REFRIGERATED DISPLAY CASE AND NIGHT COVER THEREFOR

Abstract

A refrigerated display case 1 of the open front type has a roller mounted night cover 51 formed of flexible material which, in a deployed position, is arranged to close the front opening of the display case. The flexible material of the night cover has a plurality of apertures 54 arranged in a first section 51 that are disposed in an upper 30%-40% of the front opening. The apertures have a constant diameter D, chosen to be a fixed dimension in the range 9 mm-11 mm, that are arranged in a vertical and a horizontal grid. The spacing between the aperture centres in the vertical direction y of the grid is 3D and the spacing between aperture centres in the horizontal direction x of the grid is in the range 2D to 4D, preferably 3D. The specific dimensions of the first section and of the apertures and their grid arrangement is arranged to eliminate hotspots and improve the efficiency of the refrigeration system.

Claims

1. A refrigerated display case having a front opening and a roller mounted night cover formed of flexible material, said night cover being arranged to be in a non-deployed position when the refrigeration display case front opening is to be substantially open, and when in a deployed position said night cover is arranged to substantially close said front opening, said flexible material having a plurality of apertures therein arranged in an upper first section, said first section having a range of heights extending from a top of the display case front opening down to 30%-40% of said front opening, said apertures having a constant diameter D chosen to be a fixed dimension in the range 9 mm-11 mm and being arranged in a vertical and a horizontal grid, the spacing between said aperture centres in the vertical direction of said grid being 3D and the spacing between aperture centres in the horizontal direction of said grid being in the range 2D to 4D, and a lower second section which is unapertured.

2. A refrigerated display case as claimed in claim 1, wherein the apertures are arranged in the night cover to be in an upper one third of the display case opening.

3. A refrigerated display case as claimed in claim 1, wherein the diameter D of the apertures is 10 mm.

4. A refrigerated display case as claimed in claim 1, wherein the spacing of the aperture centres in the horizontal direction of said grid is 3D.

5. A refrigerated display case as claimed in claim 1, wherein the night cover has a further section without apertures extending from a top edge of the first section to 10% of the length of the first and second sections, wherein the further section is wound around said roller.

6. A refrigerated display case as claimed in claim 1, wherein in a manual version of the night cover, the lowermost end thereof is attached to a handle for deploying the night cover.

7. A refrigerated display case as claimed in claim 6, wherein said handle has a hook for securing the night cover to a base of the refrigerated display case.

8. A refrigerated display case as claimed in claim 1, wherein the lowermost end of the night cover forms an envelope within which is located a magnetic strip for securing the night cover when deployed to a base of the refrigerated case.

9. A refrigerated display case as claimed in claim 1, wherein the roller is electrically operated to deploy and rewind the night cover.

10. A night cover for covering an opening in a front of a refrigerated display case, said night cover being made from a flexible material having a height h1, and having a plurality of apertures in an upper first section, said upper first section characterised by having a range of heights a which is 30%-40% of said height h1, said apertures having a constant diameter D chosen to be a fixed dimension in the range 9 mm-11 mm and arranged in a vertical and horizontal grid, the spacing between said aperture centres in the vertical direction of said grid being 3D, and the spacing between aperture centres in the horizontal direction of said grid being chosen to be in the range 2D to 4D, and a lower second section which is unapertured.

11. A night cover as claimed in claim 10, wherein height a is one of one third of h1, 30% of h1, 40% of h1 and 37% of h1.

12. A night cover as claimed in claim 10, wherein the night cover has a further section without apertures extending from a top edge of the first section to 10% of height h1, wherein the further section is arranged to be wound around a roller.

13. A night cover as claimed in claim 10, wherein for a one metre wide night cover the percentage of aperture area to unapertured area ranges between 2.6% for a 450 mm high night cover to 4.2% for a 870 mm high night cover.

Description

[0026] The invention will now be described, by way of example, with reference to the accompanying drawings, in which:

[0027] FIG. 1 shows a perspective view of a known refrigeration display case having a known night cover,

[0028] FIG. 2a shows airflow in a known display case when a night blind is not deployed,

[0029] FIG. 2b shows airflow in a known display case when a known night cover is deployed,

[0030] FIG. 2c shows the airflow of a display case having a night cover in accordance with this invention,

[0031] FIG. 3a shows airflow ingress and leakage of a display case with a known night cover,

[0032] FIG. 3b indicates the spread of hotspots in a known display case with a known night cover,

[0033] FIG. 3c shows products affected by hotspots in a known display case having a known night cover,

[0034] FIG. 4 shows, in graphical form, the effect of hotspots in a known display case having a known night cover, and the reduction in temperature with a night cover in accordance with this invention,

[0035] FIG. 5 shows a perspective view of a refrigerated display case having a night cover in accordance with this invention,

[0036] FIG. 6 shows a night cover in accordance with this invention,

[0037] FIGS. 7a-7d show the apertured to non-apertured proportions of a night cover in accordance with this invention for different display cases,

[0038] FIG. 8 shows, in graphical form, the refrigeration system energy improvement with the night cover of this invention, and

[0039] FIG. 9 shows, in graphical form, the energy demand with no night cover, a known night cover and a night cover in accordance with the invention.

[0040] In the Figures like reference numerals denote like parts.

[0041] FIG. 1 shows a refrigerated display case 1 having a base 2, side walls 3, a rear wall 4, a top cover 5 and adjustably locatable shelves 6 mounted on brackets 7. In the example shown, there are five shelves, but this number will vary upon the requirements of the merchandiser. Also, in the current example, the side wall is shown as being transparent plastics or glass, but may be metal or, if two display cases are joined together, open.

[0042] The display case is provided with a pair of un-perforated night covers 40 which are each mounted on a respective roller having a spring biased mechanism against which the covers may be deployed to a position, as shown in FIG. 1, where a handle 11 used for manual deployment and re-deployment is attached by a hook, not shown, to the base 2 so as to maintain the cover in a deployed position. The display case, when the covers are not deployed, has an aperture height h, known as the throat height of the display case.

[0043] The roller upon which the night cover 10 is wound is secured to the top cover 5 and located behind a valance 8.

[0044] FIG. 2a shows airflow in a known display case having a riser 9 extending from the base 2. Located beneath the lowermost shelf 6 is a refrigeration system 20 comprising a compressor, condenser, and an evaporator, these items not being separately shown. The display case has an open front 21. The refrigeration system produces cooled air which is blown by a fan (not shown) through a channel 22 at the rear of the display case and through apertures in the rear wall 4 to spread over each of the shelves 6, the flow of cooled air being shown by arrow-headed lines 23. The cooled air travels along the underside of the top cover 5 and it is then directed downwardly as an air curtain 24 to the inner side of the riser 9, whereupon the air re-enters the base to be re-cooled by the refrigeration system 20.

[0045] Ambient air 25, shown by arrow-headed broken lines, enters the front of the display case and mixes with, but does not penetrate, the air curtain 24, and a mixture of the cool, heavier, air from the air curtain 24 and the ambient air 25 spills out at the base of the display case over the riser 9.

[0046] When the night cover 40 is deployed, as shown in FIGS. 2b and 3a, it will be understood that because the night cover is not sealed to the display case, so ambient air passes between the upper outer vertical edge of the night cover and the side 4 of the display case and also between a vertical gap between each adjacent night cover 40, as shown by arrow-headed lines 26 in FIG. 3a. Because the ambient air is travelling through a relatively narrow gap of approximately 10 mm between the outer vertical edge of the blind and the display case side and a gap of about 20 mm between adjacent edges of the night covers, so a positive air pressure is formed which, as shown by broken arrow-headed lines 27 in FIG. 2b, penetrates the air curtain to cause hotspots, as will be described herein with reference to FIG. 3b. The ambient air mixed with the air curtain reaches an equilibrium pressure around the centre, height-wise of the display case, and exits around the vertical edges of the night blind through negative pressure and the denser cooled air shown exiting the display case is shown by arrow-headed lines 28 in FIGS. 2b and 3a.

[0047] The effect of the cool air 28 escaping towards the base of the display case results in more warm ambient air being drawn into the gap at the vertical edges of the blind which cause product temperatures to dramatically rise in hotspots. The formation of hotspots is shown in FIG. 3b. A median of the display case throat height is denoted by broken line M, and hotspot areas caused by a conventional night blind, as shown by cross-hatched areas S, increase in width with greater height extending from a point just below the median M. The effect of these hotspots upon products on the shelves within the display case is shown in FIG. 3c, where product 50 is shown stacked on each of the shelves 6 and base 2 and the products 51 affected by the hotspots are shown to increase laterally of the display case with height with the possibility that products in the hotspots may exceed a desired temperature for life expectancy.

[0048] The effect of the known night cover upon temperature within the display case is graphically shown in FIG. 4, which has temperature in degrees C. as an ordinate and an abscissa of time in hours. The time at which the night cover is lowered is indicated by line 41 and the graphical representations are temperatures measured at the second shelf down from the top. Broken line 42 is the temperature measured by a heat probe located at the centre of shelf 2, i.e. between the two adjacent blinds 40;. Broken line 43 is the temperature measured by a heat probe located at the left hand side of shelf 2. Broken line 44 shows the temperature measured by a heat probe on the shelf 2 at the right hand side of shelf 2; changes in temperature over a sixteen-hour period are recorded.

[0049] Referring to FIG. 5, a pair of night covers 50 in accordance with this invention are shown mounted over the open front of a display case 1. The open front of the display case has height h and the night cover of this invention has an uppermost apertured section 51 extending the width of each night cover and to a depth a from the top of the case opening to a distance d, and an unapertured section 52 extending from d to the lowermost part of the opening at the base of a distance u.

[0050] A top plan view of the night cover, before it is wound on a roller, is shown in FIG. 6. In its unwound state from the top of the apertured section 51 to the lowermost end of the night cover is height h1. The length al of the apertured section 51 is in the range 30%-40% of h1, in dependence upon the height of a display case and the size of the front opening of the display case, as will be described later herein with reference to FIG. 7. The distance from distance d of the unapertured section 52 to the lowermost end of the night cover is ul. In general, distance al, in a preferred embodiment, is one third h1, and distance ul is two thirds h1.

[0051] An unapertured section 53 above the apertured section 51 is provided for securement about the roller and the section 53 is denoted by length r which has a length, typically, 0.1 of h1, i.e. approximately 10% of h1. In practice, however, in dependence upon the size of the display case, a portion of the section 51 may also be wrapped around the roller.

[0052] The night cover has a width w.

[0053] In one exemplary embodiment, length r is 150 mm, length a is 870 mm, distance u1 is 1,100 mm so that h1 is 1,970 mm. The lowermost 20 mm of section 53 of the night cover is turned back on itself to form an envelope within which may be located a stiffening strip which, in one embodiment, is a magnetic strip for securing the night cover when deployed to a base of the refrigerated case.

[0054] The apertures 54 are each circular holes which have a constant hole diameter D in the chosen to be in the range 9 mm-11 mm and, preferably, 10 mm The apertures are in a grid and have a hole centre spacing in the vertical direction y of 3D. The spacing between hole centres in the horizontal direction x is in the range 2D to 4D, preferably 3D.

[0055] By way of example, for a one metre wide night cover the percentage of aperture area to unapertured area ranges between 2.6% for a 450 mm high night cover to 4.2% for a 870 mm high night cover, so there is very little wasted material.

[0056] The distances x and y and the hole diameter D are particularly chosen so as not to weaken the night cover and to provide a cover avoiding hotspots. Similarly, the ratio of the apertured section51 to the unapertured section 52 is particularly chosen to provide non-turbulent airflow and to accomplish the avoidance of hotspots. Thus, the dimensions are a particular selection of dimensions.

[0057] FIG. 2c shows the night cover of this invention deployed with the ingress of ambient air shown by broken lines 29 evenly spread through the apertured section 51, lowering the air velocity so it does not penetrate the air curtain and exiting near the base 2.

[0058] FIG. 7 shows various height sizes of display case in which FIG. 7a shows a display case having a height of 2m and the apertured section 51 is 540 mm and the unapertured section 52 is 1,080 mm, giving a one third to two thirds ratio of apertured to unapertured sections.

[0059] FIG. 7b shows another display case having a height of 2 m, but with a front riser 9. In this example, the apertured section 51 has a height of 450 mm and the unapertured section 52 has a height of 1,080 mm, giving a ratio of 30%-70% apertured to unapertured sections.

[0060] FIG. 7c shows a display case having a height of 2.2 m with no riser and the apertured portion extends a distance of 735 mm and the unapertured section extends a distance of 1,080 mm, providing a ratio of apertured to non-apertured sections of about 40% to 60%.

[0061] FIG. 7d shows another display case having a height of 2.2 m with a riser 9. In this example, the apertured section 51 extends a distance of 630 mm and the non-apertured section 52 extends a distance of 1,080 mm, giving a ratio of apertured to non-apertured of approximately one third to two thirds.

[0062] Referring again to FIG. 4, with a night cover in accordance with this invention a heat probe mounted at the centre of shelf 2 at the gap between adjacent night covers 50 recorded a curve as shown by line 47, a heat probe at the left hand side of the night cover recorded a temperature shown by curve 45, and a probe at the right hand side of the night cover recorded a temperature as shown by curve 46. From a comparison of curves 42 and 47, between curves 43 and 45, and between curves 44 and 46, it will be seen that a significant drop in temperature occurred with the night cover of this invention versus the known night cover.

[0063] FIG. 8 shows curves of the energy drawn by the refrigeration system. The cycle is over a period of twenty four hours, with the night cover not deployed for sixteen hours and deployed for eight hours, the time at which the night cover was lowered being denoted by line 80. The power consumption is shown as the ordinate in kWh and the abscissa is time in hours. The known night cover power consumption is denoted by broken line 81 and the power consumption of the present invention is denoted by solid line 82. The power peaks and troughs with the night cover raised is caused by the refrigerator system cycling. It will be noted that with the night cover lowered, the energy consumption shows a difference of approximately 10% improvement.

[0064] The energy demand of the refrigeration system in various circumstances is shown in FIG. 9. The curves shown in FIG. 9 have an ordinate in kW and the abscissa is time in hours. The energy curve of the present invention is shown in section 91, the energy demand without a night cover is shown in section 92, and the energy demand with a known non-apertured night cover is shown in section 93. From these curves, the energy demand of the present invention versus a known night cover is seen to have a mean improvement of 0.25 kW.

[0065] Thus, after several years experimentation, the present inventor has found that a particular aperture shape and size having a particular pitch in the x and y direction and spaced over a particularly defined portion of a night cover regulates and evenly diffuses air ingress to eliminate night hotspots and improve energy demand The elimination of hotspots serves to improve product, e.g. food safety, and eliminate wastage through the temperature of product in a case rising unallowably. Further, by virtue of carefully balancing air ingress into the case when a night cover is deployed, so energy consumption is reduced, making a contribution to the reduction of global warming.

[0066] Thus, the invention, has apertures which are particularly sized and spaced to permit ambient air to flow therethrough to substantially prevent hotspots occurring in the refrigerator display case and which compensate for air lost from the refrigerated display case without breaking through the air curtain in the display case.

[0067] The night cover of this invention has the further advantages that: [0068] It does not require extra parts and so may be readily retro-fitted to all case types. [0069] It is inexpensive to produce. [0070] It requires no changes to existing cases. [0071] It requires no extra staff training.