ICE MAKING ASSEMBLY WITH CHILLED RESERVOIR

Abstract

An ice making assembly includes a mold assembly with a mold cavity defined in the mold assembly. The ice making assembly also includes a reservoir in fluid communication with the mold assembly to provide a flow of liquid water to the mold cavity defined in the mold assembly. The ice making assembly further includes a thermally conductive element positioned at least partially in the reservoir. The thermally conductive element receives a flow of chilled air from the sealed system, such that the liquid water in the reservoir is chilled by the chilled air via the thermally conductive element.

Description

FIELD OF THE INVENTION

The present subject matter relates generally to ice making appliances, and more particularly to ice making appliances which include a reservoir for liquid water in fluid communication with one or more additional components of the ice making appliance, such as a mold assembly and/or mold cavity.

BACKGROUND OF THE INVENTION

In domestic and commercial applications, ice is often formed as solid cubes, such as crescent cubes or generally rectangular blocks. The shape of such cubes is often dictated by the container holding water during a freezing process. For instance, an ice maker can receive liquid water, and such liquid water can freeze within the ice maker to form ice cubes. In particular, certain ice makers include a freezing mold that defines a plurality of cavities. The plurality of cavities can be filled with liquid water that stays static within the cavities and can freeze within the plurality of cavities to form solid ice cubes. Typical solid cubes or blocks may be relatively small in order to accommodate a large number of uses, such as temporary cold storage and rapid cooling of liquids in a wide range of sizes.

Although the typical solid cubes or blocks may be useful in a variety of circumstances, they may have certain drawbacks. For instance, such typical cubes or blocks can be cloudy, e.g., less than fully transparent, such as partially translucent and partially transparent, due to impurities found within the freezing mold or water. As a result, certain consumers prefer clear ice. In clear ice formation processes, dissolved solids typically found within water (e.g., tap water) are separated out and essentially pure water freezes to form the clear ice. Since the water in clear ice is purer than that found in typical cloudy ice, clear ice is less likely to affect drink flavors.

Additionally or alternatively, typical cubes or blocks may have a size or shape that is undesirable in certain conditions. There are certain conditions in which distinct or unique ice shapes may be desirable. Specifically, relatively large or rounded ice billets or gems (e.g., around two inches in diameter) will melt slower than typical ice sizes/shapes. Slow melting of ice may be especially desirable in certain liquors or cocktails. Moreover, such billets or gems may provide a unique or upscale impression for the user.

Accordingly, further improvements in the field of ice making and refrigerator appliances would be desirable. In particular, it may be desirable to provide a refrigerator appliance capable of reliably and efficiently producing substantially clear ice billets.

BRIEF DESCRIPTION OF THE INVENTION

Aspects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.

In one exemplary aspect of the present disclosure, a refrigerator appliance is provided. The refrigerator appliance includes a cabinet, a liner, a sealed system, and an ice making assembly. The liner is attached to the cabinet and defines an icebox (TB) compartment. The sealed system is mounted to the cabinet to selectively cool the IB compartment. The ice making assembly includes a mold assembly with a mold cavity defined in the mold assembly. The ice making assembly also includes a reservoir in fluid communication with the mold assembly to provide a flow of liquid water to the mold cavity defined in the mold assembly. The ice making assembly further includes a thermally conductive element positioned at least partially in the reservoir. The thermally conductive element receives a flow of chilled air from the sealed system, such that the liquid water in the reservoir is chilled by the chilled air via the thermally conductive element.

In another exemplary aspect of the present disclosure, an ice making assembly is provided. The ice making assembly includes a mold assembly with a mold cavity defined in the mold assembly. The ice making assembly also includes a reservoir in fluid communication with the mold assembly to provide a flow of liquid water to the mold cavity defined in the mold assembly. The ice making assembly further includes a thermally conductive element positioned at least partially in the reservoir. The thermally conductive element receives a flow of chilled air from the sealed system, such that the liquid water in the reservoir is chilled by the chilled air via the thermally conductive element.

These and other features, aspects and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

A full and enabling disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended figures.

FIG. 1 provides a perspective view of a refrigerator appliance according to exemplary embodiments of the present subject disclosure.

FIG. 2 provides a front view of the exemplary refrigerator appliance of FIG. 1 with the refrigerator and freezer doors shown in an open position.

FIG. 3 provides a perspective view of a freezer chamber of the exemplary refrigerator appliance of FIG. 1 with the freezer doors and storage bins removed for clarity.

FIG. 4 provides a front elevation view of the exemplary freezer chamber of FIG. 3.

FIG. 5 provides a schematic view of a sealed cooling system of the exemplary refrigerator appliance of FIG. 1.

FIG. 6 provides a front elevation view of an ice making assembly within an icebox compartment of the exemplary refrigerator appliance of FIG. 2.

FIG. 7 provides a side sectional view of a portion of the ice making assembly and icebox compartment of the FIG. 6.

FIG. 8 provides a schematic view of an ice making assembly according to exemplary embodiments of the present disclosure.

FIG. 9 provides a bottom perspective view of an ice mold according to exemplary embodiments of the present disclosure.

FIG. 10 provides a perspective view of a water dispensing assembly according to exemplary embodiments of the present disclosure.

FIG. 11 provides a top perspective view of an ice building unit according to exemplary embodiments of the present disclosure.

FIG. 12 provides an elevation view of the exemplary water dispensing assembly of FIG. 10.

FIG. 13 provides an exploded perspective view of the exemplary ice building unit of FIG. 11.

FIG. 14 provides a schematic view of a reservoir of an ice making assembly and an exemplary thermally conductive element for chilling liquid water in the reservoir according to exemplary embodiments of the present disclosure.

FIG. 15 provides a perspective view of an exemplary thermally conductive element according to exemplary embodiments of the present disclosure.

FIG. 16 provides a perspective view of a portion of another exemplary thermally conductive element according to exemplary embodiments of the present disclosure.

FIG. 17 provides a schematic section view of yet another exemplary thermally conductive element according to exemplary embodiments of the present disclosure.

FIG. 18 provides a schematic view of a reservoir of an ice making assembly and another exemplary thermally conductive element for chilling liquid water in the reservoir according to exemplary embodiments of the present disclosure.

FIG. 19 provides a schematic view of a reservoir of an ice making assembly and still another exemplary thermally conductive element for chilling liquid water in the reservoir according to exemplary embodiments of the present disclosure.

DETAILED DESCRIPTION

Reference now will be made in detail to embodiments of the invention, one or more examples of which are illustrated in the drawings. The detailed description uses numerical and letter designations to refer to features in the drawings. Like or similar designations in the drawings and description have been used to refer to like or similar parts of the disclosure. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the invention. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present invention covers such modifications and variations as come within the scope of the appended claims and their equivalents.

As used herein, the term “or” is generally intended to be inclusive (i.e., “A or B” is intended to mean “A or B or both”). The phrase “in one embodiment,” does not necessarily refer to the same embodiment, although it may.

The terms “first,” “second,” and “third” may be used interchangeably to distinguish one component from another and are not intended to signify location or importance of the individual components. The terms “upstream” and “downstream” refer to the relative flow direction with respect to fluid flow in a fluid pathway. For example, “upstream” refers to the flow direction from which the fluid flows, and “downstream” refers to the flow direction to which the fluid flows.

As used herein, terms of approximation, such as “generally,” or “about” include values within ten percent greater or less than the stated value. When used in the context of an angle or direction, such terms include within ten degrees greater or less than the stated angle or direction. For example, “generally vertical” includes directions within ten degrees of vertical in any direction, e.g., clockwise or counter-clockwise.

FIG. 1 provides a perspective view of a refrigerator appliance 100 according to an exemplary embodiment of the present subject matter. Refrigerator appliance 100 includes a cabinet or housing 102 that extends between a top 104 and a bottom 106 along a vertical direction V, between a first side 108 and a second side 110 along a lateral direction L, and between a front side 112 and a rear side 114 along a transverse direction T. Each of the vertical direction V, lateral direction L, and transverse direction T are mutually perpendicular to one another.

Housing 102 defines chilled chambers for receipt of food items for storage. In particular, housing 102 defines fresh food chamber 122 positioned at or adjacent top 104 of housing 102 and a freezer chamber 124 arranged at or adjacent bottom 106 of housing 102. As such, refrigerator appliance 100 is generally referred to as a bottom mount refrigerator. It is recognized, however, that the benefits of the present disclosure apply to other types and styles of refrigerator appliances such as, e.g., a top mount refrigerator appliance or a side-by-side style refrigerator appliance. Consequently, the description set forth herein is for illustrative purposes only and is not intended to be limiting in any aspect to any particular refrigerator chamber configuration. Additionally, it should be understood that the ice making assembly described hereinbelow may be provided in a variety of appliances, such as a standalone ice making appliance, among numerous other possible examples.

Refrigerator doors 128 are rotatably hinged to an edge of housing 102 for selectively accessing fresh food chamber 122. Similarly, freezer doors 130 are rotatably hinged to an edge of housing 102 for selectively accessing freezer chamber 124. To prevent leakage of cool air, refrigerator doors 128, freezer doors 130, or housing 102 may define one or more sealing mechanisms (e.g., rubber gaskets, not shown) at the interface where the doors 128, 130 meet housing 102. Refrigerator doors 128 and freezer doors 130 are shown in the closed configuration in FIG. 1 and in the open configuration in FIG. 2. It should be appreciated that doors having a different style, position, or configuration are possible and within the scope of the present subject matter.

Refrigerator appliance 100 also includes a dispensing assembly 132 for dispensing liquid water or ice. Dispensing assembly 132 includes a dispenser 134 positioned on or mounted to an exterior portion of refrigerator appliance 100, e.g., on one of refrigerator doors 128. Dispenser 134 includes a discharging outlet 136 for accessing ice and liquid water. An actuating mechanism 138, shown as a paddle, is mounted below discharging outlet 136 for operating dispenser 134. In alternative exemplary embodiments, any suitable actuating mechanism may be used to operate dispenser 134. For example, dispenser 134 can include a sensor (such as an ultrasonic sensor) or a button rather than the paddle. A control panel 140 is provided for controlling the mode of operation. For example, control panel 140 includes a plurality of user inputs (not labeled), such as a water dispensing button and an ice-dispensing button, for selecting a desired mode of operation such as crushed or non-crushed ice.

Discharging outlet 136 and actuating mechanism 138 are an external part of dispenser 134 and are mounted in a dispenser recess 142. Dispenser recess 142 is positioned at a predetermined elevation convenient for a user to access ice or water and enabling the user to access ice without the need to bend-over and without the need to open refrigerator doors 128. In the exemplary embodiment, dispenser recess 142 is positioned at a level that approximates the chest level of a user. According to an exemplary embodiment, the dispensing assembly 132 may receive ice from an icemaker or ice making assembly 300 disposed in a sub-compartment of the refrigerator appliance 100 (e.g., icebox compartment 180).

Refrigerator appliance 100 further includes a controller 144. Operation of the refrigerator appliance 100 is regulated by controller 144 that is operatively coupled to or in operative communication with control panel 140. In one exemplary embodiment, control panel 140 may represent a general purpose I/O (“GPIO”) device or functional block. In another exemplary embodiment, control panel 140 may include input components, such as one or more of a variety of electrical, mechanical or electro-mechanical input devices including rotary dials, push buttons, touch pads, or touch screens. Control panel 140 may be in communication with controller 144 via one or more signal lines or shared communication busses. Control panel 140 provides selections for user manipulation of the operation of refrigerator appliance 100. In response to user manipulation of the control panel 140, controller 144 operates various components of refrigerator appliance 100. For example, controller 144 is operatively coupled or in communication with various components of a sealed system, as discussed below. Controller 144 may also be in communication with a variety of sensors, such as, for example, chamber temperature sensors or ambient temperature sensors. Controller 144 may receive signals from these temperature sensors that correspond to the temperature of an atmosphere or air within their respective locations.

In some embodiments, controller 144 includes memory and one or more processing devices such as microprocessors, CPUs or the like, such as general or special purpose microprocessors operable to execute programming instructions or micro-control code associated with operation of refrigerator appliance 100. The memory can represent random access memory such as DRAM, or read only memory such as ROM or FLASH. The processor executes programming instructions stored in the memory. The memory can be a separate component from the processor or can be included onboard within the processor. Alternatively, controller 144 may be constructed without using a microprocessor (e.g., using a combination of discrete analog or digital logic circuitry; such as switches, amplifiers, integrators, comparators, flip-flops, AND gates, and the like; to perform control functionality instead of relying upon software).

FIG. 2 provides a front view of refrigerator appliance 100 with refrigerator doors 128 and freezer doors 130 shown in an open position. According to the illustrated embodiment, various storage components are mounted within fresh food chamber 122 and freezer chamber 124 to facilitate storage of food items therein as will be understood by those skilled in the art. In particular, the storage components include bins 146, drawers 148, and shelves 150 that are mounted within fresh food chamber 122 or freezer chamber 124. Bins 146, drawers 148, and shelves 150 are configured for receipt of food items (e.g., beverages or solid food items) and may assist with organizing such food items. As an example, drawers 148 can receive fresh food items (e.g., vegetables, fruits, or cheeses) and increase the useful life of such fresh food items.

Referring now to FIGS. 3 and 4, freezer chamber 124 will be described according to exemplary embodiments of the present disclosure. As illustrated, cabinet or housing 102 includes an inner liner 160 which defines freezer chamber 124. For example, inner liner 160 may be an injection-molded door liner attached to an inside of housing 102. Insulation (not shown), such as expandable foam can be present between housing 102 and inner liner 160 in order to assist with insulating freezer chamber 124. For example, sprayed polyurethane foam may be injected into a cavity defined between housing 102 and inner liner 160 after they are assembled. Freezer doors 130 may be constructed in a similar manner to assist in insulating freezer chamber 124.

Freezer chamber 124 generally extends between a left wall 162 and a right wall 164 along the lateral direction L, between a bottom wall 166 and a top wall 168 along the vertical direction V, and between a chamber opening 170 and a back wall 172 along the transverse direction T. In some embodiments, refrigerator appliance 100 further includes a mullion 176 positioned within freezer chamber 124 to divide freezer chamber 124 into a pair of discrete sub-compartments, such as an icebox (IB) compartment 180 and a dedicated freezer (Fz) compartment 182. According to the illustrated embodiment, mullion 176 generally extends between chamber opening 170 and back wall 172 along the transverse direction T and between bottom wall 166 and top wall 168 along the vertical direction V. In this manner, mullion 176 is generally vertically-oriented and may split freezer chamber 124 into two equally-sized compartments 180, 182. Nonetheless, it should be appreciated that mullion 176 may be sized, positioned, and configured in any suitable manner to form separate freezer sub-compartments within freezer chamber 124. Moreover, alternative embodiments may be provided without any such mullion.

To limit heat transfer between IB compartment 180 and Fz compartment 182, mullion 176 may generally be formed from an insulating material such as foam. In addition, to provide structural support, a rigid injection molded liner or a metal frame may surround the insulating foam. According to another exemplary embodiment, mullion 176 may be a vacuum insulated panel or may contain a vacuum insulated panel to minimize heat transfer between IB compartment 180 and Fz compartment 182. Optionally, inner liner 160 or mullion 176 may include features such as guides or slides to ensure proper positioning, installation, and sealing of mullion 176 within inner liner 160.

Referring now to FIG. 5, a schematic view of an exemplary sealed system 190 which may be used to cool freezer chamber 124 will be described. Sealed system 190 is generally configured for executing a vapor compression cycle for cooling air within refrigerator appliance 100 (e.g., within fresh food chamber 122 or freezer chamber 124). Sealed cooling system 190 includes a compressor 192, a condenser 194, an expansion device 196, and an evaporator 198 connected in fluid communication (e.g., in series) with each other and charged with a refrigerant.

During operation of sealed system 190, gaseous refrigerant flows into compressor 192, which operates to increase the pressure of the refrigerant and motivate refrigerant through sealed system 190. This compression of the refrigerant raises its temperature, which is lowered by passing the gaseous refrigerant through condenser 194. Within condenser 194, heat exchange with ambient air takes place so as to cool the refrigerant and cause the refrigerant to condense to a liquid state.

Expansion device (e.g., an expansion valve, capillary tube, or other expansion device) 196 receives liquid refrigerant from condenser 194. From expansion device 196, the liquid refrigerant enters evaporator 198. Upon exiting expansion device 196 and entering evaporator 198, the liquid refrigerant drops in pressure and vaporizes. Due to the pressure drop and phase change of the refrigerant, evaporator 198 is cool relative to fresh food and freezer chambers 122 and 124 of refrigerator appliance 100. As such, cooled air is produced and refrigerates fresh food and freezer chambers 122 and 124 of refrigerator appliance 100. Thus, evaporator 198 is a type of heat exchanger which transfers heat from air passing over evaporator 198 to refrigerant flowing through evaporator 198.

It should be appreciated that the illustrated sealed system 190 is only one exemplary configuration of sealed system 190 which may include additional components (e.g., one or more additional evaporators, compressors, expansion devices, or condensers). As an example, sealed cooling system 190 may include two evaporators. As a further example, sealed system 190 may further include an accumulator 199. Accumulator 199 may be positioned downstream of evaporator 198 and may be configured to collect condensed refrigerant from the refrigerant stream prior to passing it to compressor 192.

Referring again generally to FIGS. 3 and 4, in some embodiments, evaporator 198 is positioned adjacent back wall 172 of inner liner 160. The remaining components of sealed system 190 may be located within a machinery compartment 200 of refrigerator appliance 100. A conduit 202 may pass refrigerant into freezer chamber 124 to evaporator 198 through a fluid tight inlet and may pass refrigerant from evaporator 198 out of freezer chamber 124 through a fluid tight outlet.

According to the illustrated embodiments, evaporator 198 includes a first evaporator section 204 and a second evaporator section 206. First evaporator section 204 and second evaporator section 206 are connected in series such that refrigerant passes first through first evaporator section 204 before second evaporator section 206. More specifically, according to the illustrated embodiment, first evaporator section 204 and second evaporator section 206 are coupled by a transition tube 208. Transition tube 208 may be a separate connecting conduit or a part of the same tube forming evaporator 198. As illustrated, first evaporator section 204 is positioned within IB compartment 180 and second evaporator section 206 is positioned within Fz compartment 182. In this regard, transition tube 208 may pass through an aperture in mullion 176.

An evaporator cover may be placed over evaporator 198 to form an evaporator chamber with inner liner 160. For example, as illustrated, a first evaporator cover 220 is positioned within IB compartment 180 over evaporator 198, or more specifically, over first evaporator section 204. In this manner, inner liner 160, mullion 176, and first evaporator cover 220 define a first evaporator chamber 222 which houses first evaporator section 204. Similarly, a second evaporator cover 224 is positioned within Fz compartment 182 over evaporator 198, or more specifically, over second evaporator section 206. In this manner, inner liner 160, mullion 176, and second evaporator cover 224 define a second evaporator chamber 226 which houses second evaporator section 206.

Evaporator chambers 222, 226 may include one or more return ducts and supply ducts to allow air to circulate to and from IB compartment 180 and Fz compartment 182 (e.g., along one or more air paths). In exemplary embodiments, first evaporator cover 220 defines one or more first return ducts 230 for allowing air to enter first evaporator chamber 222 and one or more first supply ducts 232 for exhausting air out of first evaporator chamber 222 into IB compartment 180 (e.g., along a first air path 250). Additionally or alternatively, second evaporator cover 224 may define one or more second return ducts 234 for allowing air to enter second evaporator chamber 226 and one or more second supply ducts 236 for exhausting air out of second evaporator chamber 226 into Fz compartment 182 (e.g., along a second air path 252). According to the illustrated embodiment, a first return duct 230 and a second return duct 234 are positioned proximate a bottom of freezer chamber 124 (e.g., proximate bottom wall 166) and a first supply duct 232 and a second supply duct 236 are positioned proximate a top of freezer chamber 124 (e.g., proximate top wall 168). It should be appreciated, however, that according to alternative embodiments, any other suitable means for providing fluid communication between the evaporator chambers and the freezer compartments are possible and within the scope of the present disclosure.

Refrigerator appliance 100 may include one or more fans to assist in circulating air through evaporator 198 and chilling freezer compartments 180, 182. For example, according to the illustrated exemplary embodiment refrigerator appliance 100 includes a first fan 240 in fluid communication with first evaporator chamber 222 for urging air through first evaporator chamber 222. Optionally, first fan 240 may be an axial fan positioned within a first supply duct 232 for urging chilled air from first evaporator chamber 222 into IB compartment 180 through a first supply duct 232 while recirculating air through a first return duct 230 back into first evaporator chamber 222 to be re-cooled. Additionally or alternatively, refrigerator appliance 100 may include a second fan 242 in fluid communication with second evaporator chamber 226 for urging air through second evaporator chamber 226. Optionally, second fan 242 may be an axial fan positioned within a second supply duct 236 for circulating air between second evaporator chamber 226 and Fz compartment 182, as described above.

Turning especially to FIGS. 6 through 8, an ice making assembly 300 may be mounted within IB compartment 180. Generally, ice making assembly 300 includes a mold assembly 310 that defines a mold cavity 318 within which an ice billet 320 may be formed. Optionally, a plurality of mold cavities 318 may be defined by mold assembly 310 (e.g., as discrete or connected ice building units 312) and spaced apart from each other (e.g., perpendicular to the vertical direction V, such as along the lateral direction L). Generally, mold assembly 310 may be positioned along the air path 250 within IB compartment 180 between a supply duct 232 and a return duct 230. In some such embodiments, mold assembly 310 is vertically positioned between supply duct 232 and return duct 230.

As will be described in further detail below, mold assembly 310 may further include a thermal electric heat exchanger (TEHE) mounted thereon (e.g., in conductive thermal communication with each discrete ice building unit 312). Generally, TEHE 348 may be any suitable solid state, electrically-driven heat exchanger, such as a Peltier device. TEHE 348 may include a first heat exchange end and a second heat exchange end. When activated, heat may be selectively directed between the ends. In particular, a heat flux created between the junction of the ends may draw heat from one end to the other end (e.g., as driven by an electrical current). In some embodiments, TEHE 348 is operably coupled (e.g., electrically coupled) to a controller 144, which may thus control the flow of current to TEHE 348. During use, TEHE 348 may selectively draw heat from mold cavity 318, as will be further described below.

A water dispenser 314 positioned below mold assembly 310 may generally act to selectively direct the flow of water into mold cavity 318. Generally, water dispenser 314 includes a water pump 322 and at least one nozzle 324 directed (e.g., vertically) toward mold cavity 318. In embodiments wherein multiple discrete mold cavities 318 are defined by mold assembly 310, water dispenser 314 may include a plurality of nozzles 324 or fluid pumps vertically aligned with the plurality mold cavities 318. For instance, each mold cavity 318 may be vertically aligned with a discrete nozzle 324.

In some embodiments, a water basin or reservoir 316 is positioned below the ice mold 340 (e.g., directly beneath mold cavity 318 along the vertical direction V). Reservoir 316 includes a solid nonpermeable body and may define a vertical opening and interior volume 328 in fluid communication with mold cavity 318. When assembled, fluids, such as excess water falling from mold cavity 318, may pass into interior volume 328 of reservoir 316 through the vertical opening. Optionally, a drain conduit may be connected to reservoir 316 to draw collected water from the reservoir 316 and out of IB compartment.

In certain embodiments, a guide ramp 330 is positioned between mold assembly 310 and reservoir 316 along the vertical direction V. For example, guide ramp 330 may include a ramp surface that extends at a negative angle (e.g., relative to a horizontal direction, such as the transverse direction T) from a location beneath mold cavity 318 to another location spaced apart from reservoir 316 (e.g., horizontally). In some such embodiments, guide ramp 330 extends to or terminates above an ice bin 332 (e.g., within IB compartment 180). Optionally, guide ramp 330 may define a perforated portion that is, for example, vertically aligned between mold cavity 318 and nozzle 324 or between mold cavity 318 and interior volume 328. One or more apertures are generally defined through guide ramp 330 at perforated portion. Fluids, such as water, may thus generally pass through perforated portion of guide ramp 330 (e.g., along the vertical direction V between mold cavity 318 and interior volume 328).

In exemplary embodiments, ice bin 332 generally defines a storage volume 336 and may be positioned below mold assembly 310 and mold cavity 318. Ice billets 320 formed within mold cavity 318 may be expelled from mold assembly 310 and subsequently stored within storage volume 336 of ice bin 332 (e.g., within IB compartment 180). In some such embodiments, ice bin 332 is positioned within IB compartment 180 and horizontally spaced apart from water dispenser 314 or mold assembly 310. Guide ramp 330 may span a horizontal distance above or to ice bin 332 (e.g., from mold assembly). As ice billets 320 descend or fall from mold cavity 318, the ice billets 320 may thus be motivated (e.g., by gravity) toward ice bin 322.

As shown, controller 144 may be in communication (e.g., electrical communication) with one or more portions of ice making assembly 300. In some embodiments, controller 144 is in communication with one or more fluid pumps (e.g., water pump 322), TEHE 348, and fan 240. Controller 144 may be configured to initiate discrete ice making operations and ice release operations. For instance, controller 144 may alternate the fluid source spray to mold cavity 318 and a release or ice harvest process, which will be described in more detail below.

During ice making operations, controller 144 may initiate or direct water dispenser 314 to motivate an ice-building spray (e.g., as indicated at arrows 346) through nozzle 324 and into mold cavity 318 (e.g., a through mold opening at the bottom end of mold cavity 318). Controller 144 may further direct fan 240 to motivate a chilled airflow (e.g., from sealed system 190, such as evaporator section 204 thereof, along the air path 250) to convectively draw heat from within mold cavity 318 during the ice building spray 346. As the water from the ice-building spray 346 strikes mold assembly 310 within mold cavity 318, a portion of the water may freeze in progressive layers from top end 344 to a bottom end of mold cavity 318. Excess water (e.g., water within mold cavity 318 that does not freeze upon contact with mold assembly 310 or the frozen volume therein) and impurities within the ice-building spray 346 may fall from mold cavity 318 and, for example, to reservoir 316. After an initial portion of ice has formed within the mold cavity 318, controller 144 may activate the TEHE 348 to further draw heat from the ice mold cavity 318, thereby accelerating freezing of ice billet 320, notably, without requiring a significant power draw.

Once an ice billet 320 is formed within mold cavity 318, an ice release or harvest process may be performed in accordance with embodiments of the present disclosure. For instance, fan 240 may be restricted or halted to slow/stop the active chilled airflow. Moreover, controller 144 may first halt or prevent the ice-building spray 346 by de-energizing water pump 322. Additionally or alternatively, an electrical current to the TEHE 348 may be reversed such that heat is delivered to mold cavity 318 from TEHE 348. Thus, controller 144 may slowly increase a temperature TEHE 348 and ice mold 340, thereby facilitating partial melting or release of ice billets 320 from mold cavities 318.

Turning now especially to FIGS. 9, 11, and 13, ice mold 340 may include a top wall 344 and a plurality of sidewalls 350 that are cantilevered from top wall 344 and extend downward from top wall 344. More specifically, according to the illustrated embodiment, ice mold 340 includes eight sidewalls 350 that include an angled portion 352 that extends away from top wall 344 and a vertical portion 354 that extends down from angled portion 352 substantially along the vertical direction. In this manner, the top wall 344 and the plurality of sidewalls 350 form a mold cavity 318 having an octagonal cross-section when viewed in a horizontal plane. In addition, each of the plurality of sidewalls 350 may be separated by a gap 358 that extends substantially along the vertical direction V. In this manner, the plurality of sidewalls 350 may move relative to each other and act as spring fingers to permit some flexing of ice mold 340 during ice formation. Notably, this flexibility of ice mold 340 facilitates improved ice formation and reduces the likelihood of cracking.

In general, ice mold 340 may be formed from any suitable material and in any suitable manner that provides sufficient thermal conductivity to transfer heat to the surrounding environment and TEHE 348 to facilitate the ice making process. According to an exemplary embodiment, ice mold 340 is formed from a single sheet of copper. In this regard, for example, a flat sheet of copper having a constant thickness may be machined to define top wall 344 and sidewalls 350. Sidewalls 350 may be subsequently bent to form the desired shape of mold cavity 318 (e.g., such as the octagonal or gem shape described above). In this manner, top wall 344 and sidewalls 350 may be formed to have an identical thickness without requiring complex and costly machining processes.

According to exemplary embodiments of the present disclosure, TEHE 348 is mounted in direct contact with the top wall 344 of ice mold 340. In addition, TEHE 348 may not be in direct contact with sidewalls 350. This may be desirable, for example, to prevent restricting the movement of sidewalls 350 (e.g., to reduce to the likelihood of ice cracking). Notably, when TEHE 348 is mounted only on top wall 344, the conductive path to each of the plurality of sidewalls 350 is through the joint or connection where sidewalls 350 meet top wall 344.

In addition, to improve the thermal contact between TEHE 348 and ice mold 340, it may be desirable to make top wall 344 relatively large. Therefore, according to exemplary embodiments, top wall 344 may define a top width 362 and mold cavity 318 may define a max width 364. According to exemplary embodiments, top width 362 is greater than about 50% of max width 364. According to still other embodiments, top width 362 may be greater than about 60%, greater than about 70%, greater than about 80%, or greater, of max width 364. In addition, or alternatively, top width 362 may be less than 90%, less than 70%, less than 60%, less than 50%, or less, of max width 364. It should be appreciated that other suitable sizes, geometries, and configurations of ice mold 340 are possible and within the scope of the present disclosure.

Referring especially to FIGS. 11 and 13, a discrete TEHE 348 may be disposed on each discrete ice building unit 312 above the corresponding mold cavity 318. In some embodiments, a finned heat sink 360 is provided in thermal communication with a corresponding TEHE 348. Specifically, finned heat sink 360 may be mounted in conductive thermal communication to contact TEHE 348. Finned heat sink 360 may include any suitable conductive material, such as an aluminum or copper material (e.g., including alloys thereof).

As shown, fins may extend above or horizontally from TEHE 348 to exchange heat with air along the air path 250. In some such embodiments, a conductive recess plate 370 is further provided (e.g., below finned heat sink 360). When assembled, conductive recess plate 370 may house TEHE 348 (e.g., within a recess or pocket of conductive recess plate 370). For instance, conductive recess plate 370 may horizontally bound TEHE 348 while top wall 344 and finned heat sink 360 vertically bound TEHE 348. Moreover, conductive recess plate 370 may be fixed to one or more of the ice building molds 340. In turn, conductive recess plate 370 may provide a structure or surface onto which finned heat sink 360 may be mounted or secured (e.g., via one or more mechanical fasteners, adhesives etc.). In optional embodiments, an insulator plate 372 (e.g., formed from an insulating foam or polymer) is disposed between conductive recess plate 370 and the finned heat sink 360 above TEHE 348. Notably, heat may be focused to finned heat sink 360 from TEHE 348.

Referring now specifically to FIGS. 10 and 12, an exemplary water dispenser assembly 314, including a dispenser base 368 and one or more removable spray caps 374, that may be used with ice making assembly 300 will be described according to exemplary embodiments of the present disclosure. Specifically, for example, dispenser base 368 and spray cap 374 may be used as (or as part of) guide ramp 330 and nozzle 324 (e.g., FIG. 8), respectively. Thus, water dispenser 366 may be positioned below (e.g., directly below) the ice mold 340 to direct an ice-building spray of water to the mold cavity 318. Although two discrete spray caps 374 are illustrated to provide a corresponding number of ice-building sprays to ice molds thereabove, any suitable number of spray caps (and thus corresponding ice building units 312) may be provided, as would be understood in light of the present disclosure.

As shown, the dispenser base 368 generally defines one or more water paths 378 through which water may flow to a corresponding spray cap 374. For instance, one or more conduits 376 may be provided to or beneath spray cap 374 and define water path 378 Thus, water path 378 may be upstream from the spray cap 374. Moreover, when assembled water path 378 may be upstream from pump 322 (FIG. 8), as would be understood in light of the present disclosure.

In some embodiments, the conduits 376 of dispenser base 368 are joined to a support deck 380 (e.g., as discrete or, alternatively, integral unitary member) on which spray cap 374 is selectively received. Support deck 380 may define a guide ramp 382 having a ramp surface that extends at a non-vertical angle θN (e.g., negative angle relative to a horizontal direction) from an upper edge 384 to a lower edge 386. When assembled the ice mold 340 (e.g., FIGS. 9 and 11) may be vertically aligned below support deck 380 between the upper edge 384 and the lower edge 386 such that falling ice billets may strike guide ramp 382 and roll therealong (e.g., as motivated by gravity) to the lower edge 386. From the lower edge 386, ice billets may further roll into an ice bin (e.g., 332—FIG. 2), as described above. Optionally, guide ramp 382 may define a perforated portion, as further described above. Alternatively, guide ramp 382 may define a solid, non-permeable guide surface.

In certain embodiments, support deck 380 includes a cup wall 388 that defines a nozzle recess 390 within which a corresponding spray cap 374 is received. For instance, cup wall 388 may extend from or above conduit 376 such that nozzle recess 390 is defined as a vertically-open cavity through which the ice-building may flow. As shown, cup wall 388 and nozzle recess 390 may be positioned between upper edge 384 and lower edge 386. When assembled, nozzle recess 390 may thus be defined beneath or below at least a portion of guide ramp 382. For instance, a bottom surface of cup wall 388 may extend horizontally from the ramp surface of guide ramp 382 towards upper edge 384. In other words, the bottom surface of cup wall 388 may extend away from lower edge 386 and fail to cross a forward plane defined by the ramp surface along the non-vertical angle N. The resulting nozzle recess 390 may, in turn, have a side profile that is shaped as a right triangle (e.g., enclosed within the triangular side profile of support deck 380).

Generally, nozzle recess 390 defines a horizontal profile having one or more horizontal maximums. For instance, in the illustrated embodiments, nozzle recess 390 defines a lateral maximum LM and a transverse maximum TM that is larger than the lateral maximum LM. Alternative embodiments may have a circular profile and, thus, a single horizontal maximum or diameter. In certain embodiments, the maximum horizontal recess width (i.e., largest horizontal maximum of nozzle recess 390, such as lateral maximum LM) is smaller than a maximum horizontal mold width MM (FIGS. 5 and 6) of mold cavity 318 (e.g., 364). In other words, the maximum horizontal mold width MM, which at least partially defines ice billets formed therein, is larger than the maximum horizontal recess width of nozzle recess 390. Thus, the ice billets formed in (and released from) ice mold 340 are generally larger than the opening to nozzle recess 390.

In optional embodiments, the maximum horizontal mold width MM is at least 50 percent larger than the maximum horizontal recess width (e.g., lateral maximum LM). In additional or alternative embodiments, the maximum horizontal recess width (e.g., lateral maximum LM) is less or equal to than 1.5 inches. In further additional or alternative embodiments, the maximum horizontal mold width MM is greater than or equal to 3 inches. In still further additional or alternative embodiments, the maximum horizontal mold width MM is about 1.5 inches while the maximum horizontal recess width is about 3 inches.

Advantageously, ice billets may be prevented from falling into nozzle recess 390 or otherwise blocking the ice-building spray from spray cap 374.

As shown, spray cap 374 may be positioned on at least a portion of dispenser base 368 (e.g., within nozzle recess 390). Specifically, spray cap 374 is mountable downstream from water path 378 to direct an ice-building spray therefrom (e.g., along a vertical spray axis A towards a corresponding mold cavity 318—FIGS. 4 and 6). Generally, spray cap 374 includes a nozzle head 392 through which one or more outlet apertures 394 are defined. In particular, spray cap 374 extends across the vertical spray axis A while the outlet apertures 394 extend upward through spray cap 374. As water flows from the water path 378, it may thus flow through the outlet apertures 394 as the ice-building spray.

The ice making assembly 300 described above is provided by way of example. Aspects of the present disclosure may also be usable with any ice making assembly including a water reservoir, such as a billet ice maker with only one mold cavity, or more than two mold cavities, or a nugget ice maker, or an ice maker with a vertical mold over which liquid water is cascaded to form ice, or any other suitable ice making assembly with a reservoir, especially where the formation of clear ice is desired. Additionally, the ice making assembly may be provided in a standalone ice maker appliance, or in any suitable chilled chamber or compartment within a refrigerator appliance, such as in an icebox compartment as described above, an in-door icebox compartment, or in a fresh food storage compartment.

Referring now to FIGS. 14-19, the reservoir 316 may be chilled, e.g., the ice making assembly 300 may include a thermally conductive element 400 positioned at least partially in the reservoir 316, e.g., such that at least a portion of the thermally conductive element 400 extends into the internal volume 328 of the reservoir 316, e.g., in direct contact with liquid water stored therein such that the thermally conductive element 400 is in conductive thermal communication with the liquid water. The thermally conductive element 400 may be positioned and configured to receive a flow of chilled air from the sealed system 190, e.g., a portion of the chilled air generated by sealed system 190, such as from the evaporator section(s) 204 and/or 206 thereof, may pass on, over, around, and/or through the thermally conductive element 400. As a result of this flow of chilled air received by the thermally conductive element, the liquid water in the internal volume 328 of the reservoir 316 may be chilled by the chilled air via the thermally conductive element 400. The thermally conductive element 400 may comprise any suitable thermally conductive material, such as a metallic material, such as copper and alloys thereof.

As illustrated in FIG. 14, the reservoir 316 may be positioned in a separate compartment from the freezer chamber 124, such as in the icebox compartment 180, fresh food chamber 122, or other suitable portion of the refrigerator appliance 100, as mentioned above. Thus, the reservoir 316 may be separated from the freezer chamber 124 by one of the thermally insulated walls thereof, such as top wall 168 as indicated in FIG. 14. The thermally conductive element 400 may extend through the insulated wall, e.g., top wall 168, to provide thermal communication between the freezer chamber 124 and the reservoir 316. In additional embodiments, the thermally conductive element 400 may extend into a duct to receive the flow of chilled air from the sealed system 190, such as a duct downstream of the sealed system 190, such as one of the supply ducts 232 or 236 described above, whereby the thermally conductive element 400 provides thermal communication between the sealed system 190 and the reservoir 316 through at least the wall(s) of the duct. Thus, the thermally conductive element 400 may provide chilling of the liquid water within the reservoir 316 without the chilled air from the sealed system 190 entering the reservoir 316, such as the internal volume 328 thereof, or the compartment in which the reservoir 316 is positioned and/or without the chilled air from the sealed system 190 otherwise directly contacting the reservoir 316 or liquid water therein, thereby providing cooling to the liquid water in the reservoir 316.

In some embodiments, e.g., as illustrated in FIGS. 14-17, the thermally conductive element 400 may be generally cylindrical, e.g., the thermally conductive element 400 may be a cylindrical element extending from a first end 402 positioned in the reservoir 316 to a second end 404 positioned in direct contact with the flow of chilled air from the sealed system, such as the second end 404 may be positioned in the freezer chamber 124 or a duct downstream of the sealed system 190, such as one of the supply ducts, as mentioned above, whereby at least a portion of the chilled air from the sealed system 190 that flows into the freezer chamber 124 and/or through the duct 232 or 236 will also flow on, over, and/or around the second end 404 of the thermally conductive element 400.

The cylindrical thermally conductive element 400 may be a solid rod, e.g., a solid copper rod, as illustrated for example in FIGS. 14 and 15. The cylindrical thermally conductive element 400 may be a hollow tube. For example, as illustrated in FIG. 17, the hollow tube thermally conductive element 400 may contain a working fluid therein, e.g., in a heat pipe heat exchanger, as described in more detail below.

In some embodiments, e.g., as illustrated in FIGS. 15-17, the thermally conductive element 400 may include fins 406 on the second end 404 thereof. The fins 406 may provide increased surface area (as compared to a smooth cylinder or other shape without fins) for contact with the flow of chilled air from the sealed system 190, thereby increasing the rate of thermal transfer to the chilled air from the thermally conductive element 400, resulting in increased and/or faster chilling of the liquid water in the reservoir 316.

For example, as illustrated in FIG. 15, the fins 406 may be provided by a plurality of turns of a helical thread formed on and adjacent to the second end 404 of the thermally conductive element 400. For example, the helical thread may extend over approximately one half of a longitudinal dimension of the thermally conductive element 400, where the half or other portion of the thermally conductive element 400 over which the fins 406 extend is the same portion of the thermally conductive element 400 in which the second end 404 is defined. The helical thread 406 may be subtractively formed, e.g., defined by a recess in a primary surface of the thermally conductive element 400, for example as illustrated in FIG. 15.

As another example, e.g., as illustrated in FIG. 16, the fins 406 may be formed as a series of radial projections extending outward from the primary surface of the thermally conductive element 400. Also illustrated in FIG. 16 is an exemplary temperature sensor 410, e.g., thermocouple, which may be provided in various embodiments of the present disclosure (e.g., the temperature sensor 410 may be provided in any of the illustrated embodiments of FIGS. 14-19 and is not limited to the embodiment illustrated in FIG. 16). In embodiments where the temperature sensor 410 is provided, the temperature sensor 410 may be communicatively coupled to the controller 144 for monitoring a temperature of the thermally conductive element 400.

In some embodiments, the thermally conductive element 400 may be a heat pipe heat exchanger, e.g., as illustrated in FIG. 17. A heat pipe heat exchanger, also referred to herein as a “heat pipe,” is an efficient means of transferring thermal energy, e.g., heat, from one location to another.

As shown in FIG. 17, the heat pipe 400 (which is an embodiment of a thermally conductive element 400) includes a sealed casing 412 containing a working fluid 414 in the casing 412. In various embodiments, the working fluid 414 may be any suitable working fluid such as R600 series refrigerants, e.g., R600 or R600a (butane or isobutane), R290 refrigerant (propane), acetone, glycol, methanol, ethanol, or toluene. In other embodiments, any suitable fluid may be used for working fluid 414, e.g., that is compatible with the material of the casing 412 and is suitable for the desired operating temperature range. For example, the desired operating temperature range (in any embodiment, not limited to the heat pipe embodiment illustrated in FIG. 17) may be such that the liquid water in the reservoir 316 is chilled to a temperature at or just above freezing, e.g., about 32° Fahrenheit. The heat pipe 400 extends between a condenser section at the second end 404 and an evaporator section at the first end 402. The working fluid 414 contained within the casing 412 of the heat pipe 400 absorbs thermal energy at the evaporator section at the first end 402, e.g., from the liquid water in the reservoir 316, whereupon the working fluid 414 travels in a gaseous state from the evaporator section at first end 402 to the condenser section at second end 404. The gaseous working fluid 414 condenses to a liquid state at the second end 404 (as illustrated in FIG. 17) and thereby releases thermal energy at the condenser section at the second end 404, e.g., to the flow of chilled air from the sealed system 190 in the freezer chamber 124 or duct 232 or 236. A plurality of fins 406 may be provided on an exterior surface of the casing 412, e.g., the condenser section at second end 404. As described above, such fins 406 may provide an increased contact area between the heat pipe 400 and chilled air flowing around the second end 404 of the heat pipe 400 for improved transfer of thermal energy.

The heat pipe 400 may include an internal wick structure 416 to transport liquid working fluid 414 from the condenser section at the second end 404 to the evaporator section at the first end 402 by capillary flow. For example, as illustrated in FIG. 17, the heat pipe 400 may be arranged such that the evaporator section is positioned above the condenser section along the vertical direction V, whereby condensed working fluid 414 in a liquid state may be drawn upwards from the condenser section at second end 404 to the evaporator section at first end 402 by the capillary action of the wick structure 416. For example, when the reservoir 316 is positioned in the fresh food chamber 122 above the freezer chamber 124, the evaporator section of the heat pipe 400 may be positioned above the condenser section.

In other embodiments, the heat pipe 400 may be oriented in other directions, such as generally perpendicular to the vertical direction V, e.g., generally along the lateral direction L, e.g., when the reservoir 316 is positioned in a compartment such as the icebox compartment 180 that is horizontally aligned with the freezer chamber 124 (see, e.g., FIG. 3). Moreover, in embodiments where the reservoir 316 is below at least a portion of the freezer chamber 124 or duct in which the second end 404 is positioned, the heat pipe 400 may be oriented such that the evaporator section at the first end 402 is below the condenser section at the second end 404, such as directly below (e.g., the inverse of the position illustrated in FIG. 17) or directly below and horizontally offset from (e.g., at an oblique angle to the vertical direction V), whereby condensed working fluid 414 in a liquid state may return to the evaporator section from the condenser section by gravity, thus permitting the wick structure 416 to be eliminated.

In some embodiments, for example as illustrated in FIGS. 18 and 19, the thermally conductive element 400 may be positioned entirely within the reservoir 316. In some embodiments, the thermally conductive element 400 may define an internal volume, such as a pocket, e.g., in FIG. 18, or a channel, e.g., in FIG. 19. In such embodiments, the internal volume of the thermally conductive element 400 may be in fluid communication with the sealed system 190 such that the flow of chilled air from the sealed system 180 flows into the internal volume of the thermally conductive element 400 to chill the liquid water in the reservoir 316.

For example, in some embodiments, e.g., as illustrated in FIG. 18, the thermally conductive element 400 may comprise one or more walls that extend into the internal volume 328 of the reservoir 316. In such embodiments, the wall(s) of the thermally conductive element 400 may thereby define a single open cavity 418. For example, in such embodiments, the thermally conductive element 400 may include only the single open cavity 418 and no other openings or passages therein. The single open cavity 418 may be positioned and configured to receive the flow of chilled air 1000 from, e.g., the freezer chamber 124, through an aperture 169 defined in a wall, such as top wall 168 in the illustrated example embodiment of FIG. 18. Thus, the chilled air 1000 may be in thermal communication with liquid water within the internal volume 328 of the reservoir 316 via the thermally conductive element 400, whereby heat from the liquid water may be transferred to the chilled air 1000 through the thermally conductive element 400 and thus the liquid water may be chilled.

In additional exemplary embodiments, the thermally conductive element 400 may be a duct, e.g., as illustrated in FIG. 19. The duct 400 (which is an exemplary embodiment of the thermally conductive element 400) may extend from an inlet to an outlet. The inlet of the duct 400 may be in fluid communication with the sealed system 190 whereby the inlet receives the flow of chilled air 1000 from the sealed system 190 via a first aperture 169 in the wall, e.g., wall 168. The outlet of duct 400 may be in fluid communication with the sealed system 190 whereby a return flow of air (also denoted 1000 in FIG. 19, at the arrow leading back to freezer chamber 124) to the sealed system 190 flows from the duct 400 at the outlet via a second aperture 169. For example, the flow of chilled air 1000 may be motivated through the duct 400 by a fan, such as fan 240 (FIG. 4) described above.

Reducing the heat of, e.g., chilling, the liquid water in the reservoir 316 may provide numerous advantages. For example, in embodiments where the ice making assembly 300 include a TEHE such as TEHE 248 (FIG. 13) described above, the TEHE may be cooled by liquid water from the reservoir 316. Although such cooling may advantageously improve the performance and/or increase the usable life of the TEHE, the resultant warming of the liquid water may also impede or delay ice formation. Thus, chilling the liquid water in the reservoir with a thermally conductive element 400 as described herein may permit cooling of a TEHE with water from the reservoir 316 without sacrificing ice building performance.

This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.

Claims

1. A refrigerator appliance comprising:

a cabinet;

a liner attached to the cabinet, the liner defining a chilled compartment;

a sealed system mounted to the cabinet to selectively cool the chilled compartment; and

an ice making assembly, the ice making assembly comprising a mold assembly; a mold cavity defined in the mold assembly; a reservoir in fluid communication with the mold assembly to provide a flow of liquid water to the mold cavity defined in the mold assembly; and a thermally conductive element positioned at least partially in the reservoir, the thermally conductive element positioned and configured to receive a flow of chilled air from the sealed system, whereby the liquid water in the reservoir is chilled by the chilled air via the thermally conductive element.

2. The refrigerator appliance of claim 1, wherein the thermally conductive element comprises a cylindrical element extending from a first end positioned in the reservoir to a second end positioned in direct contact with the flow of chilled air from the sealed system.

3. The refrigerator appliance of claim 2, further comprising a freezer compartment defined in the liner, wherein the second end of the thermally conductive element is positioned in the freezer compartment.

4. The refrigerator appliance of claim 2, wherein the second end of the thermally conductive element is positioned in a duct downstream of the sealed system.

5. The refrigerator appliance of claim 2, wherein the thermally conductive element comprises fins at the second end.

6. The refrigerator appliance of claim 2, wherein the thermally conductive element comprises a solid rod.

7. The refrigerator appliance of claim 2, wherein the thermally conductive element comprises a heat pipe heat exchanger.

8. The refrigerator appliance of claim 1, wherein the thermally conductive element defines an internal volume in fluid communication with the sealed system whereby the flow of chilled air from the sealed system flows into the internal volume of the thermally conductive element to chill the liquid water in the reservoir.

9. The refrigerator appliance of claim 8, wherein the internal volume of the thermally conductive element comprises a single open cavity positioned and configured to receive the flow of chilled air.

10. The refrigerator appliance of claim 1, wherein the thermally conductive element comprises a duct extending from an inlet in fluid communication with the sealed system whereby the inlet receives the flow of chilled air from the sealed system to an outlet in fluid communication with the sealed system whereby a return flow of air to the sealed system flows from the duct at the outlet.

11. An ice making assembly, comprising:

a mold assembly;

a mold cavity defined in the mold assembly;

a reservoir in fluid communication with the mold assembly to provide a flow of liquid water to the mold cavity defined in the mold assembly; and

a thermally conductive element positioned at least partially in the reservoir, the thermally conductive element positioned and configured to receive a flow of chilled air from a sealed system, whereby the liquid water in the reservoir is chilled by the chilled air via the thermally conductive element.

12. The ice making assembly of claim 11, wherein the thermally conductive element comprises a cylindrical element extending from a first end positioned in the reservoir to a second end positioned in direct contact with the flow of chilled air from the sealed system.

13. The ice making assembly of claim 12, wherein the second end of the thermally conductive element is positioned in a chilled food storage compartment.

14. The ice making assembly of claim 12, wherein the second end of the thermally conductive element is positioned in a duct downstream of the sealed system.

15. The ice making assembly of claim 12, wherein the thermally conductive element comprises fins at the second end.

16. The ice making assembly of claim 12, wherein the thermally conductive element comprises a solid rod.

17. The ice making assembly of claim 12, wherein the thermally conductive element comprises a heat pipe heat exchanger.

18. The ice making assembly of claim 11, wherein the thermally conductive element defines an internal volume in fluid communication with the sealed system whereby the flow of chilled air from the sealed system flows into the internal volume of the thermally conductive element to chill the liquid water in the reservoir.

19. The ice making assembly of claim 18, wherein the internal volume of the thermally conductive element comprises a single open cavity positioned and configured to receive the flow of chilled air.

20. The ice making assembly of claim 11, wherein the thermally conductive element comprises a duct extending from an inlet in fluid communication with the sealed system whereby the inlet receives the flow of chilled air from the sealed system to an outlet in fluid communication with the sealed system whereby a return flow of air to the sealed system flows from the duct at the outlet.