The present invention relates to refrigeration appliances such as refrigerators, refrigerators/freezers, freezers, and the like, and in particular, refrigerated appliances having air filters for filtering air circulated through at least one interior compartment of the appliance.
Filtering air to and from a refrigerated compartment is known. One example of a replaceable or refreshable air filter is the FreshFlow™ brand air filter available from Whirlpool® Corporation under part number W10311524. Benefits of filtered air include, but are not limited to, neutralizing odors and bacteria.
Designing such filtering must balance a variety of issues and factors. Examples are functionality, maintenance or repair, space utilization, power usage, and economy in terms of cost of materials, production of components, and assembly. Another is acceptable co-existence and integration aesthetically and with the other refrigerator functions.
As is appreciated by those in this technical field, some of the above factors are antagonistic. Therefore, it has been identified there is room for improvement in this technical area.
The present disclosure presents an apparatus, method, or system for filtering air to and from a refrigerated compartment of a refrigeration appliance that improves over or solves problems and deficiencies in the art.
Additionally, a device, method, or system as described integrates functionally and aesthetically into a refrigerated appliance, helps the consumer identify and locate a replaceable air filter, integrates multiple functions including identification and location of the filter and air intake to the filter, economically provides for such multiple functionalities in terms of material, production, assembly, operational, and maintenance costs and economically and efficiently integrates into a refrigerated appliance both regarding space utilization and resource utilization (e.g., electrical power).
According to one aspect of the present disclosure, a refrigerator includes a cabinet body, an interior liner in the cabinet body defining at least a portion of an interior space, and an air filter assembly positioned in the interior liner. The air filter assembly includes a surface facing the interior space and generally flush with the liner, a luminous frame around the surface, an air filter covered by and recessed from the surface, and an air path from the interior space through the filter.
According to another aspect of the present disclosure, a refrigerator includes a cabinet body having interior and exterior wall surfaces, and at least one door openable and closeable over an opening into the cabinet body. An air filter assembly is housed within the cabinet body and has one or more air intake ports, an air filter cover in the interior wall surface in covering relation over the air filter assembly, and an illuminated frame member surrounding the air filter cover. The illuminated frame member comprises at least a portion of the one or more air intake ports surrounding the air filter cover.
According to another aspect of the present disclosure, a method of operating a refrigerator having an outer cabinet and an inner liner defining an interior refrigerated or freezer compartment enclosable by at least one door includes exchanging air to and from the compartment through an air filter positioned between the cabinet and the liner behind a removable cover generally flush with the liner and having a perimeter accenting the perimeter of the cover with lighting.
These and other features, advantages, and objects of the present device will be further understood and appreciated by those skilled in the art upon studying the following specification, claims, and appended drawings.
In the drawings:
For a better understanding of the invention, examples of several forms the invention can take will now be set forth in detail. These examples are neither inclusive nor exclusive of the forms and variations possible with the invention.
The exemplary embodiments will be discussed primarily in the context of a French-door-type household refrigerator (fresh food compartment accessible by two oppositely openable and closeable doors with bottom freezer below it). The rear wall of the refrigerator fresh food compartment has what will be called an air tower, which is an air flow channel or space vertically behind or otherwise integrated with that liner wall. The refrigerator has conventional control circuitry and components for conventional refrigerator/freezer functions such as refrigerated and circulated air, interior space illumination, and other operations. For example, the control circuitry supplies electrical power for lighting to illuminate the fresh food compartment when it senses at least one door to it is opened, accordingly turning the lighting on and off with respective opening and closing of the doors 14. The control circuit can also operate such things as a fan to control air flow in the appliance.
It is to be understood, however, that the invention is applicable to other configurations of refrigeration appliances. It can be applied to almost any type of refrigeration appliance in analogous ways to the embodiments discussed below.
As is conventional, refrigerator 10 has an inner plastic liner. Insulation can be injected between the liner and the exterior cabinet wall so there is generally a space behind the liner not only for insulation but also wiring, conduits or channels for air flow, or placement of other structures or components between the liner and the exterior cabinet.
A portion of rear liner wall 22 of fresh food compartment 12, in this embodiment, is sometimes called air tower 20. It is a vertical liner surface raised forwardly from the rest of the rear liner wall 22. This provides a larger horizontal cross-sectional space between the liner wall and the exterior cabinet. Air filter assembly 30 is mounted along this air tower, takes in air from food compartment 12 and delivers filtered air to the air tower. Filtered air is directed through the air tower to one or more return air vents 38 spaced apart from air filter assembly 30 along air tower 20.
As will be explained in more detail, air filter assembly 30 includes an air intake. Air filtering occurs by drawing air into that intake of air filter assembly 30, up through air tower 20, and back out into fresh food compartment 12 through air return vents 38. As indicated at
Air filter assembly 30 has the following features. A pre-formed opening 32 in air tower 20 surrounds and essentially “frames” a removable filter cover 70. The gap between liner opening 32 and the perimeter of cover 70 will sometimes be called channel 34. As indicated at
Light sources in air filter assembly 30 are configured to provide what might be considered accent lighting for air filter cover 70. As will be explained later, light sources recessed from the plane of cover 70 and air tower 20 are used to create luminosity in or at channel 34. This luminous channel surrounds or frames cover 70 of an air filter held behind it. This allows an aesthetically-pleasing accent lighting of the location of the air filter. It additionally helps a consumer know where the air filter is and how to locate it (e.g. for replacement or recharging).
As further indicated in
The accent lighting in channel 34 from air filter assembly 30 can be a different color (e.g., blue) to provide contrast and bring attention to filter assembly 30 relative to other lighting in refrigerator 10. Air filter assembly 30 is configured such that accent lighting of channel 34 does not overwhelm or materially conflict with the white illumination lighting 28 or other ambient lighting within compartment 12. For example, it generally creates an a luminous glow and neither creates significant glare to direct viewing by the consumer nor does it spill light out into the fresh food compartment 12 in a manner that materially conflicts with or is at cross-purposes with illumination lighting 28. In this embodiment the blue light is characterized by its dominant wavelength directly related with the light source used, which in the present example may be 468 nm. The width of channel is on the order of one (1) inch wide.
As indicated in
As can be further understood from
As will be further discussed below, the accent lighting produced by this embodiment is essentially a glow more in the nature of backlighting than of task lighting. LED light sources with blue color output cooperate with light transmissive surfaces to produce the glow or luminance. Such characteristics and effects may be achieved by selecting LEDs of certain characteristics (e.g. light output distribution pattern, intensity, color, etc.) and light transmissive surfaces (e.g. clear, translucent, reflective, refractive, etc.) that cooperate to directly and/or indirectly produce a light intensity at and around channel 34 which distinguish from the background or other illumination, but yet do not overwhelm, inhibit, or materially affect other lighting in fresh food compartment 12. Reference numeral 36 will sometimes be used to refer to the radiation pattern or luminance at channel 34.
Air filter assembly 30 has multi-functionality including placement of a replaceable air filter for relatively easy access by the consumer, accent lighting of the removable filter cover 70 for identification and location of the air filter, and aesthetically pleasing proportionality of channel 34 with a radiation output relative to the rest of the refrigerator and cover 70, while concurrently taking advantage of space behind the outer wall of air tower 20 to build in an air intake to the air filter and communicate it to return vents 38 spaced apart from air filter assembly 30.
This combination of multi-functionality and design draws attention to and distinguishes the air filter location from other components of the refrigerator 10. In this example, the color is blue. Of course, other colors are possible, including white. It helps the consumer understand what is needed to access and replace the air filter. Replacement is periodic and recommended for optimal air filtering. Alternatively, some are refreshable or rechargeable after which they can be reinstalled.
Additionally, specific structural cooperation in air filter assembly 30 creates an output radiation pattern for the accent lighting that does not overwhelm the interior lighting 28, and does not interfere with interior lighting 28 or other lighting. It does not create problematic glare or spill light but rather is in the nature of accent lighting.
The width of channel 34 in proportion to refrigerator 10, fresh food compartment 12, and cover 70 is aesthetically pleasing. It basically distinctively “frames” cover 70. The flush position of cover 70 relative to the remaining portions of air tower 20 stands out with respect to the recess of channel 34 and gives the aesthetic appearance of cover 70 “floating” in space. The glowing or luminosity at channel 34 adds another aesthetic effect. The degree of these aesthetic effects can be adjusted or tuned by providing a desired luminosity for the accenting and visually identifying the position of assembly 30 to the consumer at or even more than several feet away (e.g. across a room) from the open doors 14L and R. On the other hand, channel width, depth, and shape, as well as proportion, creates a sufficient air intake from the fresh food compartment for purposes of effective air filtering throughput to and through the air filter and circulation back from the air filter to compartment 12. The intake area and volume of framing channel 34 relative to cover 70 and the air filter, and the air path to return vents 38, can be designed for a rate of air circulation (with or without fan operation over and above normal air exchange to and from compartment 12) which is effective for good air filtering for a refrigerator. Again, the relatively flush position of cover 70 relative to the outer surface of air tower 20, and the luminosity of the radiation pattern from channel 34 give the appearance of cover 70 “floating” in space and framed by light. But this combination also allows filter air intake essentially through the lighted channel 34.
As can be appreciated by one skilled in the art, this general relationship can be implemented in different form factors. Cover 70 can be a variety of shapes and lengths and widths. Channel 34 can vary in width and depth.
An inner reflector member 80 has a plate 81 with distal edges 87, angled perimeter side walls 86 (all four sides), corner air openings 89 (all four corners), and a central opening 82 bounded by a pair of C-shaped walls 83. Apertures 85 in the C-shaped walls 83 snap into bosses 47 on the outside of receiver 45 of reflector member 40.
A filter cover 70 includes a top solid surface 71 and a lip 21 that can simply removable snap fit over the distal edges 87 of angled walls 86.
By comparing
In this example, the LEDs can be a commercially available Everlight Electronics Model 19-117Z/BHC-YL2M2QY/3T (0603 Package Chip Led (0.4 mm Height) blue LED. Others are of course possible.
This embodiment therefore allows easy access to removable filter 60 by simply unsnapping cover 70, grabbing filter 60, and pulling it out. While assembled, assembly 30 decoratively covers filter 60, provides accent lighting around it, and also presents an air intake to it.
What will be called the base 40 of air filter assembly 30 is a clear plastic part having the following characteristics. A plate 41 has a central through-opening 42. Opening 42 has a shape which would receive one side of air filter 60 by interference fit. The perimeter of base 40 is essentially a U-shaped member 43 defining a slot 44. Slot 44 has characteristics to allow it to be interference fit into turned-in lip or flange 21 of the outer wall of air tower 20. Between slot 44 and opening 42 of base 40 is an angled web 46 (e.g. solid clear plastic sections). When assembled (see
Printed circuit board (PCB) 50 is essentially a rectangular frame or plate 51 defining an interior through-opening 52. LEDs 54 are distributed roughly equally spaced on front side 53 (see
As shown in
In this embodiment filter 60 is basically a valid rectangular-in-cross-section filter medium having a body 61 with front 62, back 64, and side wall 66. As illustrated in
Cover 70 is an independent piece including a forward portion defining surface 71 and a receiver 72 defined by side wall 73 behind surface 71. The shape of receiver 72 is also complimentary to the perimeter length and width of filter 60 body 61. Receiver 72 of cover 70 can simply be interference fit over the opposite side of filter 60 from that seated in base 40. As shown in
Further details regarding particular components are as follows. PCB 50 can be made of conventional printed circuit board with surface mounted components and conventional wiring according to circuit diagram of
The LEDs can be selected to have characteristics to be effective for that purpose and in the environment of a refrigerator/freezer. One selected characteristic may be tolerance of a temperature range for a reasonably useful LED life over typical refrigerator appliance temperature ranges (e.g. −20° C. to 80° C.). Beam angle could be half intensity plus or minus 60 to 170 degrees and, in one example, about 130 degrees. However, as can be appreciated, different LED types and characteristics can be used along with different optical characteristics of base 40 to achieve similar luminosity results. Again, the combination described produces accent lighting around filter cover 70 but does not produce glare or spill light that obscures cover 70 or any indicia on it. It does not overwhelm or materially adversely affect other lighting in the refrigerator. Of course, the characteristics can be adjusted according to need or desire.
In this embodiment, nominal characteristics of the circuit of
Strip total power=0.4 W
Forward voltage=3.02 V
Bias resistor (R)=462.28 Ohms
Current per string=7.38 mA
The closest 1% resistor available is 464 Ohms
With this resistor the power would be 0.3985 W
Initial power variation=˜25% i.e. Pmax=0.5 W
JST XA (2 pin) type connector
However the designer can vary these characteristics according to need or desire. An alternative way to describe LEDs 54 is blue small signal LEDs such as are conventional for user interfaces. Again, the power draw and light output production are not needed for task lighting type illumination levels but rather accent lighting.
As shown, PCB 50 can be a rectangular shape having a cutout therein such that the body of PCB 50 defines a frame having a thickness of about 8 mm around the opening. PCB 50 can further have a length, width, and height of about 70 mm, about 90 mm, and 1.6 mm, respectively. Wiring 58 could be operatively electrically connected to two refrigerator circuitries that could have the following function. When that circuitry senses a switch indicating opening of either or both doors 14L or 14R, LEDs 54 would be activated. Conversely when both doors are closed, LEDs 54 can be turned off.
The above characteristics of the circuit of
As can be further appreciated, cover 70 can be molded of thermal plastic and relatively inexpensive. It can be aesthetically matched in color and finish to the outer wall of air tower 20 for an integrated appearance. Filter 60 can be made of typical filtering media (with or without a frame or cage) such as what is known in the art. Base 40 can be molded of thermal plastic having clear optical properties or substantially clear optical properties. On the other hand it could be semi-light transmissive or translucent.
Interference fit of components is possible. Alternatively, base 40 could be adhered or fastened to air tower 20, such as to the outer wall thereof, as could PCB 50 to base 40. For a removable and replaceable filter 60, filter 60 could be releasably mountable to base 40 as would cover 70 to filter 60. But other techniques are possible.
With reference to
LEDs 54 are turned on when the refrigerator control circuit senses a refrigerator door is open (which is conventional by a door open switch in most refrigerators). As described above, the accent lighting which surrounds cover 70 is aesthetically pleasing. It also identifies and allows location of the air filter for replacement. But it does not overwhelm, or create glare or spill light that is disruptive of, other functions or illumination.
Furthermore, cost effectiveness is achieved by the materials and minimization of parts and components. The pieces are predominantly thermoplastic, although they do not have to be. Filter 60 pops into base 40. Cover 70 pops on top of filter 60. The angle of the web 46 at base 40 provides both an at least partially light transmissive angled surface for light from LEDs 54 but also channels intake air through filter 60. Energy consumption is minimal. There is no obstruction of space utilization because of the components being flush or recessed. Furthermore, it is adaptable and flexible to different refrigerator configurations or placements in refrigeration appliances.
As will be appreciated by those skilled in the art, variations are possible. Variations obvious to those skilled in the art will be included within the invention which is defined solely by its claims. In one example, the configuration of base 40 may vary.
Another example of an alternative is illustrated in
One example of an optional feature would be to have several different colored LEDs on PCB 50. Circuitry could monitor length of cumulative time since the last filter change. When a predetermined cumulative time expires, the accent lighting could change from one color to another. An example would be blue accent lighting during useful life of that filter. It could change to red when the circuit wants to alert the owner of the appliance change of filter is recommended, such at or toward the end of the estimated useful life of the filter. Many conventional refrigerators have circuits or sensors that would generate a “change filter” signal that could be used to shut off the blue LEDs and activate the red LEDs of the example given above.
It is to be further understood that the location of air filter assembly 30 could vary. It does not necessarily have to be centered in the rear wall of a compartment. It could be to one side or one corner of the rear wall. It could also be on a side wall. It might also be in a freezer compartment.
Although the width of channel 34 width can be consistent all around the filter cover, variations in width are possible.
Furthermore, as mentioned earlier, the specific number, power, color, output distribution pattern, other characteristics of the light sources can vary. They do not necessarily have to be LEDs. Instead of simply optically clear or substantially light transmissive non-optical plastic (e.g. angled web 46 or 46′) as a clear covering over the light sources, components having optical characteristics (lens, reflectors, diffusers, filters, etc.) could be utilized.
Still further, cover 70 does not have to be absolutely flush or coplanar with the outer surface of air tower 20. It could be a bit out of plane or could be substantially recessed and still provide a multi-function of air intake and accent lighting.
Additionally, it is to be understood that the perimeter shape of cover 70 is not limited to one that is rectangular. A wide variety of sizes and geometric shapes (e.g., symmetrical or asymmetrical, regular or irregular) are possible. The perimeter of cover 70 could be curved, compound curves, or a combination of straight and curved sections and still retain the multi-functionality of air intake plus accent lighting around such cover. Also, the filter could be any of a variety of shapes (symmetrical or asymmetrical). The filter cover (e.g. 70 or 70′) could substantially follow the perimeter of the filter. Alternatively, the perimeter of the filter does not have to be complimentary to the perimeter of the cover.
It will be understood by one having ordinary skill in the art that construction of the described device and other components is not limited to any specific material. Other exemplary embodiments of the device disclosed herein may be formed from a wide variety of materials, unless described otherwise herein.
For purposes of this disclosure, the term “coupled” (in all of its forms, couple, coupling, coupled, etc.) generally means the joining of two components (electrical or mechanical) directly or indirectly to one another. Such joining may be stationary in nature or movable in nature. Such joining may be achieved with the two components (electrical or mechanical) and any additional intermediate members being integrally formed as a single unitary body with one another or with the two components. Such joining may be permanent in nature or may be removable or releasable in nature unless otherwise stated.
It is also important to note that the construction and arrangement of the elements of the device as shown in the exemplary embodiments is illustrative only. Although only a few embodiments of the present innovations have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited. For example, elements shown as integrally formed may be constructed of multiple parts or elements shown as multiple parts may be integrally formed, the operation of the interfaces may be reversed or otherwise varied, the length or width of the structures and/or members or connector or other elements of the system may be varied, the nature or number of adjustment positions provided between the elements may be varied. It should be noted that the elements and/or assemblies of the system may be constructed from any of a wide variety of materials that provide sufficient strength or durability, in any of a wide variety of colors, textures, and combinations. Accordingly, all such modifications are intended to be included within the scope of the present innovations. Other substitutions, modifications, changes, and omissions may be made in the design, operating conditions, and arrangement of the desired and other exemplary embodiments without departing from the spirit of the present innovations.
It will be understood that any described processes or steps within described processes may be combined with other disclosed processes or steps to form structures within the scope of the present device. The exemplary structures and processes disclosed herein are for illustrative purposes and are not to be construed as limiting.
It is also to be understood that variations and modifications can be made on the aforementioned structures and methods without departing from the concepts of the present device, and further it is to be understood that such concepts are intended to be covered by the following claims unless these claims by their language expressly state otherwise.
The above description is considered that of the illustrated embodiments only. Modifications of the device will occur to those skilled in the art and to those who make or use the device. Therefore, it is understood that the embodiments shown in the drawings and described above is merely for illustrative purposes and not intended to limit the scope of the device, which is defined by the following claims as interpreted according to the principles of patent law, including the Doctrine of Equivalents.
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