Patent Application
20240019188
Ice makers form ice pieces that are directed into a bin for storage. Existing ice makers tend to bias a pile of the ice pieces in a direction that the ice pieces are dropped into the bin. For example, a typical ice maker directs the ice pieces toward a front of the bin resulting in an ice pile that is taller toward the front of the bin than to the back of the bin. Sensors may be used to indicate when the ice bin is full to stop the formation of additional ice pieces. In some cases, the biased ice pile results in an indication that the bin is full when it is not full.
In an example embodiment, an ice maker is provided. The ice maker includes, but is not limited to, an ice maker housing, an ice mold, an ice chute, and an ice stop. The ice mold is mounted to the ice maker to receive a fluid from which an ice piece is formed when the ice maker is used. The ice chute is mounted below the ice mold to receive the ice piece when the ice piece is formed. The ice chute slopes downward from a first edge to a second edge. The ice stop is formed of a sheet of material mounted to extend in a vertical direction. The ice stop is mounted a distance from the second edge of the ice chute such that, when the ice piece exits from the second edge of the ice chute, the ice piece strikes the ice stop.
In another example embodiment, a method of making and distributing ice is provided. The method includes, but is not limited to, receiving a fluid into an ice mold mounted to an ice maker housing, forming an ice piece in the ice mold by freezing the received fluid, releasing the formed ice piece onto an ice chute mounted below the ice mold to receive the formed ice piece, discharging the released ice piece from a second edge of the ice chute, and deflecting the discharged ice piece by an ice stop formed of a sheet of material. The ice chute slopes downward from a first edge to the second edge.
Other principal features of the disclosed subject matter will become apparent to those skilled in the art upon review of the following drawings, the detailed description, and the appended claims.
Illustrative embodiments of the disclosed subject matter will hereafter be described referring to the accompanying drawings, wherein like numerals denote like elements.
Referring to
Door 102 provides access to bin 202 that holds ice and may generally be defined by top wall 106, right side wall 104, back wall 106, left side wall 204, a bin front wall 208, and bottom wall 206. In the illustrative embodiment, a cleaning fluid drawer 210, an ice backstop 212, and ice maker 200 may be mounted adjacent top wall 106 within bin 202. Bin front wall 208 may include an aperture wall 214 that defines an opening through which ice may be withdrawn from bin 202 by a user. In the illustrative embodiment, aperture wall 214 defines a rectangular opening though other shapes may be used to define the aperture through which ice is withdrawn. In the illustrative embodiment, cleaning fluid drawer 210 is mounted at a top of aperture wall 214 and is recessed from a plane defined by a front face of bin front wall 208 though cleaning fluid drawer 210 may be mounted to other locations on ice maker assembly 100 and may not be recessed. When door 102 is in a closed position, ice cannot be withdrawn from bin 202.
As understood by a person of skill in the art, the walls and door 102 that form ice maker assembly 100 are insulated walls that include insulation to assist in maintenance of the desired temperature in bin 202. Electrical wiring and various conduits may further be located in the insulated walls. For example, during a manufacturing process, a space between exterior walls of ice maker assembly 100 and an interior liner may be filled with an insulating foam material that provides insulation.
Use of directional terms, such as top, bottom, right, left, front, back, etc. are merely intended to facilitate reference to the various surfaces and elements of the described structures relative to the orientations shown in the drawings and are not intended to be limiting in any manner. For consistency, the components of ice maker assembly 100 are labeled such that door 102 defines a front of ice maker assembly 100.
Though shown in the illustrative embodiment as forming a generally rectangular shaped enclosure, ice maker assembly 100 may form any shaped enclosure including other polygons as well as circular or elliptical enclosures. As a result, door 102, the walls forming ice maker assembly 100, and other components may have any shape including other polygons as well as circular or elliptical shapes.
Referring to
The refrigeration components of ice maker assembly 100 cool ice mold 416 to a temperature that promotes the formation of ice as understood by a person of skill in the art. The refrigeration components may include a compressor, a condenser, an evaporator, a drier, etc., mounted to various walls of ice maker assembly 100 either within the walls, on an exterior of the walls relative to ice maker assembly 100, and/or on an interior of the walls relative to ice maker assembly 100. For example, the refrigeration components mounted within base compartment 110 may include a compressor 304, a fan 306, a condenser 308, a drier 310, and a sump water pump 312. Additional refrigeration components may be mounted closer to ice maker 200 as described further below. Various tubing may connect the refrigeration components to provide a refrigeration cycle as understood by a person of skill in the art.
Referring to
Top drawer drain 410 is located on a floor of drawer 404 to provide a drain for fluid poured into drawer 404. The fluid travels through or over top drawer drain 410 onto a floor of transition tray 406 and/or onto a floor of bottom tray 408. Drain tube 412 is mounted to extend from the floor of bottom tray 408. Drain tube 412 receives the fluid poured into drawer 404 and provides a conduit to transport the fluid to an intended location within ice maker 200.
Ice maker 200 may include a sump housing 414, an ice mold 416, a mold tray 417, an evaporator coil 418, an ice chute 420, curtain fingers 422, drain aperture walls 424, a plurality of sprayers 426, and a cover 428. Referring to
Ice maker 200 further may include a filter assembly 506, an accumulator 508, a warm refrigerant intake conduit 510, a refrigerant intake conduit 511, a refrigerant outtake conduit 512, a valve 514, a water intake conduit 516, a filter intake conduit 517, a filtered water conduit 518, a sump water pump 520, a drain cap 522, and an overflow drain tube 524. In an alternative embodiment, ice maker 200 may not include filter assembly 506.
Warm refrigerant intake conduit 510 may be connected to receive warm refrigerant from compressor 304. Warm refrigerant intake conduit 510 is connected to provide the warm refrigerant to evaporator coils 418 to trigger release of ice from ice mold 416. Refrigerant intake conduit 511 may be connected to receive refrigerant from condenser 308. Refrigerant intake conduit 511 is connected to provide the refrigerant to evaporator coils 418 to form the ice in ice mold 416. Refrigerant outtake conduit 512 is connected to receive the refrigerant from evaporator coil 418 after cooling ice mold 416. Accumulator 508 is mounted to receive refrigerant from refrigerant outtake conduit 512 to prevent liquid refrigerant from reaching compressor 304 that is designed to move vapor refrigerant in the form of a gas. Accumulator 508 is connected to provide the refrigerant in the form of a gas to compressor 304. Compressor 304 is connected to provide the refrigerant to condenser 308 that condenses the gaseous refrigerant back to a liquid state. Drier 310 is connected between condenser 308 and refrigerant intake conduit 511. Fan 306 is mounted to cool condenser 308. An ice maker controller (not shown) may control a flow of refrigerant through condenser 308, drier 310, evaporator coils 418, accumulator 508, and compressor 304 to control a temperature of ice mold 416 and within bin 202.
Referring to
Sump drain aperture wall 610 is formed through lower sump bottom wall 608. Drain cap 522 is sized and shaped to mount to sump drain aperture wall 610. Drain cap 522 can be removed to empty any fluid or solid materials that accumulate in the sump cavity formed by sump housing 414.
Overflow drain tube 524 extends through lower sump bottom wall 608. A portion of overflow drain tube 524 extends above lower sump bottom wall 608. Overflow drain tube 524 provides a sump overflow drain tube that may be connected to sump water pump 312 to receive excess water within the sump cavity. For example, overflow drain tube 524 may be selected to extend above lower sump bottom wall 608 a height that is less than a height of lower sump front wall 607 to ensure that fluid does not overflow the sump cavity above upper sump bottom wall 606.
Referring to
Evaporator coil 418 forms a two-level serpentine pattern above a top of each ice piece mold of ice mold 416 and between each row of molds of ice mold 416. For example, in the illustrative embodiment, ice mold 416 includes four rows of generally rectangular molds with six molds in each row to form 24 ice pieces. Each mold may form other shapes and be larger or smaller than those shown in the illustrative embodiment. Ice mold 416 may form a greater or a fewer number of ice pieces in alternative embodiments. Each ice piece may be formed to have a variety of shapes including spheres, cylinders, multi-sided polygons, etc. The size of the ice piece is further not intended to be limiting.
Ice mold 416 is formed using a material that can be kept at or below freezing by evaporator coil 418 to form the ice pieces. Illustrative materials include stainless steel and copper with or without plating. Ice mold 416 is surrounded by mold tray 417. Mold tray 417 includes mold aperture walls within which each mold of ice mold 416 fits. Mold tray 417 slopes downward toward a front of ice maker 200.
A sprayer conduit 700 is connected to receive water from a pump head 712 of sump water pump 520 that pumps water from the sump cavity into sprayer conduit 700. Sprayer conduit 700 splits into a first sprayer conduit 702, a second sprayer conduit 704, and a third sprayer conduit 706. Each sprayer conduit is connected to a different sprayer of the plurality of sprayers 426. For example, in the illustrative embodiment, the plurality of sprayers 426 includes three sprayers. First sprayer conduit 702 is connected to a first sprayer of the plurality of sprayers 426. Second sprayer conduit 704 is connected to a second sprayer of the plurality of sprayers 426. Third sprayer conduit 706 is connected to a third sprayer of the plurality of sprayers 426. There may be a greater or a fewer number of sprayers of the plurality of sprayers 426, for example, based on dimensions of ice mold 416.
An ice chute drip channel 714 is a channel formed across a front edge of ice chute 420. Channel drain aperture walls 716 are formed through a bottom of ice chute drip channel 714.
Referring to
To form ice, valve 514 is connected to receive water or another type of fluid in an alternative embodiment. Valve 514 controls a flow of the water into filter intake conduit 517 that is connected between valve 514 and filter assembly 506. Filter assembly 506 filters the water and provides the filtered water to filtered water conduit 518 that is connected to a first intake conduit 708 and a second intake conduit 710 that extend through aperture walls formed through ice maker back wall 504 and open onto mold tray 417.
The water from first intake conduit 708 and second intake conduit 710 flows down mold tray 417 through apertures (not shown) formed in a front of mold tray 417. The water from mold tray 417 flows down through drain aperture walls 424 of ice chute 420 and channel drain aperture walls 716 of ice chute drip channel 714 onto upper sump bottom wall 606 and downward into the sump cavity where it can be pumped by sump water pump 520 into sprayer conduit 700. In particular, water striking curtain fingers 422 flows down into ice chute drip channel 714 and through channel drain aperture walls 716. Curtain fingers 422 primarily keep the water from flowing exterior of ice maker 200.
Sprayer conduit 700 splits the pumped water into first sprayer conduit 702, second sprayer conduit 704, and third sprayer conduit 706 that are each connected to a sprayer of the plurality of sprayers 426. Each nozzle of the plurality of sprayers 426 sprays the water upward into ice mold 416 to form the ice pieces as the sprayed water freezes. Unfrozen water falls back onto ice chute 420 and flows down through drain aperture walls 424 of ice chute 420 and channel drain aperture walls 716 of ice chute drip channel 714 onto upper sump bottom wall 606 and downward into the sump cavity where it can again be pumped by sump water pump 520 into sprayer conduit 700. The ice pieces formed by ice maker 200 may be referred to as “clear ice” due to a reduction in minerals trapped in the ice pieces. Minerals not removed by filter assembly 506 collect in a bottom of the sump cavity.
Once the ice maker controller determines that sufficient water has been provided to form the ice pieces, valve 514 is switched closed to stop the flow of water into filter assembly 506 or directly into filtered water conduit 518 when ice maker 200 does not include filter assembly 506. Once the ice maker controller determines that formation of the ice pieces is complete, the ice maker controller triggers a release of the ice pieces from ice mold 416. Warm refrigerant may be provided through warm refrigerant intake conduit 510 to release the ice from ice mold 416, for example. The ice pieces travel by gravity down ice chute 420 through curtain fingers 422 and into bin 202.
Typically, the ice pieces fall and collect toward a front of bin 202 instead of distributing evenly across a top surface of bottom wall 206 of bin 202 due to the downward slope of ice chute 420 towards the front of bin 202 as indicated by an ice chute plane 801. The ice pieces may strike a top of the ice pile and tumble from the ice pile toward a back of bin 202. Nevertheless, the ice pile is biased towards the front of bin 202 with the ice pile high toward the front and low toward the back of bin 202.
Referring to
In an illustrative embodiment, an ice level sensor 900 is mounted within a sensor housing 902 that is mounted to a bottom surface of a support bottom wall 922 of drawer base 400. Ice level sensor 900 points down towards the ice pile and is configured to measure a height of the ice pile that is provided to the ice maker controller so that the ice maker controller can determine when to stop forming ice pieces and when to start forming more ice pieces. For example, ice level sensor 900 may be an infrared sensor though other types of sensors may be used. Additionally, ice level sensor 900 may be mounted in alternative locations within bin 202 in alternative embodiments.
Ice level sensor 900 ensures that the ice does not spill out of aperture wall 214 by indicating when the ice pile has reached a predefined height within bin 202. Because the ice pile is biased toward the front of bin 202, ice level sensor 900 does not accurately indicate when additional ice pieces should be formed. To overcome this problem, ice backstop 212 is positioned an ice stop mounting distance 802 (shown referring to
For illustration, ice stop mounting distance 802 may be selected to direct the ice pieces received from ice chute 420 toward a center of bin 202 to result in an approximately even distribution of the ice pieces across the top surface of bottom wall 206 of bin 202. Ice stop mounting distance 802 is too far to serve the purpose of even ice distribution when an insufficient number of ice pieces strike ice backstop 212 after being discharged from ice chute 420. Ice stop mounting distance 802 is too close to serve the purpose of even ice distribution when ice pieces become stuck between ice backstop 212 and ice chute 420. Ice stop mounting distance 802 may also be selected such that ice backstop 212 is far enough from aperture wall 214 so that ice backstop 212 does not interfere with the removal of ice from bin 202. An acceptable range of distance values for ice stop mounting distance 802 is between the distance that is too close and the distance that is too far.
A width 904 of ice backstop 212 may be selected to cover an ice release zone width relative to from ice chute 420. Height 906 of ice backstop 212 may be selected to extend a sufficient distance below a horizontal exit plane 806 from ice chute 420. For example, height 906 may be selected to include a momentum distance 808 below horizontal exit plane 806 to ensure that ice pieces strike ice backstop 212. As ice backstop 212 is moved away from the end of ice chute 420, thereby increasing ice stop mounting distance 802, momentum distance 808 also increases.
A type of material and a thickness of ice backstop 212 may further be selected to flex when the ice pieces strike ice backstop 212 to avoid trapping the ice pieces between ice backstop 212 and ice chute 420. For illustration, ice stop mounting distance 802 was selected as 1.26 inches and momentum distance 808 was selected as 1.54 inches with a slope of ice chute 420 equal to 30 degrees. In an illustrative embodiment, ice backstop 212 was a 0.03 inch thick sheet of Acrylonitrile butadiene styrene, which is a thermoplastic polymer. Other materials with various thicknesses can be used in alternative embodiments such as one or more layers of plastic, rubber, silicone, etc. Considerations in selecting the material for ice backstop 212 include an amount of noise created when ice strikes ice backstop 212, corrosion resistance, strength, hardness, etc.
To illustrate the effect of ice backstop 212 on the ice distribution, an illustrative design for ice maker assembly 100 without ice backstop 212 was used. Ice level sensor 900 indicated that bin 202 was full when sixteen pounds of ice was stored in bin 202. Based on the illustrative design for ice maker assembly 100 with ice backstop 212, twenty-two pounds of ice was stored in bin 202 when ice level sensor 900 indicated that bin 202 was full. Due to the more even distribution of ice in bin 202, six additional pounds of ice was stored when using ice backstop 212.
Ice backstop 212 may include a right mounting slit wall 908 and a left mounting slit wall 910. Right mounting slit wall 908 formed through ice backstop 212 defines a right mounting tab 912. Left mounting slit wall 910 formed through ice backstop 212 defines a left mounting tab 914. A right mounting hook 916 is mounted to a right side of a support descending back wall 920 of drawer base 400 in the illustrative embodiment. A left mounting hook 918 is mounted to a left side of support descending back wall 920.
Referring to
Support descending back wall 920 is mounted to extend downward away from support bottom wall 922 of drawer base 400. In the illustrative embodiment, ice backstop 212 is mounted within bin 202 by inserting right mounting hook 916 through right mounting slit wall 908 and inserting left mounting hook 918 through left mounting slit wall 910. In the illustrative embodiment, right mounting hook 916 and left mounting hook 918 have a top edge 1100 that is sloped towards support descending back wall 920 to further facilitate mounting of ice backstop 212 within bin 202. Use of mounting hooks and slits allows ice backstop 212 to be easily installed and removed when needed. A greater or a fewer number of slits and mounting hooks may be used in alternative embodiments to mount ice backstop 212 within bin 202. Other mounting mechanisms may be used in alternative embodiments to mount ice backstop 212 within bin 202 in the selected location relative to curtain fingers 422. For example, a screw, a rivet, adhesive, etc. may be used in alternative embodiments. ice backstop 212 further may be mounted to extend vertically downward from other components of ice maker assembly 100 such as downward from an interior surface of top wall 108.
Drawer base 400 may include a support right sidewall 924, a support front wall 926, a support left sidewall 928, support bottom wall 922, support descending back wall 920, a right mounting arm 932, and a left mounting arm 934. A finger depression wall 930 may be formed in support bottom wall 922 to facilitate insertion of a finger of a user to grab drawer 404 and pull drawer 404 away from support front wall 926. Right mounting arm 932 has an L-shape and extends upward away from a top edge of support right sidewall 924. Left mounting arm 934 has an L-shape and extends upward away from a top edge of support left sidewall 928. A first fastener may be inserted through a top tab of right mounting arm 932, and a second fastener may be inserted through a top tab of left mounting arm 934 to mount drawer base 400 to the interior surface of top wall 108. Other mounting mechanisms may be used in alternative embodiments to fixedly mount drawer base 400 to ice maker assembly 100 in an orientation to allow withdrawal of drawer 404 from drawer base 400. In the illustrative embodiment, support front wall 926 is split into a right portion and a left portion to define an aperture within which drawer 404 is slid.
Referring to
Cleaning fluid drawer 210 can be opened by inserting one or more fingers into finger depression wall 930 and pulling cleaning fluid drawer away from drawer base 400. In the illustrative embodiment, cleaning fluid drawer 210 is slid outward using a right slide 1300 and a left slide 1302 mounted to an inner surface of a right side of drawer 404 and an inner surface of a left side of drawer 404, respectively. Other sliding mechanisms may be used in alternative embodiments. For example, cleaning fluid drawer 210 may be slid outward using a track formed on or in support bottom wall 922.
Right slide 1300 is mounted to a right slide mounting brace 1304, and left slide 1302 is mounted to a left slide mounting brace 1306. Right slide mounting brace 1304 is mounted to a right support platform 1308 that is mounted to support bottom wall 922. Left slide mounting brace 1306 is mounted to a left support platform 1310 that is mounted to support bottom wall 922. In the illustrative embodiments, fasteners are used to mount the slides to a respective slide mounting brace and to mount the slide mounting braces to a respective support platform though other mounting mechanisms may be used in alternative embodiments.
Referring to
Drawer 404 may include a drawer front wall 1500, a drawer top wall 1502, a drawer right sidewall 1504, a drawer back wall 1506, a drawer left sidewall 2000 (shown referring to
Drawer bottom wall 1508 is sloped to form a funnel that directs fluid poured into the drawer receptacle toward top drawer drain 410 formed in drawer bottom wall 1508. In the illustrative embodiment, top drawer drain 410 is located approximately in a center of drawer back wall 1506 though top drawer drain 410 may be positioned in other locations as long as drawer bottom wall 1508 is sloped to form the funnel that directs the fluid toward top drawer drain 410. A size of the drawer receptacle and of top drawer drain 410 may be selected to accommodate an expected pour rate for the fluid to avoid spilling of the fluid outside of the drawer receptacle. A distance that drawer 404 can be withdrawn from drawer base 400 also may be selected to provide a sufficient area for the fluid to be poured into the drawer receptacle without spillage.
In the illustrative embodiment with top drawer drain 410 located approximately in the center of drawer back wall 1506, drawer bottom wall 1508 includes a center funnel floor 1512, a right funnel floor 1514, and a left funnel floor 1516. Center funnel floor 1512 is sloped toward top drawer drain 410. Right funnel floor 1514 is sloped toward center funnel floor 1512. Left funnel floor 1516 is sloped toward center funnel floor 1512. In the illustrative embodiment, top drawer drain 410 includes a plurality of grate walls 1520 though in an alternative embodiment, top drawer drain 410 may simply be an aperture formed through drawer bottom wall 1508.
A plurality of support feet 1518 are formed between right receptacle wall 2002 and right funnel floor 1514 and between left receptacle wall 1510 and left funnel floor 1516. Splash guard tray 402 may be mounted to drawer 404 by placing sides of splash guard tray 402 on a top surface of the plurality of support feet 1518 so that splash guard tray 402 is positioned above drawer bottom wall 1508.
Referring to
Referring to
Bottom tray 408 may include a bottom tray bottom wall 1620, a bottom tray back wall 1622, a bottom tray front wall 1700, a bottom tray right sidewall 1624, a bottom tray left sidewall 1626, a right mating tab 1628, a left mating tab 1630, a right mounting tab 1632, and a left mounting tab 1634. Bottom tray front wall 1700 extends upward from a front edge of bottom tray bottom wall 1620. Bottom tray back wall 1622 extends upward from a back edge of bottom tray bottom wall 1620. Bottom tray right sidewall 1624 extends upward from a right edge of bottom tray bottom wall 1620. Bottom tray left sidewall 1626 extends upward from a left edge of bottom tray bottom wall 1620. Bottom tray right mounting tab 1632 extends outward from a top edge of bottom tray right sidewall 1624. Bottom tray left mounting tab 1634 extends outward from a top edge of bottom tray left sidewall 1626. One or more fasteners may be used to mount right mounting tab 1632 and left mounting tab 1634 to support bottom wall 922 in an illustrative embodiment though other mounting mechanisms may be used in alternative embodiments.
Right mating tab 1628 mounts to bottom tray right sidewall 1624 and extends upward forming a hook shape. Left mating tab 1630 mounts to bottom tray right sidewall 1624 and extends upward forming the hook shape. Right mating tab 1628 and left mating tab 1630 may be used to mount transition tray 406 to bottom tray 408 as described further below.
Referring to
Center funnel floor 1512 is sloped downward from front receptacle wall 1800 toward top drawer drain 410 at a first angle 1806 relative to a second horizontal plane 1807. Transition tray bottom wall 1608 is sloped downward from transition tray front wall 1610 toward drain tube 412 at a second angle 1808 relative to a third horizontal plane 1809. Transition tray bottom wall 1608 is sloped downward from transition tray front wall 1610 toward drain tube 412 at a third angle 1810 relative to a fourth horizontal plane 1811. First angle 1806, second angle 1808, and third angle 1810 may have the same or different values. For illustration, first angle 1806, second angle 1808, and third angle 1810 may be in the range of one to ten degrees. A minimum angle may be selected based on provision of a sufficient flow of the fluid from front to back in the illustrative embodiment. For example, the minimum angle may be based on a viscosity of the fluid. Depending on a location of cleaning fluid drawer 210 within ice maker assembly 100, the flow may not be front to back, but is downward from an exterior entry point such as drawer bottom wall 1508 to an interior exit point such as drain tube 412. A maximum angle may be selected based on a height 1812 and a depth 1814 for cleaning fluid drawer 210. For example, as the slope(s) increase a greater height 1812 is needed for a common depth 1814.
Referring to
Referring to
In the illustrative embodiment, right funnel floor 1514 is sloped toward center funnel floor 1512, and left funnel floor 1516 is sloped toward center funnel floor 1512. For illustration, center funnel floor 1512, right funnel floor 1514, and left funnel floor 1516 may have slopes of three to four degrees to provide sufficient flow of the fluid toward top drawer drain 410.
Drawer bottom wall 1508 may include a greater or a fewer number of funnel floors. For example, in the illustrative embodiment, top drawer drain 410 is positioned approximately in a center of drawer back wall 1506. Three funnel floors are included to direct the flow of the fluid toward the center of drawer back wall 1506. As an example, a single funnel floor may be used with top drawer drain 410 that extends a greater distance across drawer back wall 1506. As another example, two funnel floors may be used with top drawer drain 410 located in a corner of drawer back wall 1506. In alternative embodiments, top drawer drain 410 may be located at other locations on drawer bottom wall 1508.
In the illustrative embodiment, drawer front wall 1500 extends wider than drawer right sidewall 1504 and drawer left sidewall 2000. To align with drawer front wall 1500, drawer right sidewall 1504 includes a right protrusion wall 2010, and drawer left sidewall 2000 includes a left protrusion wall 2012. Right protrusion wall 2010 is generally parallel to drawer front wall 1500 and perpendicular to drawer right sidewall 1504 in the illustrative embodiment. Left protrusion wall 2012 is generally parallel to drawer front wall 1500 and perpendicular to drawer left sidewall 2000 in the illustrative embodiment.
In a space between right protrusion wall 2010 and drawer front wall 1500, a first right support wall 2014 is mounted to extend downward from drawer top wall 1502. First right support wall 2014 is generally parallel to drawer front wall 1500 and to right protrusion wall 2010 in the illustrative embodiment. A second right support wall 2018 is also mounted in the space between right protrusion wall 2010 and drawer front wall 1500. Second right support wall 2018 is mounted between right protrusion wall 2010 and first right support wall 2014 generally parallel to drawer right sidewall 1504 and perpendicular to first right support wall 2014 in the illustrative embodiment.
In a space between left protrusion wall 2012 and drawer front wall 1500, a first left support wall 2016 is mounted to extend downward from drawer top wall 1502. First left support wall 2016 is generally parallel to drawer front wall 1500 and to left protrusion wall 2012 in the illustrative embodiment. A second left support wall 2020 is also mounted in the space between left protrusion wall 2012 and drawer front wall 1500. Second left support wall 2020 is mounted between left protrusion wall 2012 and first left support wall 2016 generally parallel to drawer left sidewall 2000 and perpendicular to first left support wall 2016 in the illustrative embodiment.
First right support wall 2014 and second right support wall 2018 form a mirror image of first left support wall 2016 and second left support wall 2020 in the illustrative embodiment. First right support wall 2014, second right support wall 2018, first left support wall 2016, and second left support wall 2020 extend from drawer top wall 1502 a shorter distance than drawer right sidewall 1504 and drawer left sidewall 2000.
First right support wall 2014 and second right support wall 2018 form a first corner cavity, and first left support wall 2016 and second left support wall 2020 form a second corner cavity. In the illustrative embodiment, to mount drawer 404 to right slide 1300, a right corner formed by first right support wall 2014 and second right support wall 2018 is positioned within first upward facing channel 1602 of first front face 1600 of right slide 1300. First upward facing channel 1602 rests on second right support wall 2018 such that a remainder of a right portion of first front face 1600 of right slide 1300 is located within the first corner cavity. A left corner formed by first left support wall 2016 and second left support wall 2020 is positioned within second upward facing channel 1606 of second front face 1604 of left slide 1302. Second upward facing channel 1606 rests on second left support wall 2020 such that a remainder of a left portion of second front face 1604 of left slide 1302 is located within the second corner cavity. Drawer 404 may be mounted to right slide 1300 and to left slide 1302 using other mounting methods in an alternative embodiment.
Referring to
Referring to
Right mating tab 1628 includes a right shelf 2212 that extends outward to define a horizontal surface adjacent a top edge of right mating tab 1628. Left mating tab 1630 includes a left shelf 2214 that extends outward to define a horizontal surface. Right shelf 2212 slides along transition tray right top wall 1612 within right slide aperture wall 1616. Left shelf 2214 slides along transition tray left top wall 1614 within left slide aperture wall 1618. Right mating tab 1628 extends away from bottom tray right sidewall 1624. Left mating tab 1630 extends away from bottom tray left sidewall 1626.
Drain tube 412 forms a nozzle that is inserted into drain aperture wall 502 formed through cover 428 when cleaning fluid drawer 210 is mounted to ice maker 200. The fluid is provided into the sump cavity through drain tube 412 to clean and sanitize the ice making components when the ice maker controller enters a cleaning cycle.
A user pulls drawer 404 out from ice maker assembly 100 until the drawer receptacle is open a sufficient distance to avoid spillage. In the illustrative embodiment, drawer 404 can be withdrawn from a closed position shown in
Once stop wall 1802 contacts transition tray front wall 1610 of transition tray 406, transition tray 406 slides with drawer 404 until right mating tab 1628 reaches a front edge of right slide aperture wall 1616 and left mating tab 1630 reaches a front edge of left slide aperture wall 1618. A length of right slide aperture wall 1616 and left slide aperture wall 1618 from front to back defines a withdrawal distance for transition tray 406.
Stop wall 1802 is positioned to ensure that top drawer drain 410 overhangs at least a portion of transition tray bottom wall 1608 of transition tray 406 so that the fluid flows down transition tray bottom wall 1608 and onto bottom tray bottom wall 1620 without spillage. When transition tray 406 is not included, stop wall 1802 contacts bottom tray front wall 1700 of bottom tray 408 that limits further withdrawal of drawer 404 from ice make assembly 100.
A user pours the fluid into the drawer receptacle of drawer 404 with or without splash guard tray 402. The fluid flows by gravity down the sloped walls of drawer bottom wall 1508 through top drawer drain 410 onto transition tray bottom wall 1608 of transition tray 406 and/or onto bottom tray bottom wall 1620 of bottom tray 408. The fluid flows through drain tube 412 into the sump cavity.
The dimensions of the various components of cleaning fluid drawer 210 are selected to provide the connection between drawer 404 and the sump cavity through drain tube 412.
Referring to
Transition tray 406 is mounted to bottom tray 408 by inserting right mating tab 1628 into right slide aperture wall 1616 and left mating tab 1630 into left slide aperture wall 1618. In the illustrative embodiment, right mating tab 1628 and left mating tab 1630 are flexible and biased away from bottom tray right sidewall 1624 and bottom tray left sidewall 1626, respectively, so that right shelf 2212 abuts transition tray right top wall 1612 and left shelf 2214 abuts transition tray left top wall 1614. Transition tray right sidewall 2100 and transition tray left sidewall 1611 are sized to fit within bottom tray bottom wall 1620.
Cleaning fluid drawer can similarly be incorporated into other appliances such as a washing machine. Cleaning fluid drawer 210 may be mounted so that drawer 404 is accessible to the user and opens a sufficient distance to avoid spilling of the fluid. A greater or a fewer number of trays may be included with dimensions sufficient to provide the fluid to the appropriate location within the appliance. Drain tube 412 may be shorter or longer and may be straight or include bends as needed to reach the appropriate location within the appliance.
As used in this disclosure, the term “mount” is intended to define a structural connection between two or more structural components and includes join, unite, connect, couple, associate, insert, hang, hold, affix, attach, fasten, bind, paste, secure, bolt, screw, rivet, solder, weld, glue, adhere, form over, layer, and other similar terms. The phrases “mounted on” and “mounted to” include any interior or exterior portion of the components referenced. These phrases also encompass direct mounting (in which the referenced components are in direct contact) and indirect mounting (in which the referenced components are not in direct contact). Components referenced as mounted to each other may further be integrally formed together, for example, using a molding process as understood by a person of skill in the art. Though described as including multiple structural components mounted to each other, components described herein may be formed of a single continuous piece of material, for example, by molding, or may be formed of multiple distinct pieces mounted together, for example, attached to each other using various fasteners including adhesives, screws, rivets, welded joints, etc. The components of ice maker assembly 100 may be formed of one or more materials, such as metal, glass, and/or plastic having a sufficient strength and rigidity and aesthetic value to provide the illustrated and/or described function.
The word “illustrative” is used herein to mean serving as an example, instance, or illustration. Any aspect or design described herein as “illustrative” is not necessarily to be construed as preferred or advantageous over other aspects or designs. Further, for the purposes of this disclosure and unless otherwise specified, “a” or “an” means “one or more”. Still further, using “and” or “or” in the detailed description is intended to include “and/or” unless specifically indicated otherwise.
The foregoing description of illustrative embodiments of the disclosed subject matter has been presented for purposes of illustration and of description. It is not intended to be exhaustive or to limit the disclosed subject matter to the precise form disclosed, and modifications and variations are possible in light of the above teachings or may be acquired from practice of the disclosed subject matter. The embodiments were chosen and described in order to explain the principles of the disclosed subject matter and as practical applications of the disclosed subject matter to enable one skilled in the art to utilize the disclosed subject matter in various embodiments and with various modifications as suited to the particular use contemplated.
