Refrigerators

Abstract

A refrigerator has an open front and an air curtain system having at least one upper air egress with an outer edge and at least one lower air-recovery ingress. The air curtain system is adapted to produce a substantially vertical air curtain over at least part of the open front of the refrigerator. The refrigerator comprises at least one shelf between the egress and the ingress, the shelf having a front edge, and at least one elongate air-guiding strip extending across at least part of the open front of the fridge. The strip is located substantially in the plane of the shelf and spaced from the front edge of the shelf. The strip is located substantially vertically beneath the outer edge of the upper air egress.

Claims

1. A refrigerator, comprising: a body defining a storage space and an open front, the open front providing access to the storage space; an air curtain system including an air egress having an outer edge, the air curtain system configured to produce an air curtain over at least part of the open front in a direction; a plurality of shelves disposed within the storage space, each shelf from the plurality of shelves having a front edge disposed on a first side of the air curtain; and a plurality of asymmetrical airfoils, each airfoil from the plurality of airfoils having a pressure surface having a first camber facing the storage space and a curved suction surface having a second camber that is greater than the first camber opposite the pressure surface, each airfoil having a chord line substantially aligned with the direction of the air curtain; each airfoil from the plurality of airfoils coupled to and spaced from a shelf from the plurality of shelves such that at least a portion of the pressure surface of that airfoil is in a plane defined by that shelf and extending across at least part of the open front at least partially on a second side of the air curtain such that at least a portion of the air curtain is disposed between the front edge of that shelf and the pressure surface of that airfoil; an upper edge of each airfoil from the plurality of airfoils located vertically beneath the outer edge of the air egress; the pressure surface and the curved suction surface of each airfoil from the plurality of airfoils are collectively configured to create a pressure differential between a first portion of the air curtain located between the pressure surface and the storage space and a second portion of the air curtain located across the each airfoil opposite the first portion of the air curtain to stabilize a flow of the air curtain and straighten the flow of the air curtain towards vertical.

2. The refrigerator of claim 1, wherein a line drawn vertically from the outer edge of the air egress intersects the pressure surface of each airfoil from the plurality of airfoils.

3. The refrigerator of claim 1, wherein a line drawn vertically from the outer edge of the air egress intersects the upper edge of each airfoil from the plurality of airfoils.

4. The refrigerator of claim 1, wherein an airfoil from the plurality of airfoils extends across an entire width of a shelf from the plurality of shelves to which that airfoil is coupled.

5. The refrigerator of claim 1, wherein an airfoil from the plurality of airfoils extends across an entire width of the open front.

6. The refrigerator of claim 1, wherein: a first airfoil from the plurality of airfoils is coupled to a first shelf from the plurality of shelves; and a second airfoil from the plurality of airfoils is coupled to a second shelf from the plurality of shelves, the first shelf, the second shelf, the first airfoil, and the second airfoil collectively define an open vertical passageway, the air curtain flowing vertically through the open vertical passageway, the first airfoil and the second airfoil each configures to guide air that is moving out of the open vertical passageway back into the open vertical passageway without projecting into the open vertical passageway of the air curtain.

7. The refrigerator of claim 1, wherein a first airfoil from the plurality of airfoils is attached to at least one of a ticket strip or a support for the ticket strip located at a front edge of a first shelf from the plurality of shelves to which the first airfoil is coupled.

8. The refrigerator of claim 1, wherein a first airfoil from the plurality of airfoils is coupled to a first shelf from the plurality of shelves via a bracket, the bracket configured to space the first airfoil apart from the front edge of the first shelf.

9. The refrigerator of claim 1, further comprising a plurality of brackets, each bracket from the plurality of brackets coupling an airfoil from the plurality of airfoils to a shelf from the plurality of shelves.

10. The refrigerator of claim 1, wherein a portion of an airfoil from the plurality of airfoils is transparent.

11. The refrigerator of claim 1, wherein an airfoil from the plurality of airfoils includes a housing configured to contain a product label.

12. The refrigerator of claim 1, wherein an airfoil from the plurality of airfoils includes a backing portion and a front portion.

13. The refrigerator of claim 12, wherein the backing portion is formed of metal.

14. The refrigerator of claim 12, wherein the front portion is formed of a transparent plastic material.

15. The refrigerator of claim 1, wherein an airfoil from the plurality of airfoils includes an electronic display.

16. The refrigerator of claim 1, wherein the plurality of shelves includes an upper shelf and a lower shelf, the refrigerator further comprising: a product label coupled to a first airfoil from the plurality of airfoils that is coupled to the upper shelf; and a second airfoil from the plurality of airfoils coupled to the lower shelf, no product label coupled to the second airfoil.

17. The refrigerator of claim 16, wherein a portion of the second airfoil is transparent.

18. The refrigerator of claim 1, wherein an airfoil from the plurality of airfoils has a thickness that increased from a leading edge of the airfoil to a point of maximum thickness and decreases from the point of maximum thickness to a trailing edge of the airfoil.

19. The refrigerator of claim 1, wherein: a first subset of the plurality of airfoils has a backing portion and a front portion, the front portion being transparent and configured to display a product label; a second subset of the plurality of airfoils has monolithic plastic airfoils.

20. The refrigerator of claim 19, wherein the first subset of the plurality of airfoils are disposed above the second subset of the plurality of airfoils.

21. The refrigerator of claim 1, wherein a first airfoil from the plurality of airfoils includes a body portion and an elastomeric flexible cover configured releasably retain a product label.

22. The refrigerator of claim 1, wherein each airfoil from the plurality of airfoils has a height between 35 mm and 50 mm.

23. The refrigerator of claim 1, wherein each airfoil from the plurality of airfoils has a height between 40 mm and 45 mm.

24. The refrigerator of claim 1, wherein an airfoil from the plurality of airfoils has a curved pressure surface.

25. The refrigerator of claim 1, wherein each airfoil from the plurality of airfoils has a height between 25 mm and 60 mm.

26. A refrigerator, comprising: a body defining a storage space and an open front, the open front providing access to the storage space; an air curtain system including an air egress having an outer edge and an air-recovery ingress, the air curtain system configured to produce an air curtain over at least part of the open front in a direction; a shelf disposed between the air egress and the air-recovery ingress, the shelf having a front edge; and an airfoil spaced from the front edge of the shelf having a chord line substantially aligned with the direction of the air curtain, a curved suction surface having a first camber, and a pressure surface opposite the curved suction surface and facing the storage space and having a second camber that is less than the first camber exposed to the air curtain, the airfoil having a thickness that increases from a leading edge of the airfoil to a point of maximum thickness and decreases from the point of maximum thickness to a trailing edge of the airfoil, the airfoil associated with the shelf and extending across an entire width of the open front, the pressure surface and the curved suction surface of the airfoil are collectively configured to create a pressure differential between a first portion of the air curtain located between the storage space and a second portion of the air curtain located across the airfoil opposite the first portion of the air curtain to stabilize a flow of the air curtain and guide air when the air is moving out of a stream of the air curtain back into the stream.

27. The refrigerator of claim 26, wherein the airfoil is coupled to the shelf.

28. The refrigerator of claim 26, further comprising a bracket coupling the airfoil to the shelf.

29. The refrigerator of claim 26, wherein the shelf is from a plurality of shelves.

30. The refrigerator of claim 26, further comprising a transparent elastomeric flexible cover coupled to the airfoil, the transparent elastomeric flexible cover configured to releasably retain a product label.

Description

(1) In order that the invention may be more fully understood a specific embodiment will now be described. In the drawings, like reference characters refer to parts throughout the views, in which, of which:

BRIEF DESCRIPTION OF THE DRAWINGS

(2) FIG. 1 is a schematic cross-section of a standard prior-art open-fronted refrigeration unit;

(3) FIG. 2 is a schematic cross-section of the refrigerator of FIG. 1 adapted in accordance with the present invention;

(4) FIG. 3 is a schematic diagram illustrating by means of a temperature profile how a vertical air curtain disperses as its progresses downwards on a standard open-fronted refrigerator;

(5) FIG. 4 is a schematic diagram illustrating by means of a temperature profile how the air curtain of a refrigerator adapted in accordance with the present invention disperses less as its progresses downwards;

(6) FIG. 5 is schematic cross-section of a first embodiment of an air-guiding strip;

(7) FIG. 6 is a schematic perspective view of the strip of FIG. 3;

(8) FIG. 7 is a schematic perspective view of a first embodiment of a bracket for attaching an air-guiding strip to a refrigerator;

(9) FIG. 8 is a schematic perspective view of the bracket of FIG. 5 attached to a shelf support on a refrigerator;

(10) FIG. 9 is a schematic perspective view of the bracket of FIG. 5 attached to a shelf support on a refrigerator with a shelf in place;

(11) FIG. 10 is a schematic perspective view of an air-guiding strip attached to a refrigerator by means of the first embodiment of brackets;

(12) FIG. 11 is a schematic perspective view of a second embodiment of a bracket for attaching an air-guiding strip to a refrigerator;

(13) FIG. 12 is a schematic perspective view of the bracket of FIG. 9 attached to a ticket strip support on a refrigerator;

(14) FIG. 13 is a schematic perspective view of an air-guiding strip attached to a refrigerator by means of the second embodiment of brackets;

(15) FIG. 14 is a schematic cross-section of a second embodiment of an air-guiding strip showing the two halves of the strip separately and conjoined;

(16) FIG. 15 is a schematic perspective view of the strip of FIG. 12;

(17) FIG. 16 is a schematic perspective view of the strip of FIG. 12 showing how price labels may be retained thereby;

(18) FIG. 17 is a schematic cross-section of a third embodiment of an air-guiding strip comprising an electronic display;

(19) FIG. 18 is a schematic cross-section of a fourth embodiment of an air-guiding strip;

(20) FIG. 19 is a schematic perspective view of the strip of FIG. 18;

(21) FIG. 20 is a schematic perspective view of the strip of FIG. 18 showing how price labels may be retained thereby;

(22) FIG. 21 is a schematic perspective view of a refrigerator having a different types of air-guiding strip attached thereto.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

(23) Referring to the drawings, FIG. 1 shows a standard open-fronted refrigerator 1 having an open front 2 and a plurality of shelves 3. Refrigerator 1 comprises an air curtain system having an air egress 4 at its top and located above the open front of the refrigerator and an air recovery ingress 5 located below egress 4.

(24) Various other elements of the air curtain system exist, but such systems are so well-known in the art that further discussion thereof is not considered necessary.

(25) The air curtain system of refrigerator 1 is adapted to pass an air curtain of cooled air between air egress 4 and air recovery ingress 5 such that the air curtain passes in front of shelves 3 so as to increase the efficiency of refrigerator 1.

(26) Air egress 4 has an outer edge 9, and an air curtain expelled from air egress 4 therefore directly after expulsion from egress 4 has its front edge substantially in line with outer edge 9.

(27) However, as can be seen in FIG. 3 as the air curtain progresses downwards it gradually becomes more dispersed owing to turbulence, and the front edge of the air curtain becomes more difficult to define, but in effect moves outwards. It can be seen how the air curtain of a standard prior art refrigerator is therefore less effective near the air ingress in comparison to adjacent its air egress.

(28) Referring to FIG. 2 wherein the refrigerator of FIG. 1 has been fitted with a retrofit air-guiding strips 6 in accordance with the present invention, each shelf 3 has had attached thereto an elongate air-guiding strip 6, which is attached to its respective shelf 3 by means of brackets 7. Brackets 7 attach the ends of air-guiding strip 6 to the ends to the supports for shelf 3.

(29) Referring to FIGS. 5 and 6, air-guiding strip 6 is in the present embodiment in the form of an aerofoil blade, having a leading edge 11, lower surface (also known as a ‘pressure surface’) 10 which faces front edge 8 of shelf 3 and an upper surface (also known as a ‘suction surface’) 12 which faces outwardly from the storage space 13 of the refrigerator such that when refrigerator is in use upper surface 12 faces a user.

(30) In the present embodiment air-guiding strip is around 9 mm in maximum thickness (i.e. between lower surface 10 and upper surface 12.

(31) In the present embodiment air-guiding strip is around 45 mm in height (i.e. between leading edge 11 and trailing edge 13.

(32) Air-guiding strip 6 is spaced from the front edge 8 of shelf 3 such that its pressure surface 10 sits substantially vertically beneath outer edge 9 of air egress 4.

(33) Leading edge 11 of air-guiding strip 6 faces the flow of air being expelled from air egress 4.

(34) In use, with refrigerator 1 fitted with the air-guiding strips 6 of the present invention runs substantially as normal, except that the air curtain that passes between egress 4 and ingress 5 is guided down the open front 2 of the refrigerator by the air-guiding strips 6.

(35) Air-guiding strips 6 act stabilize the flow of the air curtain and hinder dispersal of the air curtain as air flows between air egress 4 and air ingress 5. Air-guiding members 6 do this by guiding air that is moving out of the stream of the air curtain back into it.

(36) Thus air-guiding strips with an aerofoil profile have been found to be ideal, although other shapes of air-guiding strips have been found to have some effect, particularly if the strip is at least 4 mm in thickness, more preferably at least 6 mm in thickness and even more preferably at least 8 mm in thickness.

(37) As can be seen in FIG. 4 when air-guiding strips 6 are fitted to a refrigerator 1 the air curtain is more contained with less dispersal thereof as air flows down towards egress 5.

(38) Beneficially, with air-guiding strips 6 in place a refrigerator 1 is able to be stocked as normal and users are able to remove products from the storage space 14 of refrigerator 1 as access to storage space 14 on shelves 3 is not hindered by air-guiding strips 6 as they each lie substantially in the same plane as shelves 3.

(39) It will be apparent that the optimal positioning of air-guiding strip 6 will depend upon the particular refrigerator with which the strip 6 is being used. In the present embodiment it has been found that positioning the air-guiding strip located substantially vertically beneath outer edge of the upper air egress seems to be preferable.

(40) Turning to FIGS. 7 to 10 and a first embodiment of a bracket that may be used to attach air-guiding strip 6 to a refrigerator, bracket 15 comprises an elongate arm 16 having a hook portion 17 adjacent a first end 18 and two projections 19a, 19b adjacent an opposite second end 20 adapted to retain therebetween air-guiding strip 6.

(41) An air-guiding strip 6 may be secured between projections 19a, 19b by any suitable means such as adhesive, a nut and bolt, or a grub screw.

(42) As can be seen in FIGS. 8 and 9, hook portion 17 of bracket 15 is adapted to fit over an existing shelf support 21, where it may be secured in place by any suitable means such as a nut and bolt or a grub screw. When in place shelf 22 may be repositioned upon shelf support 21.

(43) As best seen in FIG. 10, air-guiding strip 6 extends substantially across the full width of shelf 3. In the present embodiment as refrigerator 1 has only a single stack of shelves air-guiding strip 6 therefore extends substantially across the full width of the open front of refrigerator 1.

(44) It will be apparent that it is preferable for any air-guiding strip to extend substantially across the width of the air curtain, which in most refrigerators extend themselves across the full width of their open fronts. It will also be apparent that in order to span the width of the open front of a refrigerator two or more air-guiding strips could be used. Such an arrangement may be ideal for refrigerators that have more than one stack of shelves.

(45) It will also be apparent that in some embodiments air-guiding strips that do not substantially span the width of the open face of a refrigerator could be used, but such arrangements are not preferred.

(46) Air-guiding strip 6 lies substantially in the plane of shelf 22 and therefore also substantially in the plane of ticket strip 23 wherein prices of goods stored on shelf 22 may be retained and displayed. In order that ticket strip 23 is not obscured from view air-guiding strip 6 is formed of a substantially transparent plastics material, allowing shoppers to see ticket strip 23 through air-guiding strip 6.

(47) Turning to FIGS. 11 to 13 and a second embodiment of a bracket that may be used to attach air-guiding strip 6 to a refrigerator, bracket 29 comprises an elongate arm 24 having a clip portion 25 adjacent a first end 26 of elongate arm 24 and substantially orthogonal thereto.

(48) Bracket 29 further comprises two projections 27a, 27b adjacent an opposite second end 28 of elongate arm 24 adapted to retain therebetween air-guiding strip 6.

(49) An air-guiding strip 6 may be secured between projections 27a, 27b by any suitable means such as adhesive, a nut and bolt, or a grub screw.

(50) As can be seen in FIG. 12, clip portion 25 of bracket 29 is adapted to clip to an existing support 30 for a ticket strip 31, where it may be secured in place by any suitable means such as a nut and bolt or a grub screw.

(51) It is preferable that when fitted to a refrigerator the air-guiding strip and brackets may not be moved or altered so as to prevent users of the refrigerator unwittingly moving the air-guiding strip away from its optimum position. Thus, it is preferred that when fitted the air-guiding strips are in a substantially fixed position.

(52) Turning now to FIGS. 14 to 16 and a second embodiment of an air-guiding strip that may be employed with the present invention, air-guiding strip 32 is also in the shape of an aerofoil, but instead of being formed substantially in one piece of a transparent plastics material is instead formed in two halves.

(53) Backing portion 33 is formed of extruded aluminum and incorporates the leading edge 34, lower surface 35 and trailing edge 36 of an aerofoil.

(54) Front piece 38 is formed of a transparent plastics material and forms the upper surface 37 of an aerofoil.

(55) Front piece 38 comprises projections 39a, 39b adapted to engage with corresponding recesses 40a, 40b on backing portion 33 such that front piece 38 may be securely but releasably attached to backing portion 33.

(56) When conjoined backing portion 33 and front piece 39 together form a complete aerofoil.

(57) When air-guiding strip 32 is attached to a refrigerator it is front piece 38 that faces shoppers. Thus, in order that product prices may be displayed to shoppers front piece 38 is adapted to retain a plurality of product labels.

(58) Front piece 38 comprises a transparent flexible cover 41 formed by an incision 42 through the body of front piece 38.

(59) As best illustrated by FIG. 16 flexible cover 41 may be peeled back such that a user may insert product labels 43 into front piece 38, such that they are retained and displayed by air-guiding strip 32. Product labels 43 may be removed and replaced by a user as desired.

(60) Turning to FIG. 17 and a further embodiment of an air-guiding strip for use with the present invention, air-guiding strip 44 is in the form of an aerofoil and comprises a plurality of electronic price displays 45.

(61) Turning to FIGS. 18 to 20 and a further embodiment of an air-guiding strip for use with the present invention, air-guiding strip 46 is in the form of an aerofoil and has a main body 48 that has adhered to its upper surface (i.e. the aerofoil surface that faces out from a refrigerator when air-guiding strip 46 is in use) a transparent elastomeric flexible cover 47 that is adapted to releasably retain product labels

(62) As best illustrated by FIG. 20 flexible cover 47 may be peeled back such that a user may insert product labels (not shown) behind flexible cover, such that they are retained and displayed by air-guiding strip 46. The product labels may be removed and replaced by a user as desired.

(63) Beneficially with this embodiment main body 48 may be formed of any suitable material, and once formed flexible cover 47 may be attached thereto by adhesive.

(64) Turning to FIG. 21 and a refrigerator 49 retrofitted with air-guiding strips made in accordance with the present invention, it can be seen that in some circumstances it may be preferable to retrofit a fridge with a variety different types of air-guiding strip.

(65) On the lower three shelves of refrigerator 49 cheaper transparent plastic air-guiding strips 50 have been provided, whereas on the upper two shelves are provided more expensive composite air-guiding members 51 comprising an extruded aluminum backing portion and a frontal transparent product label housing.

(66) The reason for this is that shoppers are able to see original product labels 52 over the top of air-guiding strips fitted to the lower shelves.

(67) However, shoppers cannot see past air-guiding members 51 on the upper shelves that are at or around eye-level.

(68) Thus the upper shelves require product labels to be housed on the front of the air-guiding members 51.

(69) It will be apparent that the invention is not limited to retrofit kits for adapting existing refrigerators, but that new refrigerators may be made incorporating the air guides in accordance with the present invention.

(70) It will be apparent that although in the present embodiment an elongate aerofoil blade has been used in order to provide an air-guiding strip, other air-guiding strips might be employed.

(71) In general any air-guiding strip should preferably be in the form of a continuous elongate strip. However, it may be possible to provide a plurality of smaller air-guiding strips that in effect form an elongate strip that runs across the open front of a refrigerator.

(72) It is preferred that the air-guiding strips have an aerofoil cross-section. However, an air-guiding strip with a rectangular, curved, or oval cross-section might be used and such an air-guiding strip might still result in a reduction in energy consumption by a refrigerator employing air-guiding strips in accordance with the present invention.

Example 1

(73) The invention was initial tested using Computational Fluid Dynamics.

(74) A steady state two dimensional representation of an open-fronted multi-deck refrigerated display cabinet was modeled using Ansys CFX 14.5 CFD code. Heat transfer by convection between the ambient and the refrigerated air curtain was modeled. Buoyancy was modeled. The temperatures of products were not modeled, nor were effects of thermal radiation or humidity.

(75) Both a multi-deck with air-guiding strips and an identical cabinet without air-guiding strips in the form of aerofoils were modelled so that a direct comparison of the effect of air-guiding strips could be made. The numerical mesh and all other modelling parameters were kept as similar as possible, so that only the differences due to the air-guiding strips would be apparent.

(76) Parameters of the model are shown below. Ambient temperature outside of the cabinet=25° C. Temperature of air curtain and rear panel flow=−1° C. Mass flow rate of air curtain=1 kg/s per metre length Flow rate through rear panel=1 kg's per metre length Number of shelves=5+well Depth of shelves and well=500 mm Distance between shelves=300 mm Height of product on shelf=150 mm Height of shelf=40 mm Depth of discharge and return grille=100 mm Aerofoil type=NACA4314 (non-symmetric) Aerofoil length=40 mm Distance from aerofoil to shelf=100 mm Inside of discharge grille in line with edge of shelf Outside of discharge grille in line with edge of aerofoil

(77) TABLE-US-00001 TABLE 1 Temperature and enthalpy increases from discharge to return, domain imbalance, number of iterations and tetrahedral elements. Temp Enthalpy Domain Number of increase increase imbalance Number of tetrahedral Scenario (K) (W/m) (W/m) iterations elements No 3.3 650 2 1170 223 615 aerofoils Aerofoils 2.2 430 0.2 1180 125 805

(78) In respect of the results illustrated in Table 1, the temperature and enthalpy increases (per metre length of cabinet) come from entrainment between the warm ambient and cold air curtain. In the case with aerofoils the entrainment is only 66% of the case without aerofoils, showing a reduction of entrainment of 34%. Table 1 also shows the domain imbalance, this is a numerical error, which reduces as the model becomes more accurate. For the results to be valid it should be lower than the differences you are trying to detect, which in this case it is. Table 1 also shows the number of iterations made and the number of tetrahedral elements in each model.

(79) The aerofoils show a reduction in infiltration of 34% compared to not having aerofoils. As the infiltration of a chilled multi-deck display cabinet is approximately 70% of the total load, this would equate to a reduction in heat load of approximately 24%.

(80) A cabinet tested at 25° C. and 60% RH would be expected to have a heat load of approximately 1.6 kW per metre length. Approximately 1.1 kW would be due to entrainment, of which approximately 50% would be latent, giving a sensible infiltration of approximately 500 W/m. This is a similar value to that shown by the model.

Example 2

(81) Following the success of the theoretical modeling a real-life physical test was conducted.

(82) A Verco 0130® refrigerator was subjected to British Standards test BS EN ISO EN23953: 2005.

(83) Aerofoils made from folded stainless steel measuring 45 mm in height, and 6 mm in thickness were attached to each shelf with the leading edge of each aerofoil pointing upwards towards the top of the fridge from where the air curtain is ejected. The aerofoils were cut to be the same length as the shelves to which they were fitted. The aerofoils had substantially the same profile as depicted in FIG. 6.

(84) The aerofoils were located at a distance of 85±3 mm between the outer edge of the ticket strip and the inner edge of the aerofoil (minimum gap) and were approximately vertical. The aerofoils were slotted into brackets that were bolted to the ends of the shelves

(85) Phase 1 of the tests performed involved running the refrigerator on its normal settings and without any aerofoils attached.

(86) Phase 2 of the tests involved running the refrigerator on the same settings, but with the aerofoils as described above attached to the refrigerator.

(87) Phase 3 of the tests involved keeping the aerofoils on the refrigerator, but altering the settings on the refrigerator such that it produced substantially the same performance as during phase 1 (i.e. without the aerofoils attached to it). The reason for this is that one of the main purposes of the invention is not to improve the temperature performance of a refrigerator (although this may of course be achieved using the invention if desired), but instead is to reduce the energy consumed by refrigerators.

(88) The control settings for the three phases of the test are shown in Table 2.

(89) TABLE-US-00002 TABLE 2 Refrigerator control settings. Phase 1 & 2 Phase 3 Temperature setting −1.0° C. 0.1 Defrost interval 6 hours 6 hours Defrost maximum time 30 minutes 30 minutes Defrost termination 5.0° C. 5.0° C. temperature Hysteresis/differential 5.0° C. 5.0° C.

(90) Thus, energy consumption can be most reduced by attaching aerofoils to a refrigerator and then changing the settings on the refrigerator such that it produces substantially the same temperature performance as it did without the aerofoils.

(91) TABLE-US-00003 TABLE 3 Results of phases 1 to 3 testing (test BS EN ISO EN23953: 2005) Test Results Test Results Test Results Without Air With Air With Air Guides Guides Guides (Phase 1) (Phase 2) (Phase 3) Maximum temperature 7.7 7.1 7.7 (° C.) Minimum temperature 0.3 0.6 1.4 (° C.) Overall mean (° C.) 3.8 3.8 4.4 Mean visible (° C.) 4 4 4.7 Average power (W) 804.9 681 670.9 Energy/48 h (kWh/48 h) 19.32 16.35 16.10 % run time 83.1 67.7 67.4 TEC/TDA 11.82 10 9.85 Energy Reduction — 15% 17%

(92) TEC/TDA definition: this is the equation used to compare Total Energy Consumption (TEC) with Total Display Area (TDA). The lower this figure is, the better.

(93) As can be seen from Table 3, the aerofoils of the present invention reduce the TEC and therefore improve this figure.

(94) Further, while the average temperatures remain the same between phase 1 and 2 the temperature range has decreased resulting in a decrease of the maximum temperature of 0.6 Degrees C.

(95) Adding the aerofoils resulted in an energy decrease of 15% during phase 2, and 17% in phase 3.

(96) It should be noted that the term aerofoil has the same meaning as the US English word airfoil.

(97) Many variations are possible without departing from the scope of the present invention as set out in the appended claims.