This application relates generally to an ice maker for a refrigeration appliance, and more particularly, to a refrigeration appliance including an ice maker disposed within a fresh food compartment of a refrigerator that is maintained at a temperature above a freezing temperature of water at atmospheric conditions.
Conventional refrigeration appliances, such as domestic refrigerators, typically have both a fresh food compartment and a freezer compartment or section. The fresh food compartment is where food items such as fruits, vegetables, and beverages are stored and the freezer compartment is where food items that are to be kept in a frozen condition are stored. The refrigerators are provided with a refrigeration system that maintains the fresh food compartment at temperatures above 0° C. and the freezer compartments at temperatures below 0° C.
The arrangements of the fresh food and freezer compartments with respect to one another in such refrigerators vary. For example, in some cases, the freezer compartment is located above the fresh food compartment and in other cases the freezer compartment is located below the fresh food compartment. Additionally, many modern refrigerators have their freezer compartments and fresh food compartments arranged in a side-by-side relationship. Whatever arrangement of the freezer compartment and the fresh food compartment is employed, typically, separate access doors are provided for the compartments so that either compartment may be accessed without exposing the other compartment to the ambient air.
Such conventional refrigerators are often provided with a unit for making ice pieces, commonly referred to as “ice cubes” despite the non-cubical shape of many such ice pieces. These ice making units normally are located in the freezer compartments of the refrigerators and manufacture ice by convection, i.e., by circulating cold air over water in an ice tray to freeze the water into ice cubes. Storage bins for storing the frozen ice pieces are also often provided adjacent to the ice making units. The ice pieces can be dispensed from the storage bins through a dispensing port in the door that closes the freezer to the ambient air. The dispensing of the ice usually occurs by means of an ice delivery mechanism that extends between the storage bin and the dispensing port in the freezer compartment door.
However, for refrigerators such as the so-called “bottom mount” refrigerator, which includes a freezer compartment disposed vertically beneath a fresh food compartment, placing the ice maker within the freezer compartment is impractical. Users would be required to retrieve frozen ice pieces from a location close to the floor on which the refrigerator is resting. And providing an ice dispenser located at a convenient height, such as on an access door to the fresh food compartment, would require an elaborate conveyor system to transport frozen ice pieces from the freezer compartment to the dispenser on the access door to the fresh food compartment. Thus, ice makers are commonly included in the fresh food compartment of bottom mount refrigerators, which creates many challenges in making and storing ice within a compartment that is typically maintained above the freezing temperature of water.
One particular problem arises in circulating cooling air from an evaporator in the ice maker compartment to the ice tray wherein the ice cubes are formed. Over time, relatively warmer moisture in the ice maker collects on the relatively colder evaporator and on components downstream of the evaporator and freezes. The ice maker is designed to periodically perform a defrost cycle to melt the ice and/or frost and conduct the water away from the evaporator. In some instances, high humidity in the surrounding environment may cause excessive amounts of ice to build up on the evaporator and, in some instances, on the fan used to convey the cooling air through the ice maker. When ice builds up on the fan, the fan becomes unbalanced and/or inoperable and the ice maker ceases to make ice cubes. At this time, the problem cannot be remedied by a normal defrost cycle. Instead, a service person must manually clean away the ice build-up. As can be appreciated, this results in downtime, inconvenience and cost to the user and/or the manufacturer.
Accordingly, there is a need in the art for a refrigerator including an ice maker disposed within a fresh food compartment of the refrigerator in which the accumulation of ice/frost on the fan of the ice maker can be prevented, or at least minimized.
There is also a need in the art for a handle-operated door lock, and/or an apparatus for determining the height of ice pieces in an ice bin of the ice maker.
In accordance with one aspect, there is provided a refrigeration appliance that includes a fresh food compartment for storing food items in a refrigerated environment having a target temperature above zero degrees Centigrade. An ice maker is disposed within the fresh food compartment for producing and storing ice pieces. The ice maker includes an ice tray for forming ice pieces. An ice bin receives and stores the ice pieces produced by the ice tray. An air handler assembly conveys cooling air through the ice tray and the ice bin. An evaporator is provided for cooling air conveyed through the ice tray and the ice bin. The air handler assembly includes a fan that conveys the cooled air. An insulated air duct is disposed between the evaporator and the fan for preventing the migration of ice from the evaporator to the fan. The insulated duct has an opening extending from an end adjacent the evaporator to an end adjacent the fan. A lower inner wall of the air duct has a first ramped portion on the end adjacent the evaporator.
In accordance with another aspect, there is provided an ice maker for freezing water into ice pieces. The ice maker includes an ice tray for forming ice pieces. An ice bin receives and stores ice pieces produced by the ice tray. An evaporator is provided for cooling air conveyed through the ice tray and the ice bin. An air handler assembly conveys cooling air through the ice tray and the ice bin. The air handler assembly includes a fan that conveys the cooling air. An insulated air duct is disposed between the evaporator and the fan for preventing the migration of ice from the evaporator to the fan. The insulated duct has an opening extending from an end adjacent the evaporator to an end adjacent the fan. A lower inner wall of the air duct has a first ramped portion on the end adjacent the evaporator.
In accordance with yet another aspect, there is provided an ice maker for freezing water into ice pieces. The ice maker includes an ice tray for forming ice pieces. An ice bin is provided for receiving and storing ice pieces produced by the ice tray. A sensor assembly is positioned to detect a level of ice in the ice bin. The sensor assembly includes an emitter for sending photons along a predetermined path. A receiver is provided for detecting the photons when the photons are reflected off an object disposed in the predetermined path. A controller is programmed to measure a duration of time between the emitter sending the photons along the predetermined path and the receiver detecting the photons to determine at least one of a height of the ice pieces in the ice bin and the presence/absence of the ice bin in the ice maker based on input from the emitter and the receiver.
Referring now to the drawings,
One or more doors 16 shown in
A dispenser 18 (
Referring to
The freezer compartment 12 is used to freeze and/or maintain articles of food stored in the freezer compartment 12 in a frozen condition. For this purpose, the freezer compartment 12 is in thermal communication with a freezer evaporator (not shown) that removes thermal energy from the freezer compartment 12 to maintain the temperature therein at a temperature of 0° C. or less during operation of the refrigerator 10.
The refrigerator 10 includes an interior liner 24 (
An illustrative embodiment of the ice maker 50 is shown in
Referring now to
Keeping with
The air handler assembly 100, shown in
Referring now to
In the embodiment shown, the upper opening 114 and the lower opening 116 are divided into a plurality of openings to prevent large debris from passing into/out of the housing 110. The openings can also be appropriately sized to prevent a user from inserting a finger or other similarly sized object into the openings 114, 116. It is also contemplated that a separate piece, e.g., a screen or a grill can be placed over the openings 114, 116 or molded into the housing 110 to define the plurality of openings.
As shown in
A circular opening 118 is formed in the front face 111 of the housing 110 at a location above the lower opening 116. The circular opening 118 is dimensioned and positioned as described in detail below. A portion 111a of the front face 111 of the housing 110 is sloped and includes an oblong opening 122 therein. The oblong opening 122 is dimensioned as described in detail below.
A latch pin 123 is optionally attached to the front face of the housing 110. The latch pin 123 is provided to resist the forces and vibrations resulting from operation of the auger and to hold the ice bin 54 in place. The latch pin 123 is described in more detail in U.S. Pat. No. 9,234,690 (issued on Jan. 12, 2016) incorporated in its entirety herein by reference. Alternatively, the latch pin 123 could be coupled to or formed with the ice bin 54 and may releasably latch into a suitable hole in the front face of the housing 110.
As shown in
A lower, rear portion of the housing 110 is sloped to define a sump or fluid collection portion 132 of the housing 110. A U-shaped channel 134 extends from the sump 132. The channel 134 is attachable to a drain line (not shown). As described in detail below, fluid that collects within the sump 132 exits through the channel 134 and away from the air handler assembly 100 during a defrost cycle.
A partition 128 divides the interior cavity 113 of the housing 110 into an upper cavity 115a and a lower cavity 115b. The lower cavity 115b is dimensioned to receive the auger motor assembly 140. It is contemplated that the upper cavity 115a and the lower cavity 115b include a plurality of ribs for properly positioning components in the housing 110 and a plurality of holes for securing components to the housing 110.
As shown in
As shown in
As shown in
In the embodiment shown, the first ramped portion 156a is a downwardly sloped planar surface and the second ramped portion 156b is a downwardly sloped curved surface. It is contemplated that the first ramped portion 156a could be a downwardly curved surface and/or the second ramped portion 156b could be a downwardly sloped planar surface. In the embodiment shown, the slopes of the first ramped portion 156a and the second ramped portion 156b are continuous, i.e., no steps and no points where the slope abruptly changes. It is contemplated that at least one of the first ramped portion 156a and the second ramped portion 156b may include at least one step (not shown) or a slope that abruptly changes at one or more discrete locations (not shown) along the first ramped portion 156a and/or the second ramped portion 156b.
It is also contemplated that the second downward ramped portion 156b can a substantially vertical surface. In the embodiment shown, the first downward ramped portion 156a has a low point at the first end 152a. It is contemplated that the low point of the first downward ramped portion 156a could be at a location spaced from the first end 152a.
The second end 152b of the air duct 152 includes an upper notched portion 158a and a lower notched portion 158b on the leading edge of opening 154. The upper notched portion 158a and the lower notched portion 158b are positioned to be adjacent to a side of the fan grommet 162.
It is contemplated that the air duct 152 can be made from an insulating material, such as a rigid EPS foam, plastic, rubber, or the like. The air duct 152 can be monolithic or assembled of multiple parts. It is also contemplated that the air duct 152 can be between about 2 inches and about 5 inches in length such that the fan 164 is positioned at least about 2 to about 5 inches from the evaporator/defrost assembly 170 of the ice maker 50. It is also contemplated that the air duct 152 may be about 3 inches in length.
The fan grommet 162 is dimensioned to be placed around the outer side walls of the fan 164. Both the fan grommet 162 and the fan 164 can be secured to the second end 152b of the air duct 152 by slightly flexing the second end 152b of the air duct 152 around the fan grommet 162 and the fan 164. It is also contemplated that the fan grommet 162 and the fan 164 can be inserted into a slot formed on the second end 152b of the air duct 152 and/or fasteners (not shown), such as screws can be used to secure the fan grommet 162 and the fan 164 to the air duct 152. The fan grommet 162 can be made from an elastic material to dampen the transmission of vibrations from the fan 164 to the air duct 152 during operation. As shown in
In the embodiment shown, the air duct 152 includes the upper notched portion 158a and the lower notched portion 158b. It is also contemplated that, instead of notching the air duct 152, the corresponding side of the fan grommet 162 may be notched. It is also contemplated that one or more holes can be formed in the bottom of the air duct 152 and/or the fan grommet 162 and positioned to be in registry with the first groove or slot 119a in the housing 110 when the evaporator fan assembly 150 is positioned in the housing 110, as described in detail below.
As shown in
In the embodiment shown, the housing 172 includes a first sleeve plate 174 and a second sleeve plate 182. The first sleeve plate 174 and the second sleeve plate 182 are formed to define an upper rectangular portion of the housing 172 and a lower triangular portion of the housing 172. In the embodiment shown, individual pieces of tape 175 are provided for securing the first sleeve plate 174 to the second sleeve plate 182. It is also contemplated that the first sleeve plate 174 and the second sleeve plate 182 can be secured together using devices such as, but not limited to, fasteners, adhesives, welds, clips, snap-fit features and interference fits. It is also contemplated that one of the first sleeve plate 174 and the second sleeve plate 182 can be slightly larger or wider than the other sleeve plate 174, 182 such that one of the first sleeve plate 174 and the second sleeve plate 182 can be nested inside of the other sleeve plate 174, 182. It is contemplated that the first and second sleeve plates 174, 182 may be made of a metal, such as aluminum, or any other material that can function to evenly distribute heat from the defrost heater 194 into the housing 172, as described below.
A rectangular opening 176 (
Referring now to
The defrost heater 194 is a serpentine-shaped element that is disposed to one side of the evaporator 186. The defrost heater 194 is designed to apply heat to the evaporator 186 during a defrost cycle to metal ice/frost that may have accumulated on the evaporator 186. A plug mount 178 (
A safety bimetal switch (thermostat) 198 is attachable to the outlet line 186b of the evaporator 186. The bimetal switch 198 is connected in series with the defrost heater 194 for interrupting power to the defrost heater 194 when the bimetal switch 198 reaches a predetermined temperature during the defrost cycle. The bimetal switch 198, in general, is a switch that is designed to physically open a contact when the switch 198 reaches the predetermined temperature. The switch 198 acts as a safety switch to prevent the defrost heater 194 from heating the evaporator 186 to a temperature in excess of the predetermined temperature.
Referring to
The wiring harness 210 can be installed in the housing 110 and includes a plurality of connectors 212 that are individually configured for connecting to the motor 142, the fan 164, the plug 179 of the defrost heater 194 and the solenoid 202. A thermistor 196 is attached to one end of the wiring harness 210. The thermistor 196 is attachable to the inlet line 186a of the evaporator 186 for monitoring a temperature of the evaporator 186. Based on the temperature measured by the thermistor 196, a controller controls a defrost time of the defrost cycle. In particular, the controller monitors the temperature measured by the thermistor 196 and stops the defrost cycle when a predetermined temperature is reached.
An opposite end of the wiring harness 210 includes a plug 214 that is connectable to the controller for allowing the controller to control the operation of and/or receive signals from a respective component. The wiring harness 210 may also include a ground strap for grounding the motor 142 and the solenoid 202. The wiring harness 210 extends through the oblong opening 122 (
The air handler assembly 100 is assembled by feeding the wiring harness 210 through the oblong opening 122 in the housing 110 so that the connectors 212 are disposed within the interior cavity 113 of the housing 110 and the plug 214 is disposed outside of the housing 110. The connectors 212 of the wiring harness 210 are positioned within the housing 110 to connect to the respective components of the air handler assembly 100. The plug 214 on the opposite end of the wiring harness 210 is connected to the controller.
Referring now to
The auger motor assembly 140 is positioned in the lower cavity 115b of the housing 110. In particular, the auger motor assembly 140 is positioned within the housing 110 such that the drive shaft 146 (
As described in detail above, the open back 112 of the housing 110 of the air handler assembly 100 is dimensioned to receive the evaporator/defrost assembly 170. In particular, the evaporator/defrost assembly 170 is dimensioned and positioned such that the opening 176 in the first sleeve plate 174 aligns with the flow path extending under the auger motor assembly 140 from the lower opening 116 in the front face 111 of the housing 110. The opening 184 in the bottom of the housing 172 is positioned over the sump 132 of the housing 110.
The opening 177 in the top of the evaporator/defrost assembly 170 is disposed in an upper portion of the housing 110. In particular, the opening 177 is positioned proximate the opening 154 extending through the air duct 152.
The positioning of the foregoing components defines a cooling air flow path “A” through the air handler assembly 100. In particular, the cooling air flow path “A” extends from the lower opening 116 in the front face 111 of the housing 110, under the auger motor assembly 140, into the opening 176 of the housing 172 of the evaporator/defrost assembly 170, over the evaporator 186, out through the opening 177, through the opening 154 in the air duct 152 of the evaporator fan assembly 150, through the fan 164 and out of the housing 110 through the upper opening 114 in the front face 111. In this way, the chilled air is expelled via the opening 114 to flow directly over the ice maker and then flow downwards over the ice stored in the ice bin. Thereafter, the air flows back through the opening 116.
During operation of the ice maker 50, a refrigerant is conveyed through the evaporator 186 and the fan 164 is energized. The fan 164 causes air to flow along the cooling air path “A” such that air is drawn into a lower portion of the housing 110 from the ice bin 54 and conveyed over the evaporator 186. As the air passes over the evaporator 186, the refrigerant in the evaporator 186 draws heat from the air and causes the temperature of the air to decrease. This cooler air is then conveyed by the fan 164 out of the air handler assembly 100 and over the ice tray 64 to freeze water that may be disposed in the ice tray 64.
As the air handler assembly 100 continues to convey cool air to the ice tray 64, moisture in the air collects on the evaporator 186 and other components in the air handler assembly 100 and forms frost and/or ice. As described in detail above, the air duct 152 is positioned between the fan 164 and the evaporator 186. The air duct 152 is disposed in this position so that moisture that may have condensed on the fan 164 (if the fan 164 was immediately next to the evaporator 186) may now condense on the duct 152. In addition, as noted above, the upper gap 166a and the lower gap 166b are defined between the air duct 152 and the fan 164. The upper gap 166a and the lower gap 166b are dimensioned such that it is difficult for ice accumulating on the air duct 152 to migrate or expand across the gaps 166a, 166b and to the fan 164. The air duct 152, thus, helps to hinder the buildup of condensation and ice on the fan 164.
After a predetermined period of time, the controller of the refrigerator 10 initiates a defrost cycle to melt frost and/or ice that may have accumulated in the air handler assembly 100. The controller energizes the defrost heater 194 such that heat is generated within the housing 172 of the evaporator/defrost assembly 170. The first and second sleeve plates 174, 182 are designed to distribute heat around the evaporator 186 and decrease the time needed to melt the frost and/or ice on the evaporator 186. The heat generated by the defrost heater 194 also helps to melt frost and/or ice that may have accumulated in the air duct 152 and on the fan 164. The melting frost and/or ice on the evaporator 186 form drips or streams of water that fall to the lower portion of the housing 110. The water is directed to the opening 184 in the bottom of the housing 110 and collects in the sump 132.
In addition, melting frost and/or ice on the air duct 152 form drips or streams of water that are drained from the housing 110. As shown in
The controller continues the defrost cycle until the thermistor 196 reaches the predetermined temperature. The controller then de-energizes the defrost heater 194. In the event that a failure or some other condition occurs that does not allow the defrost heater 194 to be de-energized, the bimetal switch 198 of the evaporator/defrost assembly 170 is designed to interrupt the flow of electricity to the defrost heater 194 at a predetermined temperature.
Referring now to
The refrigerator 211 has a fresh food storage chamber 213 and a freezer storage chamber 215. The refrigerator 211 has an outer appliance housing or cabinet 217 within which the storage chambers 213, 215 are located. One or more inner liners 219 partially enclose and define the fresh food and freezer storage chambers 213, 215. Foamed-in insulation (not shown) is located between the appliance housing or cabinet 217 and the inner liner 219. A refrigeration circuit (not shown) cools the storage chambers 213, 215.
The refrigerator 211 includes movable closures (e.g., hinged doors 221, 223) for providing access to the fresh food storage chamber 213 and the freezer storage chamber 215, respectively. The hinged doors 221, 223 are movable between an open position providing access to a storage chamber (see
The doors 221, 223 each have an elongated handle 229, 231 mounted to the door, for opening and closing the door. The handles 229, 231 each operate a door lock, as discussed below. Attachment collars, which may be endcaps 233, 235 as shown in the figures (e.g.,
Since the handle 229, 231 must be manipulated to lock its corresponding door 221, 223 the door should not lock unexpectedly or automatically. Moreover, the combined axial and rotational movement of the handle 229, 231 can make it difficult for a child to the lock the doors 221, 223, especially if the appliance includes biasing mechanisms (e.g., a bias spring) that resist the axial displacement and rotation of the handle. The two motions required to lock the door 221, 223 can pose a complex difficulty for a child, and biasing mechanisms can make either movement of the handle (axial and/or rotational) physically difficult for a child to perform.
Various manipulations of the door handle 229, 231 could be employed to unlock the door. For example, a reverse, two-step axial translation and rotation could be required to unlock the door. Alternatively, the handle 229, 231 could be further rotated in the same direction used to lock the door 221, 223. For example, after moving the handle 229, 231 axially, rotating the handle 229, 231 clockwise to a first position locks the door 221, 223 and further rotation of the handle clockwise unlocks the door. If the handle 229, 231 is biased against rotation, requiring further rotation in the same direction used to lock the door 221, 223 and against the bias can make it difficult for a child to unlock the door. In addition to unlocking the door 221, 223 using the handle 229, 231, the refrigerator can include an interior release mechanism, to unlock the door from inside of the refrigerator.
The door handle 229, 231 can be mechanically coupled to operate a locking latch for the door 221, 223 as discussed below. Operations of the door handle 229, 231 and latch can be interlocked in other ways, such as electronically for example. Electronic interlocking between the handle and latch can include movements of the handle triggering a solenoid door latch.
Although other locations on the refrigerator are possible, the latch 247 for locking the door 221 is shown located at an upper portion of the refrigerator cabinet, at a higher elevation than the handle. The latch 247 is also located rearward of the handle 229, which is attached to the front of the door 221. The door 221 includes an internal rotatable linkage 249 within the door to transfer the rotation of the handle 229 to the latch 247. The internal rotatable linkage 249 and latch 247 have a periscope shape to transfer the rotation of the handle 229 upward and rearward toward the refrigerator cabinet. The internal rotatable linkage 249 is located within the door 221 to transfer internally, either partially or entirely within the door, the rotation of the handle 229 to the latch 247.
The latches 247 at the top of the internal rotatable linkages 249 are shown in
The upper end of the door handle 229 and lower end of the internal rotatable linkage 249 are shown in detail in
In certain embodiments, operation of the handles 229, 231 can assist in opening the respective door 221, 223. For example, operation of the handles via rotation and/or linear displacement can result in a pushing force being applied against the cabinet 217. The pushing force can result in the breaking of a seal formed between the doors 221, 223 and cabinet 217 when the doors are closed. The seal can be formed by a magnetic gasket located on the doors 221, 223 or cabinet. The pushing force can be applied by the latch 247 or other suitable structure (e.g., pushrod, cam surface, etc.) operatively coupled to the handles 229, 231.
The embodiment shown the figures uses a periscope-shaped internal rotatable linkage to address the vertical and horizontal offset between the handles 229, 231 and catches 251. In other embodiments, the handles can be aligned with the catches so that a periscope-shaped linkage is unnecessary. In further embodiments, the internal rotatable linkage can be eliminated and the latch can be directly operated by the engagement link, or the engagement link itself can include a latch for locking the door.
The doors 221, 223 are shown in the figures as being locked to the refrigerator cabinet. In other embodiments, the doors can be locked to each other, rather than to the cabinet. If the doors are locked to each other, only one of the door handles may be functional as a part of a handle-operated door lock.
Referring now to
In the embodiment shown, a frame 364 of the ice maker 350 is used to support the ice tray 362 and the ice level sensor assembly 370. It is contemplated that the ice level sensor assembly 370 could be mounted to a separate bracket/frame (not shown) so along as the ice level sensor assembly 370 is in the direct line of sight of the internal cavity 358 of the ice bin 354. In the embodiment shown, the ice level sensor assembly 370 is positioned a surface 364a of the frame 364. The surface 364a is dimensioned as described in detail below. The ice level sensor assembly 370 is positioned above the ice bin 354 when the ice bin 354 is fully inserted into the ice maker 350. The ice level sensor assembly 370 can be positioned to avoid contact with the ice bin 354 during insertion/removal of the ice bin 354 into/from the ice maker 350.
The ice level sensor assembly 370, in general, includes an emitter 372, a receiver 374 and a controller 380, all shown schematically in
The housing 376 is attached to the surface 364a of the frame 364. In the embodiment shown, the surface 364a is angled downward to aim the emitter 372 and the receiver 374 at a predetermined target area in the ice maker 350. The predetermined target area is selected as described in detail below.
It is contemplated that the emitter 372 can be a vertical-cavity surface emitting laser (VCSEL) diode light source that is configured to emit photons and the receiver 374 will count the photons emitted by the emitter 372. It is contemplated that the receiver 374 can be a photon avalanche diode (“SPAD”) or the like. The receiver 374 is positioned to detect the photon after it has reflected off an object. The emitter 372 and the receiver 374 are connected to the controller 380 (
In one embodiment, the controller 380 is a main system controller provided for controlling the operation of the refrigerator 10 (
The controller 380 may communicate with a user interface (not shown) for providing information to a user, e.g., the level of the ice pieces 352 in the ice bin 354, the absence or presence of the ice bin 354, etc. The user interface can be a simple LED display, buttons, knobs, a monitor and keypad/keyboard, a touch screen, etc. or combinations of the foregoing. Lastly, it is contemplated that the controller 380 or an attached component such as a network interface unit (not shown) can have network connectivity features, which may include any known or discovered wired or wireless network connectivity protocols (local area networks or wide area networks, including the internet), to provide remote control, status, or service features. Preferably, the wireless network connectivity protocols include WiFi, Bluetooth, NFC, ZigBee, etc.
During operation of the ice level sensor assembly 370, the emitter 372 will send out photons aimed at the predetermined target area. The predetermined target area is selected to allow the ice level sensor assembly 370 to detect at least one of the presence/absence of the ice bin 354 in the ice maker 350 and the level of the ice pieces 352 in the ice bin 354.
If an object, such as the ice piece 352 is disposed in the path of the photon emitted by the emitter 372, the photon will be reflected by the object to the receiver 374. The controller 380 is programmed to determine the distance travelled by the photon within a range of +/−1 mm based on the duration of time between when the photon was emitted by the emitter 372 and the time it was detected by the receiver 374. In other words, the ice level sensor assembly 370 performs a “time of flight” measurement of the photons emitted by the emitter 372 and subsequently detected by the receiver 374. The controller 380 is programmed such that the determined distance provides information, such as, (A) if the ice bin 354 is in place; and (B) the level of ice pieces 352 inside the ice bin 354.
Referring to
Referring to
Referring to
As described above, the controller 380 can be programmed to detect three specific conditions, (A) a full ice bin 354 (based on detecting the first predetermined distance); (B) an empty ice bin 354 (based on detecting the second predetermined distance); and (C) the ice bin 354 not disposed in the ice maker 350 (based on detecting the third predetermined distance). It is also contemplated that the controller 380 can be programmed to determine the amount of ice in the ice bin 354. Based on the first predetermined distance corresponding to a full ice bin 354 and the second predetermined distance corresponding to an empty ice bin 354, the controller 380 can be programmed to extrapolate the amount of ice in the ice bin 354 if the photon traveled a distance less than the second predetermined distance and greater than the first predetermined distance. It is contemplated that the controller 380 can be programmed to detect either an exact or an approximate amount (i.e., 25%, 50%, 75%, etc.) of ice pieces 352 in the ice bin 354. In other words, the controller 380 can be programmed to detect some variable amount of ices pieces 352 in the ice bin 354 between completely full and completely empty.
It is contemplated that the controller 380 can also be programmed to provide a signal to the user interface (not shown) that is indicative of the status of the ice bin 354, i.e., full, partially full, missing, etc. It is also contemplated that the controller 380 can be programmed to allow a user to select a desired level at which to maintain the ice pieces 352 in the ice bin 354. Upon detecting that the level of the ice pieces 352 in the ice bin 354 is at the desired level, the controller 380 can send a signal to the user interface and/or the main controller requesting that the ice maker 350 stop adding the ice pieces 352 to the ice bin 354. The desired level for the ice pieces 352 can be one of a plurality of preset ice levels or a level that is variable within a predetermined range. Upon detecting that the level of the ice pieces 352 in the ice bin 354 is below the desired level, the controller 380 can send a signal to the user interface and/or the main controller requesting that the ice maker 350 produce and add the ice pieces 352 to the ice bin 354.
It is contemplated that the ice level sensor assembly 370 can be calibrated for use with ice bins 354 of various sizes by making changes in the software in the controller 380. It is contemplated that the changes to the software can include changing the predetermined first, second and third distances to correspond to the ice bin 354 and the ice maker 350.
In the present application there is provided an ice maker for freezing water into ice pieces, the ice maker including: an ice tray for forming ice pieces; an ice bin for receiving and storing ice pieces produced by the ice tray; and an air handler assembly for conveying cooling air through the ice tray and the ice bin. The air handler assembly includes: an evaporator for cooling air conveyed through the ice tray and the ice bin, a fan for conveying the cooled air, and an air duct disposed between the evaporator and the fan for preventing the migration of ice from the evaporator to the fan, the air duct having an opening extending from an end adjacent the evaporator to an end adjacent the fan and a lower inner wall of the air duct have a first downward ramped portion on the end adjacent the evaporator.
In the foregoing ice maker for freezing water into ice pieces, the air duct is made from an insulating material.
In the foregoing ice maker for freezing water into ice pieces, the air duct is between about 2 inches and about 5 inches in length.
In the foregoing ice maker for freezing water into ice pieces, the air duct is about 3 inches in length.
In the present application, there is also provided an air handler assembly for conveying cooling air through an ice tray and an ice bin of an ice maker, the air handler assembly including: an evaporator for cooling air conveyed through the ice tray and the ice bin, a fan for conveying the cooled air, and an air duct disposed between the evaporator and the fan for preventing the migration of ice from the evaporator to the fan, the air duct having an opening extending from an end adjacent the evaporator to an end adjacent the fan and a lower inner wall of the air duct have a first downward ramped portion on the end adjacent the evaporator.
In the foregoing air handler assembly for conveying cooling air through an ice tray and an ice bin of an ice maker, the lower inner wall of the air duct further comprises a second downward ramped portion on the end adjacent the fan.
In air handler assembly for conveying cooling air through an ice tray and an ice bin of an ice maker, the second downward ramped portion is shorter than the first downward ramped portion.
In air handler assembly for conveying cooling air through an ice tray and an ice bin of an ice maker, a slope of the second downward ramped portion is greater than a slope of the first downward ramped portion.
In addition or alternatively, the ice maker of the present application may further be adapted to mounting and use on a freezer door. In this configuration, although still disposed within the freezer compartment, at least the ice maker (and possibly an ice bin) is mounted to the interior surface of the freezer door. It is contemplated that the ice mold and ice bin can be separated elements, in which one remains within the freezer cabinet and the other is on the freezer door.
Cold air can be ducted to the freezer door from an evaporator in the fresh food or freezer compartment, including the system evaporator. The cold air can be ducted in various configurations, such as ducts that extend on or in the freezer door, or possibly ducts that are positioned on or in the sidewalls of the freezer liner or the ceiling of the freezer liner. In one example, a cold air duct can extend across the ceiling of the freezer compartment, and can have an end adjacent to the ice maker (when the freezer door is in the closed condition) that discharges cold air over and across the ice mold. If an ice bin is also located on the interior of the freezer door, the cold air can flow downwards across the ice bin to maintain the ice pieces at a frozen state. The cold air can then be returned to the freezer compartment via a duct extending back to the evaporator of the freezer compartment. A similar ducting configuration can also be used where the cold air is transferred via ducts on or in the freezer door. The ice mold can be rotated to an inverted state for ice harvesting (via gravity or a twist-tray) or may include a sweeper-finger type, and a heater can be similarly used. It is further contemplated that although cold air ducting from the freezer evaporator as described herein may not be used, a thermoelectric chiller or other alternative chilling device or heat exchanger using various gaseous and/or liquid fluids could be used in its place. In yet another alternative, a heat pipe or other thermal transfer body can be used that is chilled, directly or indirectly, by the ducted cold air to facilitate and/or accelerate ice formation in the ice mold. Of course, it is contemplated that the ice maker of the instant application could similarly be adapted for mounting and use on a freezer drawer.
Alternatively, it is further contemplated that the ice maker of the instant application could be used in a fresh food compartment, either within the interior of the cabinet or on a fresh food door. It is contemplated that the ice mold and ice bin can be separated elements, in which one remains within the fresh food cabinet and the other is on the fresh food door.
In addition or alternatively, cold air can be ducted from another evaporator in the fresh food or freezer compartment, such as the system evaporator. The cold air can be ducted in various configurations, such as ducts that extend on or in the fresh food door, or possibly ducts that are positioned on or in the sidewalls of the fresh food liner or the ceiling of the fresh food liner. In one example, a cold air duct can extend across the ceiling of the fresh food compartment, and can have an end adjacent to the ice maker (when the fresh food door is in the closed condition) that discharges cold air over and across the ice mold. If an ice bin is also located on the interior of the fresh food door, the cold air can flow downwards across the ice bin to maintain the ice pieces at a frozen state. The cold air can then be returned to the fresh food compartment via a ducting extending back to the compartment with the associated evaporator, such as a dedicated icemaker evaporator compartment or the freezer compartment. A similar ducting configuration can also be used where the cold air is transferred via ducts on or in the fresh food door. The ice mold can be rotated to an inverted state for ice harvesting (via gravity or a twist-tray) or may include a sweeper-finger type, and a heater can be similarly used. It is further contemplated that although cold air ducting from the freezer evaporator (or similarly a fresh food evaporator) as described herein may not be used, a thermoelectric chiller or other alternative chilling device or heat exchanger using various gaseous and/or liquid fluids could be used in its place. In yet another alternative, a heat pipe or other thermal transfer body can be used that is chilled, directly or indirectly, by the ducted cold air to facilitate and/or accelerate ice formation in the ice mold. Of course, it is contemplated that the ice maker of the instant application could similarly be adapted for mounting and use on a fresh food drawer.
The invention has been described with reference to the example embodiments described above. Modifications and alterations will occur to others upon a reading and understanding of this specification. Examples embodiments incorporating one or more aspects of the invention are intended to include all such modifications and alterations insofar as they come within the scope of the appended claims.
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