RU2426959C2 - Device for reducing frost deposition in refrigerator - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: freezer resistant to frost formation includes freezing chamber, door, cooler and drier. Cooler dries the air inside cooling chamber from the first temperature inside this chamber immediately after closing the door to the second constant temperature during cooling period. Drier is arranged inside freezing chamber and chosen for absorption of moisture from freezing chamber with the speed which is enough for decreasing the relative humidity inside freezing chamber to the value which is sufficiently low to prevent frost formation inside freezing chamber at constant temperature. In control method of frost formation in refrigerator the air is cooled inside freezing chamber to constant temperature at the first relative humidity. Warm air and moisture is admitted to freezing chamber. Air is cooled again inside freezing chamber to constant temperature. At the same time, air relative humidity is decreased inside freezing chamber.

EFFECT: avoiding extra power consumption and related costs.

22 cl, 6 tbl

Description

Cross reference to related applications

This application claims priority for provisional patent application US No. 60/795638, entitled "Device to reduce the deposition of frost in the freezer."

BACKGROUND OF THE INVENTION

The present invention relates to reducing humidity in a confined space. More specifically, the invention relates to a method and apparatus for significantly reducing the deposition of hoarfrost on the inner surface of the freezer and on its contents and for removing hoarfrost in case of its deposition.

Rising frost over time in the freezer is a known inconvenience. Over time, more and more frost is deposited on the inner surfaces of the freezer and on its contents, which significantly reduces the usable space inside the freezer. In addition, the frost in the freezer also tends to cause a loss of flavor or aroma in the food product and may discolor some food products. Thus, users are willing to take on the function of removing hoarfrost deposits from the freezer, using methods such as placing hot objects in the freezer, breaking off ice with a spatula, etc. However, after the frost is removed, the problem remains unresolved, because the frost will be delayed again over time, so a repeat of the frost removal process will be required.

Besides the inconveniences described above, the presence of frost in the freezer may also have additional more harmful effects on the freezer. Over time, as hoarfrost is deposited, the air access openings may become clogged, which imposes an additional load on the compressor and the freezer mechanism as a whole. This leads to additional energy consumption, inefficiency and possible malfunctions. If even a greater deposition of hoarfrost is allowed, then there is a risk of a deficiency in the fact that the hoarfrost can actually penetrate the mechanical parts of the freezer, eventually leading to malfunctions. In each of these cases, the end result is at least excessive electricity bills, costly repairs, or the replacement of the entire freezer.

In the freezer, frost is formed for two main reasons. The first reason frost is formed in the freezer is the opening of the freezer. When the freezer is opened, relatively warm, moist air from the outside environment tends to enter the freezer. If there is a sharp temperature difference between the inside of the freezer and the surrounding air, the moisture present in the outside air will quickly condense into fog as the air cools. When the freezer is closed, the fog has no possibility of removal and slowly settles on any available surface, eventually accumulating and forming a layer of ice or hoarfrost.

The second reason for the formation of frost is sublimation. When foods, including ice cubes, etc., are placed in the freezer, moisture is usually sublimated from these products and freezes again in the form of hoarfrost on other surfaces of the freezer or on its contents.

Deposition of hoarfrost in freezers is a known problem, and there are currently two generally accepted methods for removing hoarfrost from a freezer. However, none of them is particularly effective.

The first way to remove frost from the freezer is the traditional way, which involves removing all the contents from the freezer, turning off the device, and allowing the ice to melt. With this method, it is possible to further contribute to the melting of the ice using a heating means, for example warm water, an electric frying pan, and the like. This method, of course, is not ideal, because it requires extracting the contents from the freezer and re-placing it in the refrigerator until it has thawed. In addition, this method requires an excessive amount of time.

Another method of removing frost from a freezer is usually carried out inside freezers, known as "frost-free" freezers. With this method used in such freezers, the temperature inside the freezer actually rises in a predetermined period of time: for either melting or sublimation of hoarfrost deposited in the freezer. Although this method is somewhat effective, it still requires the installation of additional complex mechanical parts in the freezer. It can increase the total cost of buying and repairing a freezer. In addition, this method requires additional energy due to the necessary heating cycles.

From the foregoing, it should be apparent that there is a need in the art for a method and apparatus for reducing frost deposits in a freezer. The method and device should require minimal user interaction. In addition, there is a need in the art for a method and apparatus for reducing frost deposits in a freezer without additional energy consumption and associated costs.

SUMMARY OF THE INVENTION

The present invention addresses the aforementioned technical needs by providing a device and method for reducing frost deposits in a freezer using a desiccant.

According to one aspect of the present invention, a frost-resistant freezer includes a freezer, a door, a cooler and a dehumidifier. The freezer has a volume. A door provides access to the freezer. The cooler cools the air inside the freezer from the first temperature inside the chamber immediately after closing the door to a second constant temperature during the cooling period. A desiccant is located in the freezer and is selected to absorb moisture from the freezer at a speed that is sufficient to reduce the relative humidity inside the freezer to a value low enough to substantially prevent frost accumulation inside the freezer at a constant temperature.

According to another aspect of the present invention, a method of controlling frost deposits in a freezer having a freezer and a cooler for cooling the air inside the freezer to a constant temperature, includes cooling the air inside the freezer to a constant temperature at a first relative humidity, inlet of warm air and moisture to the freezer chamber and re-cooling the air inside the freezer to a constant temperature, while reducing the relative humidity inside the freezer.

In order to understand these and other features of the invention, the accompanying drawings and the following description may be made, in which the present invention is illustrated and described.

Brief Description of the Drawings

Figure 1 is a perspective view of a preferred embodiment of a freezer according to the present invention,

figure 2 is a graph of the relationship between adsorbed moisture and time for various dehumidifiers according to preferred variants of the invention, and

figure 3 is a graph of the relationship between adsorbed moisture and time for additional dehumidifiers according to additional preferred variants of the invention.

DETAILED DESCRIPTION OF THE INVENTION

Preferred embodiments of the invention will now be described with reference to the accompanying drawings, if necessary.

As described in more detail above, hoarfrost deposits in freezers pose a problem. As shown in figure 1, the freezer 2, in General, contains a chamber 4, which stores food products and the like, and a cooling device 6 in communication with the chamber 4 to lower the temperature in the freezer 4 and maintain it at a constant level essentially equal to or below freezing temperature. Typically, the chamber is substantially isolated from the external environment. However, when access is made to the chamber, for example, by opening the door 8 of freezer 2, this insulation is violated, and relatively warm, moist air rushes into the chamber, displacing part of the air that previously filled the chamber. This relatively warmer air causes fogging and at the same time raises the temperature in the chamber 4, so that when the refrigeration chamber is re-insulated, the cooling device 6 must lower the temperature in the chamber. As the temperature inside the freezer 2 decreases, the relative humidity of the air rises, and if the air becomes saturated, frost is formed on the inner surfaces of the freezer 2 and / or on the products contained therein.

The inventors have developed a method of reducing frost deposits in a freezer. Specifically, as the inventors have established, when the bag 10 with the desiccant is placed inside the freezer, moisture inside the freezer can be adsorbed and / or absorbed before it precipitates in the form of hoarfrost. Specifically, the desiccant preferably maintains the relative humidity in the freezer below 100% for the time that the cooling device requires to return the temperature in the chamber to a constant temperature. In addition, a properly selected dehumidifier can lower the relative humidity inside the freezer to facilitate sublimation of the frost already in the freezer. Sublimation of ice usually occurs when the freezer is closed for a short period of time. After sublimation, the resulting moisture is adsorbed / absorbed by the desiccant composition.

In a preferred embodiment, the desiccant is packaged, such as a bag or sachet. The package is moisture permeable, so that the surrounding moisture in the freezer can pass through the package and be captured by the desiccant.

The desiccant package of the present invention preferably contains an adsorbent, which may be from any number of adsorbents, including clay, activated clay, silica gel with wide pores or pores of a standard size, salt or molecular sieve.

Tables 1 and 2 show the absorption rates of various formulations versus time according to the tests carried out by the inventors. In Table 1, composition 1 is clay, and 1 (A) and 1 (B) denote two different packages with this composition; composition 2 is silica gel, and 2 (A) and 2 (B) denote two different packages with this composition; composition 3 is Transorb® (registered trademark), and 3 (A) and 3 (B) denote two different packages with this composition; and composition 4 is a molecular sieve, and 4 (A) and 4 (B) denote two different packages with this composition. Table 2 was used to show the fifth composition containing 16 unit wide pore silica gel. In this table, 5 (A) denotes the fifth composition, while 5 (B) denotes the 16 unit silica gel provided for comparison.

In these tests, a standard top single freezer was used having an average temperature of 0 ° F (-18 ° C). The external environment had an average temperature of 77 ° F (25 ° C) and a relative humidity of 50%. For each of the tests shown, dehumidifiers were first weighed and then placed in a freezer. They were then weighed periodically to determine how much moisture the desiccant absorbed. On the "days of weighing", i.e. on the days on which the packages with the desiccant were weighed, the freezer door was opened eight times, each time for three seconds. On other days, when the weighing was not carried out, the door was opened three times, each time for three seconds. According to the inventors, when opening the freezer, about 500 mg of moisture is introduced each time.

Figure 2 graphically presents the data contained in Table 1, and figure 3 graphically presents the data contained in Table 3. In figure 3, the graph for each of the compositions 1-4 is plotted by the average values for samples (A) and ( B) an appropriate composition.

As shown in Tables 1 and 2 and in FIGS. 2 and 3, the vermiculite gel appears to be most effective in adsorbing moisture in a freezer (i.e. between about 9 ° F (-13 ° C) and - 5 ° F (-21 ° C)). In addition, the vermiculite gel continued to adsorb moisture for the longest period of time. Among the standard and wide pore silica gels tested, standard pore silica gels are likely to be more adsorptive over at least the 77-day test period, as shown in the Table and figure 2.

Table 3 is similar to Table 2, but shows the absorption of moisture by the sixth composition containing 8-unit wide-pore silica gel on potassium chloride. In Table 3, this composition is indicated as 6 (A), while 6 (B) is an 8 unit silica gel provided for comparison.

Other compositions may also be used according to the present invention to reduce frost deposits in the freezer. Such alternative compositions may include a hygroscopic salt, such as, for example, calcium chloride. The absorbent can be mixed with or saturated with such a salt. In addition, according to embodiments of the invention, stabilizers can be added to the absorbent, such as vermiculite or cellulosic materials. Such stabilizers would retain any excess material that could be converted into a stable solution. Any combination of salt and stabilizers and all such combinations may be used.

In addition, additional additives may be used to achieve various results. For example, a binder and resins may be added to facilitate molding, casting, or otherwise shaping the material. Deodorizing or flavoring sorbents may also be used. In addition, if it is necessary to regulate the environment, substances can also be added that absorb or emit oxygen or carbon dioxide and do not unduly harm the effectiveness of the invention.

The inventors also tested other compositions, some of which contained the numerous additives described above. Table 4 contains a list of the tested compositions (including compositions 1-5 already described above).

Table 4
Desiccant compositions for use in reducing frost in a refrigerator No. p \ p Composition one Clay 2 Silica gel 3 Transorb (trademark) (vermiculite and calcium chloride) four Molecular sieve 5 Wide pore silica gel 6 Dried Potassium Chloride 7 Solka-Floc (trademark) 20 FCC and calcium chloride, 52% 8 Solka-Floc 20 FCC and Calcium Chloride 2: 1 9 Wide-pore silica gel and calcium chloride 2: 1 10 Wide Pore Silica Gel Calcium Chloride Solvent eleven Potassium chloride and wide pore silica gel, 2: 1 12 Solka-Floc 900 FCC and Calcium Chloride 2: 1 13 The composition of claim 8, 52% Solka-Floc and 48% calcium chloride fourteen Solka-Floc 900 FCC 20% and Calcium Chloride 80% fifteen Solka-Floc 20 FCC 66% and Calcium Chloride 33% 16 Solka-Floc 900 FCC 33%, calcium chloride 20%, wide pore silica gel 66% 17 Solka-Floc 900 FCC 20%, calcium chloride 20%, wide pore silica gel 60% eighteen Silica gel 80% and calcium chloride 20% 19 Wide-pore silica gel 80% and calcium chloride 20% twenty Potassium Chloride 20% and Broad Pore Silica Gel 80% 21 Calcium Chloride 20%, Solka-Floc 20% and Silica Gel 60%

Tables 5 and 6 show the test results that were carried out using the compositions set forth in Table 4. Specifically, these tables show the initial weight (in grams) of the desiccant and the subsequent weights of the same desiccant. From these weights, one skilled in the art could easily determine the absorption rate for each composition. In each of the examples in Tables 5 and 6, a standard top unit freezer was used having an average temperature of 0 ° F (-18 ° C), from -5 ° F (-21 ° C) to 9 ° F (-13 ° C). The external environment had an average temperature of 77 ° F (25 ° C) and a relative humidity of 50%. On the days on which the packages with the desiccant were weighed, the freezer door was opened eight times, each time for three seconds. On other days, when the weighing was not carried out, the door was opened three times, each time for three seconds. According to the inventors, when opening the freezer, about 500 mg of moisture is introduced each time.

As shown in the tables, in the same freezer, different compositions will lead to different degrees of moisture adsorption. Currently, the preferred desiccant composition is composition 19, which consists of 80% broad pore silica gel and 20% calcium chloride.

The desiccants of the present invention will preferably adsorb moisture from about 30 days to about 180 days. At the end of the validity period, which can be marked on the package, etc., the dehumidifier is discarded and replaced with a new package. The duration of the desiccant is preferably measured in months, so that the user can easily remember when to replace the desiccant.

In addition, at a relative humidity of about 45% to 55% and a temperature of 5 ° F (-21 ° C) to 9 ° F (-13 ° C), the preferred desiccant will adsorb moisture, preferably in an amount of about 20% to about 50 % of its weight. As shown in the above tables, some of the tested compositions meet these limits.

Desiccant components are preferably contained in the package. The material from which the packaging is made should be easily permeable to surrounding water vapor. Some suitable materials would be any permeable, semi-permeable, microporous or porous non-woven materials or other suitable films. Currently, the preferred material is a porous non-woven material, such as, for example, TYVEK / registered trademark /. In each of the above tests, the composition was placed in a bag of TYVEK. It is easy to understand that the porosity of the package will affect the adsorption capacity of the desiccant composition. In particular, moisture will adsorb more slowly when the pores of the package are comparatively smaller than when the pores are comparatively larger. In the absence of any packaging, the highest adsorption rate will be provided.

The desiccant package of the invention preferably operates in a temperature range of from about -20 ° F (-29 ° C) to about 20 ° F (-7 ° C), although the above packages will also operate in a temperature range of about -40 ° F ( -40 ° C) to about 30 ° F (-1 ° C). Packages are also capable of operating in environments having varying relative humidity ranging from about 20% to about 99%, but they are preferably used at relative humidity from about 45% to about 55%. Depending on the composition used for the desiccant, the package can adsorb moisture for about 30 days to about 270 days. However, the preferred desiccant life is preferably from about 60 days to about 180 days. The life of the desiccant will also vary depending on at least the type of adsorbent or mixture used, the materials used, relative humidity and temperature.

In a preferred method of using a packaging with a desiccant according to the invention, the user acquires the packaging and places it in the freezer. The packaging maintains a non-blue environment in the freezer for the recommended life, and is discarded and replaced at the end of its life.

Several different desiccant compositions have been described above. It is understood that, depending on the desired results, other compositions may be used. For example, another composition may be useful depending on the desired adsorption rate or the desired useful life of the desiccant package. When choosing an effective packaging with a desiccant, all characteristics can be taken into account, including the equilibrium relative humidity of the desiccant, the temperature inside and outside the freezer, and the relative humidity inside and outside the freezer. For example, in some embodiments of the invention, it may be desirable to use a packaging with a desiccant that maintains a relative humidity inside the refrigerator slightly below 100%, for example from 90% to 99%. In this embodiment, the desiccant does not absorb more moisture than is necessary to maintain a non-liner environment. In addition, other embodiments of the invention are contemplated in which it is desirable that the relative humidity in the freezer be significantly reduced, for example, to 40% -50%, to allow faster and / or more efficient sublimation and subsequent absorption of water vapor. In addition, as described above, the composition of the packaging material will also have some significance for the characteristics of the entire packaging with a desiccant.

Although the invention has previously been described as being used in a freezer environment, the invention can also be used in any environment to help reduce condensation or frost on surfaces. For example, the device can also be used in air conditioning ducts, etc.

The absorbent may be in powder form in the package or it may be in some other form. For example, the adsorbent could be molded into a lattice structure, placed in a box, molded into a solid block by a binder, resin or extrusion, molded into a sheet by a binder, resin or extrusion, pressed into any mold, sintered into any mold, molded into any mold, coated with another substance or molded into a corrugated sheet. It is understood that a desiccant molded in some of these methods will not require a sachet, pouch or sachet.

In addition, as the inventors suggest, the freezer could be made with a special holder or slot for packaging with a desiccant. Thus, a packaging with a desiccant according to the invention can be shaped to fit in a holder or slot.

In an alternative embodiment, the desiccant is formed in the form of a plurality of sheets stacked in a stack one above the other. Each sheet preferably has an upper surface having a dehumidifier exposed, and a lower surface located near the upper surface of the next sheet in a stack. When the top sheet reaches the end of its useful life, remove this sheet by opening the next sheet in a bundle, in particular the following desiccant sheets. The removed sheet is preferably discarded. In addition, in this embodiment of the invention, an identifying substance, such as a color changing substance, may be introduced into each sheet to indicate to the user that the exposed sheet has reached the end of its useful life, for example, due to saturation of the desiccant. In addition, in this embodiment, a barrier layer can be placed between the sheets and / or above the top sheet, which can be removed to expose and actuate the underlying desiccant. The lower part of the lowermost sheet also preferably has a releasable adhesive and the like. for attaching the packaging with a desiccant to the inside of the freezer.

The foregoing embodiments of the invention are indicative and are used for illustrative purposes. These options are not intended to limit the scope of the invention. From reading the preceding description, obvious changes and modifications that are within the scope of the invention. As expected, the invention is limited only by the scope of the attached claims.

Claims (22)

1. A freezer that is resistant to hoarfrost and contains:
a freezer having a first volume;
a door to provide access to the freezer;
a chiller for cooling the air inside the freezer from the first temperature inside the chamber immediately after closing the door to a second, constant temperature during the cooling period; a dehumidifier located inside the freezer and selected to absorb moisture from the freezer at a speed sufficient to reduce the relative humidity inside the freezer to a value low enough to prevent frost deposits inside the freezer at a constant temperature. 2. A frost-resistant freezer according to claim 1, wherein the desiccant is selected to maintain relative humidity inside the freezer at a constant temperature near, but not lower than 100%. 3. The frost-resistant freezer according to claim 1, wherein the desiccant is selected to reduce the relative humidity inside the freezer below 100% for the time it takes for the cooler to lower the temperature inside this freezer to a constant temperature. 4. A frost resistant freezer according to claim 2, wherein the desiccant is selected to reduce the relative humidity inside the freezer at a constant temperature to a value that causes sublimation of the frost inside the freezer. 5. The frost-resistant freezer according to claim 1, wherein the desiccant is selected with the ability to absorb moisture sufficient to continue to absorb moisture in quantities sufficient to prevent frost accumulation for a period of at least 30 days. 6. The frost-resistant freezer according to claim 1, wherein the desiccant is selected with the ability to absorb moisture sufficient to continue to absorb moisture in quantities sufficient to prevent frost accumulation for a period of at least 60 days. 7. The frost-resistant freezer according to claim 1, wherein the desiccant is selected with the ability to absorb moisture sufficient to continue to absorb moisture in quantities sufficient to prevent frost accumulation for a period of at least 90 days. 8. The frost-resistant freezer according to claim 1, wherein the desiccant is selected with the ability to absorb moisture sufficient to continue to absorb moisture in quantities sufficient to prevent frost accumulation for a period of at least 120 days. 9. The frost-resistant freezer according to claim 1, wherein the desiccant is selected with the ability to absorb moisture sufficient to be able to continue to absorb moisture in quantities sufficient to prevent frost accumulation for a period of at least 180 days. 10. The frost-resistant freezer according to claim 1, wherein the desiccant is selected to absorb moisture in an amount of from about 20 to about 47% of its weight at a relative humidity of from about 45 to about 55% and a temperature of from about -5 ° F (-21 ° C) to 9 ° F (-13 ° C). 11. A frost-resistant freezer according to claim 10, wherein the desiccant is selected to provide absorption characteristics for from about 60 to about 180 days. 12. A frost-resistant freezer according to claim 10, wherein the desiccant contains silica gel. 13. A frost-resistant freezer according to claim 11, wherein the desiccant comprises a nonwoven polyester package. 14. The frost-resistant freezer according to claim 13, wherein the desiccant contains about 448 g of silica gel. 15. The frost-resistant freezer according to claim 14, wherein the desiccant is selected with the ability to absorb at least about 125 g of moisture in about 234 days. 16. A freezer resistant to hoarfrost, according to claim 1, wherein the desiccant is characterized by an effective relative humidity of more than 50%. 17. A frost-resistant freezer according to claim 1, wherein the desiccant is characterized by an effective relative humidity of more than 75%. 18. A freezer resistant to hoarfrost, according to claim 1, wherein the desiccant is characterized by an effective relative humidity of more than 85%. 19. A method of controlling the deposition of frost in a freezer having a freezer and a cooler for cooling the air inside the freezer to a constant temperature at which
cool the air inside the freezer to a constant temperature at the first relative humidity;
they let warm air and moisture into the freezer and re-cool the air inside the freezer to a constant temperature, while reducing the relative humidity inside the freezer. 20. The method according to claim 19, in which when the relative humidity of the air inside the freezer is reduced, the relative humidity is reduced to a level sufficient to prevent frost accumulation inside the freezer. 21. The method according to claim 19, in which when the relative humidity inside the freezer is reduced, the relative humidity is reduced to a level sufficient to facilitate sublimation inside the freezer. 22. The method according to claim 19, in which, when the relative humidity of the air decreases, a drying material is placed inside the freezer compartment.

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