheet at this point between −2 and 0° C. without the need for turning on the compressor, this enables the equipment to be completely disconnected from the power source which feeds the compressor and other elements of the refrigeration system.

(35) For example, when the thermal energy accumulators are in the full charge state described above, the self-sustaining cooler (1) supports continuous usage to operate in medium temperature 2 to 5° C. for 8 continuous hours (for example, at ambient conditions of 25° C. with a maximum humidity of 65%), allowing for these 8 hours of continuous usage up to 10 openings per hour of the upper doors. Thus, the product will maintain its average temperature of 2 to 5°° C. due to the thermal load that the thermal energy accumulators exert on the product.

(36) One of the additional advantages of the self-sustaining multi-tank cooler (1) of the present invention is that the self-sustaining cooler (1) can be moved or transported during these 8 hours without changes in position affecting the preservation performance of the products placed inside, considering that the conditions discussed in this example are maintained. Once the 8 hours have elapsed, the self-sustaining cooler (1) can be connected at any of the defined operating temperatures, either maintaining in medium temperature with product or restarting the charge operation of eutectic plates at the freezing temperature.

(37) As will be understood by a skilled person in the art, it should be considered within the scope of the present invention, applying the same essential technical elements to all types of refrigeration device and equipment, for example, vertical refrigerators, buildings with cold chambers, freezing stores, cooling vehicles with cold chamber, among many others, as well as with shapes other than that of a rectangular parallelepiped. Likewise, the teachings of the present self-sustaining multi-tank cooler (1) are equally applicable to other commercial household uses, for laboratories, among others, where they will be adaptable to one or more operating temperatures required for those uses.