JPH03117877A - Door structure for refrigerator and refrigerating space - Google Patents

Abstract

PURPOSE: To reduce time required for dissipating mist or frost, by providing a refrigerator having a door structure of two parallel glass panes, of which the glass pane facing a low-temperature refrigerator or freezing space is coated with an infrared-reflective coating on a surface thereof facing cooler space. CONSTITUTION: A door comprises two parallel glass panes 20 and 21. The glass pane 20 is provided with an electrically conductive coating or layer 23 for electrically heating the glass pane 20 at the surface 22 thereof facing away from the warm atmosphere of a shop area. The glass pane 21 facing toward the cooler refrigerator or freezer space is provided with an infrared-reflective coating or layer 25 at the surface 24 facing toward the low-temperature space. The low emissivity of the infrared-reflective coating 25 reduces emission exchange between the inner surface 24 of the inner glass pane 21 and the interior of the refrigerator or the freezer space and articles therein. Heating the inner glass pane is assisted a little by infrared emission incident thereto from the shop area, so that time required for dissipating cloudiness of glass is reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention is particularly suitable for use in refrigerator and freezer-type spaces or rooms of the kind used for displaying perishable fresh foods in the field of household goods. This invention relates to a door structure suitable for.

Such door constructions according to the prior art and technology have two or more root panes, which together with a frame surrounding their edges form a door piece. Merchandise may be viewed through the door, and the door may optionally be opened to allow a customer to remove refrigerated or frozen items from the display position.

When the lungs are Mg1, the door surface facing the cooler storage space has a lower temperature than the door surface facing the warmer store area.

One problem with this type of door is that the outer door surface, i.e. the door surface facing the warm, humid air, is cooled to a temperature below the ambient temperature, so that said door surface is exposed to moisture contained in the store air. fogging occurs on the surface due to condensation. Naturally, such fogging obscures the view available through the door. Another problem is that when the door is open, moisture in the store air condenses on the inside surface of the door, the surface that faces the normally cooler refrigerator or freezer space.

The first of the above problems has been solved by employing a door in the form of a close 1'JI glazing unit having two or three panes of glass. In a sealed glazing unit, the back side of the glazing is coated with a conductive coating that electrically heats it. The hermetically sealed glazing units used in such door constructions typically consist of three panes.

However, the use of sealed glazing units with high thermal insulation capacity creates high temperature gradients across the door, which means that the temperature at the inner door surface becomes very low during use. As a result, fogging occurs on the surface, for example when the door is opened by the customer, and if so, moisture freezes and solidifies on the surface.

After re-closing the door, the moisture or frost will eventually dissipate, as the case may be, due to the low dew point that is present in the refrigerator or freezer space. Since such a refrigerator or freezer space is equipped with a forced convection cooler, the mist and frost will be reduced compared to when no forced convection occurs.
Disappears relatively quickly.

However, the time normally required for complete disappearance of such mist or frost is of relatively long duration. The problem is that the mist can dissipate quickly enough before the door is opened again by the next customer, resulting in further fogging on the door surface, which is repeated one after the other. .

In some cases, these conditions can result in the gradual accumulation of frost or ice on the inside surface of the door.

Often such ° fogging (fogging) of the door surface
As a result of 70 stains, the transparency of the door will be severely impaired or completely lost, and the effectiveness of product display will be seriously compromised.

The decisive factor as to whether a door can consistently escape the formation of mist on its glass surface is the time that elapses between successive openings of the door, so that the mist formed on the glass surface as a result of the opening of the door is Efforts to reduce the time required for the disappearance of the disease are important.

SUMMARY OF THE INVENTION The present invention provides a door structure whereby the time required to clean the inner surface of the door, ie the time required for the mist or frost to dissipate, is significantly reduced. Thus, the present invention allows displayed products to be clearly viewed.

Accordingly, the present invention provides a door structure suitable for use in refrigerator and freezer spaces or rooms of the type used in stores for displaying everyday products, the door structure having two or more panes of glass. , these glass panes cooperate with a frame that completely or partially surrounds their edges to form a door piece, with the root glass facing towards the warm air of the store area generally extending from its surface remote from said store area. provided with an electrically conductive coating or layer for electrically heating the glass sheet. The door structure according to the invention consists simply of two parallel panes of glass, of which the pane facing the colder refrigerator or freezer space allows the infrared anti-coating to pass through to the cooler space. It is characterized by being provided only on the facing surfaces.

The invention will now be explained in detail in connection with an embodiment thereof illustrated in the accompanying drawings, and with reference for comparison to two doors constructed according to the known art. Dew.

Embodiment FIGS. 1-3 are cross-sectional views of a glass door constructed according to the present invention. The term "warm air" seen in the drawings refers to the air present in the shopping area or similar area; the term "cold air" refers to the air present in the refrigerator or freezer compartment; the reference symbols "'T I" and "T2" respectively It means the temperature of the warm air and cold air.

FIG. 2 schematically illustrates a conventional cross-drawn door structure.

In this conventional design, the door consists of three glass panes 1, 2, 3 parallel to each other, the surface 4 of the outer glass pane 1 facing away from the warming space is designed to heat the glass pane 1. A working conductive coating or conductive w45 is placed. A conductive coating or layer 5 is shown with dashed lines.

A door of this construction constitutes an effective means of insulation between the shopping area and the refrigerator or freezer compartment. However, one drawback of this construction of the door is that the effective insulation provided by the door may cause the temperature of the inner surface 10 of the inner glass pane 3 to rise to 70°C or 70°C, as mentioned in the preamble to the text. The temperature is so low as to cause staining (frosting). Actual tests have shown that the temperature of warm air (■
1) is +25℃ and cold air ti!匪(■2) is -2
3°C, the temperature of the inner surface 10 of the inner glass sheet 3 was shown to be -19°C. It is clear that once this door is opened and the surface 10 is exposed to the humid warm air in the store, a mist will rapidly form on the surface of the inner glass pane 3. The temperature of plate glass 3 is -19
Because of the low temperatures, it would take a considerable amount of time, approximately 75 seconds, for the mist to dissipate after the door was closed.

In these tests, the door was held open for approximately 6-8 seconds. This corresponds to the average time that the door is left open when a customer removes an item from the refrigerator or freezer space.

FIG. 3 illustrates another known door construction in which the door has two panes of glass 6.7. In this known door construction, the side of the outer glass pane 6 facing away from the warm shop space is provided with a conductive coating of the same type as described above or with a "4-electrode WI8". The surface facing away from the cold space is provided with an infrared reflective coating 9.

In the case of this door structure, infrared reflective coating 9
prevents radiation incident on the door from the store area from entering the refrigerator or freezer space, and this radiation is reflected towards the store area. Therefore, most of the infrared rays are absorbed by the root glass 6
absorbed by.

In this respect, it differs from the case where no infrared reflective coating is provided. On the other hand, this reduces the mrj
This means that l becomes higher.

Since the insulation provided by a double glazing structure, i.e. against the ingress of heat from store areas, is inferior when compared to a triple glazing structure, the temperature of the inner surface 11 of the inner glazing 7 is lower than that of all other glazings. When compared with a door constructed according to FIG. 2 under similar conditions, the temperature is slightly higher, i.e. -18°C.

It will be appreciated that whether the temperature of the inside surface of the glass sheet is -118C or -19C is of no significant importance. In the case of a door constructed according to FIG. 3, it will take about 70 seconds for the fog to clear from the door again after it has been opened and closed.

The response time interval for a door constructed according to FIG. 2 is, as already mentioned, about 75 seconds.

A door constructed according to the invention has only two mutually parallel glass panes 20,21.

The surface 22 of the glass sheet 20 facing away from the warm air of the store area is provided with an electrically conductive coating or layer 23 which serves to electrically heat the glass sheet 20. Plate glass 21 facing the cooler refrigerator or freezer space
is provided with an infrared reflective coating or layer 25 only on its surface 24 facing the cold space. Such an infrared reflective coating 25 has a relatively low emissivity, for example 0.2.

According to one preferred embodiment of the invention, said infrared reflective coating 25 has an emissivity of less than 0.2, preferably less than or equal to 0.12.

The effect of the present invention is that at the temperatures (1) and (T2), the inner surface 24 of the inner plate glass 21 reaches a temperature (T1) of -15°C, which means that the mist generated on the door exceeds 17i8. This means that it disappears within an elapsed time of about 35 seconds from the point of closure, which is approximately half the time required for doors of known construction.

Said effect is that the low emissivity of the infrared reflective coating 25 prevents the exchange of radiation between the inner surface 24 of the inner glass pane 21 and the interior of the refrigerator or freezer compartment and the items present therein in the case of a door construction according to FIG. This is based on the understanding that in the case of double tones the inner surface 11 of the inner glazing 7 is approximately 0.9
This is because it has an emissivity of . In the case of the previous experiment, the infrared reflective coating had an emissivity of 0.12. Heating of the inner glazing is aided to a small extent by infrared radiation from the store area incident on it.

Therefore, if an infrared reflective coating is applied to the inner surface of the inner glazing according to the invention instead of being applied to the outer surface of the inner glazing according to FIG.
The time required for the glass to defog is reduced from about 70 seconds to about 35 seconds when all conditions are equal.

The invention has been described above in connection with one embodiment thereof. However, it will be appreciated that infrared reflective coatings may more effectively have an emissivity lower than 0.12. As a result of the lower emissivity, the temperature on the inner surface of the inner glass pane is higher.

The invention should not be considered limited to the above-mentioned actual FM example, since modifications thereof are possible within the scope of the claims.

[Brief explanation of the drawing]

FIG. 1 is a sectional view partially showing one embodiment based on the present invention, FIG. 2 is a sectional view partially showing the first embodiment based on the known technology, and FIG. 3 is a sectional view partially showing the first embodiment based on the known technology. FIG. 2 is a cross-sectional view partially showing an embodiment of the invention. On the drawing, 20.21. , root glass, 220. inner surface,
230. Conductive coating, 24° inner surface, 250
．． Infrared reflective coating, (T1) warm air temperature, (T2>. cold air temperature.

Claims (2)

[Claims] (1) A door structure suitable for use in refrigerator and freezer spaces of the type commonly used in household goods stores for displaying merchandise for sale, having two or more panes of glass, and comprising two or more panes of glass, together with a frame which completely or partially surrounds their edges, form a door piece, and furthermore the glass panes facing the warm air of the store area are electrically heated on their surfaces remote from said store area. provided with an effective conductive coating, it is possible to simply attach two parallel panes of glass (20, 2
1), of which the plate glass (21) facing the colder refrigerator and freezer space is provided with an infrared reflective coating (25) only on its surface (24) facing the colder space. A door structure suitable for use in a refrigerator and freezer space characterized by: (2) A door structure according to claim 1, characterized in that the infrared reflective coating (25) has an emissivity of less than 0.2, preferably 0.12 or less. and a door structure suitable for use in a freezer space.