The present subject matter relates generally to ice makers, such as nugget style ice makers, for refrigerator appliances and methods for operating the same.
Certain refrigerator appliances include an ice maker. To produce ice, liquid water is directed to the ice maker and frozen. A variety of ice types can be produced depending upon the particular ice maker used. For example, certain ice makers include a mold body for receiving liquid water. An auger within the mold body can rotate and scrape ice off an inner surface of the mold body to form ice nuggets. Such ice makers are generally referred to as nugget style ice makers. Certain consumers prefer nugget style ice makers and their associated ice nuggets.
Nugget style ice makers can be operated to maximize an ice making rate of the ice maker. However, various conditions can negatively affect operation of nugget style ice makers. For example, ice within the mold body can jam the auger or otherwise prevent rotation of the auger within the mold body, and such jamming can damage a motor of the nugget style ice maker. To prevent or fix such jamming, a heater on the mold body can be activated to melt ice therein. However, activating the heater can prevent or hinder ice formation, and liquid water within the mold body that is in a super-cooled state can cause the heater to activate despite the auger continuing to operate properly.
Accordingly, a method for operating an ice maker that assists with preventing damage to a motor of the ice maker would be useful. Further, a method for operating an ice maker that assists with detecting super-cooled liquid water within a mold body of the ice maker would be useful.
The present subject matter provides an ice maker assembly and a method for operating an ice maker. The method includes measuring a temperature of the ice maker and determining a first derivative of the temperature of the ice maker with respect to time. An operating state of the ice maker is established based at least in part on the temperature of the ice maker and the first derivative of the temperature of the ice maker with respect to time. Knowledge of the operating state of the ice maker can assist with preventing damage to a motor of the ice maker and with detecting super-cooled liquid water in a mold body of the ice maker. Additional aspects and advantages of the invention will be set forth in part in the following description, or may be apparent from the description, or may be learned through practice of the invention.
In a first exemplary embodiment, a method for operating an ice maker is provided. The method includes measuring a temperature of the ice maker, determining a first derivative of the temperature of the ice maker with respect to time, and establishing an operating state of the ice maker based at least in part on the temperature of the ice maker and the first derivative of the temperature of the ice maker with respect to time.
In a second exemplary embodiment, an ice maker assembly for a refrigerator appliance is provided. The ice maker assembly includes a casing and an auger rotatably mounted within the casing. A motor is mounted to the casing and is configured for selectively rotating the auger. A fan is configured for directing a flow of chilled air towards the casing. A heater is mounted to the casing and is configured for selectively heating the casing. A temperature sensor is configured for measuring a temperature of the casing. An ice bucket is configured for receiving ice from the casing. A controller is in operative communication with the motor, the fan, the heater and the temperature sensor. The controller is configured for measuring the temperature of the casing with the temperature sensor, determining a first derivative of the temperature of the casing with respect to time, and establishing an operating state of the ice maker assembly based at least in part on the temperature of the casing and the first derivative of the temperature of the casing with respect to time.
In a third exemplary embodiment, a method for operating an ice maker is provided. The method includes measuring a temperature of the ice maker and determining a first derivative of the temperature of the ice maker with respect to time. The method also includes a step for detecting super-cooled liquid within the ice maker based at least in part on the temperature of the ice maker and the first derivative of the temperature of the ice maker with respect to time.
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.
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.
Reference now will be made in detail to embodiments of the invention, one or more examples of which are illustrated in the drawings. 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 or spirit 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.
Refrigerator doors 128 are rotatably hinged to an edge of housing 120 for selectively accessing fresh food chamber 122. In addition, a freezer door 130 is arranged below refrigerator doors 128 for selectively accessing freezer chamber 124. Freezer door 130 is coupled to a freezer drawer (not shown) slidably mounted within freezer chamber 124. Refrigerator doors 128 and freezer door 130 are shown in the closed configuration in
Refrigerator appliance 100 also includes a dispensing assembly 140 for dispensing liquid water and/or ice. Dispensing assembly 140 includes a dispenser 142 positioned on or mounted to an exterior portion of refrigerator appliance 100, e.g., on one of doors 120. Dispenser 142 includes a discharging outlet 144 for accessing ice and liquid water. An actuating mechanism 146, shown as a paddle, is mounted below discharging outlet 144 for operating dispenser 142. In alternative exemplary embodiments, any suitable actuating mechanism may be used to operate dispenser 142. For example, dispenser 142 can include a sensor (such as an ultrasonic sensor) or a button rather than the paddle. A user interface panel 148 is provided for controlling the mode of operation. For example, user interface panel 148 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 144 and actuating mechanism 146 are an external part of dispenser 142 and are mounted in a dispenser recess 150. Dispenser recess 150 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 doors 120. In the exemplary embodiment, dispenser recess 150 is positioned at a level that approximates the chest level of a user.
An access door 166 is hinged to refrigerator door 128. Access door 166 permits selective access to freezer sub-compartment 162. Any manner of suitable latch 168 is configured with freezer sub-compartment 162 to maintain access door 166 in a closed position. As an example, latch 168 may be actuated by a consumer in order to open access door 166 for providing access into freezer sub-compartment 162. Access door 166 can also assist with insulating freezer sub-compartment 162, e.g., by thermally isolating or insulating freezer sub-compartment 162 from fresh food chamber 122.
Ice making assembly 160 also includes a fan 176. Fan 176 is configured for directing a flow of chilled air towards casing 170. As an example, fan 176 can direct chilled air from an evaporator of a sealed system through a duct to casing 170. Thus, casing 170 can be cooled with chilled air from fan 176 such that ice making assembly 160 is air cooled in order to form ice therein. Ice making assembly 160 also includes a heater 180, such as an electric resistance heating element, mounted to casing 170. Heater 180 is configured for selectively heating casing 170, e.g., when ice prevents or hinders rotation of auger 172 within casing 170, as discussed in greater detail below.
Operation of ice making assembly 160 is controlled by a processing device or controller 190, e.g., that may be operatively coupled to control panel 148 for user manipulation to select features and operations of ice making assembly 160. Controller 190 can operates various components of ice making assembly 160 to execute selected system cycles and features. For example, controller 190 is in operative communication with motor 174, fan 176 and heater 180. Thus, controller 190 can selectively activate and operate motor 174, fan 176 and heater 180.
Controller 190 may include a memory and microprocessor, such as a general or special purpose microprocessor operable to execute programming instructions or micro-control code associated with operation of ice making assembly 160. The memory may represent random access memory such as DRAM, or read only memory such as ROM or FLASH. In one embodiment, the processor executes programming instructions stored in memory. The memory may be a separate component from the processor or may be included onboard within the processor. Alternatively, controller 190 may be constructed without using a microprocessor, e.g., using a combination of discrete analog and/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. Motor 174, fan 176 and heater 180 may be in communication with controller 190 via one or more signal lines or shared communication busses.
Ice making assembly 160 also includes a temperature sensor 178. Temperature sensor 178 is configured for measuring a temperature of casing 170 and/or liquids, such as liquid water, within casing 170. Temperature sensor 178 can be any suitable device for measuring the temperature of casing 170 and/or liquids therein. For example, temperature sensor 178 may be a thermistor or a thermocouple. Controller 190 can receive a signal, such as a voltage or a current, from temperature sensor 190 that corresponds to the temperature of the temperature of casing 170 and/or liquids therein. In such a manner, the temperature of casing 170 and/or liquids therein can be monitored and/or recorded with controller 190.
At step 210, a temperature of ice making assembly 160 is measured. As an example, controller 190 can measure the temperature of casing 170 with temperature sensor 178 at step 210. At step 220, a first derivative of the temperature of ice making assembly 160 with respect to time is determined. As an example, controller 190 can determine the first derivative of the temperature of casing 170 with respect to time at step 220. In particular, controller 190 can receive multiple temperature measurements from temperature sensor 178 and can determine the first derivative of the temperature of casing 170 with respect to time based at least in part on the multiple temperature measurements at step 220.
At step 230, an operating state of ice making assembly 160 is established or changed. For example, controller 190 can establish or change the operating state of ice making assembly 160 at step 230 based at least in part on the temperature of ice making assembly 160 measured at step 210 and the first derivative of the temperature of ice making assembly 160 with respect to time determined at step 220. Step 230 is discussed in greater detail below with reference to
Method 200 can also include ascertaining a second derivative of the temperature of ice making assembly 160 with respect to time. As an example, controller 190 can determine the second derivative of the temperature of casing 170 with respect to time. In particular, controller 190 can receive multiple temperature measurements from temperature sensor 178 and can determine the second derivative of the temperature of casing 170 with respect to time based at least in part on the multiple temperature measurements. Controller 190 can utilize the second derivative of the temperature of casing 170 to assist with establishing or changing the operating state of ice making assembly 160 at step 230.
Method 200 can also include ascertaining whether ice storage bin 164 is full. As an example, controller 190 can utilize a sensor, such as a feeler arm or an optical sensor, to measure or determine the level of ice nuggets within ice storage bin 164. If the ice storage bin 164 is full, control 190 deactivates or turns off motor 174 and fan 176 of ice making assembly 160, e.g., in order to stop production of ice nuggets by ice making assembly 160. Conversely, controller 190 can establish the operating state of ice making assembly 160 if the ice storage bin 164 is not full.
As may be seen in
When ice making assembly 160 is activated or an ice making cycle of ice making assembly 160 is initiated, controller 190 establishes the operating state of ice making assembly 160 as the drifting state or the recovering state. Controller 190 establishes the operating state of ice making assembly 160 as the drifting state if fan 176 is on or activated. Conversely, controller 190 establishes the operating state of ice making assembly 160 as the recovering state if heater 180 is on or activated.
As may be seen in
If the operating state of ice making assembly 160 is the recovering state (at step 320), controller 190 changes the operating state of ice making assembly 160 from the recovering state to the cooling to freezing state if the temperature of casing 170 is greater than about zero degrees Celsius at step 210 and the first derivative of the temperature of casing 170 with respect to time is less than about zero degrees Celsius per second at step 220.
If the operating state of ice making assembly 160 is the cooling to freezing state (at step 330), controller 190 changes the operating state of ice making assembly 160 from the cooling to freezing state to the ice making state if the first derivative of the temperature of casing 170 with respect to time is about zero degrees Celsius per second at step 220. Conversely, controller 190 shifts the operating state of the ice making assembly 160 from the cooling to freezing state to the super-cooling state if the temperature of casing 170 is less than about zero degrees Celsius at step 210 and the first derivative of the temperature of casing 170 with respect to time is less than about zero degrees Celsius per second at step 220. On the other hand, controller 190 changes the operating state of ice making assembly 160 from the cooling to freezing state to the insufficient cooling state if the first derivative of the temperature of casing 170 with respect to time is greater than about zero degrees Celsius per second at step 220.
If the operating state of ice making assembly 160 is the ice making state (at step 340), controller 190 changes the operating state of ice making assembly 160 from the ice making state to the freezing over state if the temperature of casing 170 is less than about zero degrees Celsius at step 210 and the first derivative of the temperature of casing 170 with respect to time is less than about zero degrees Celsius per second at step 220. Conversely, controller 190 changes the operating state of ice making assembly 160 from the ice making state to the insufficient cooling state if the temperature of casing 170 is greater than about zero degrees Celsius at step 210 and the first derivative of the temperature of casing 170 with respect to time is greater than about zero degrees Celsius per second at step 220.
If the operating state of ice making assembly 160 is the super-cooling state (at step 360), controller 190 changes the operating state of ice making assembly 160 from the super-cooling state to the nucleating state if the temperature of casing 170 is less than about zero degrees Celsius at step 210 and the first derivative of the temperature of casing 170 with respect to time is greater than about zero degrees Celsius per second at step 220. Conversely, controller 190 adjusts ice making assembly 160 from the super-cooling state to the freezing over state if the elapsed time that ice making assembly 160 has been in the super-cooling state is greater than a second predetermined time interval. On the other hand, controller 190 shifts the operating state of the ice making assembly 160 from the super-cooling state to the ice making state if the first derivative of the temperature of casing 170 with respect to time is about zero degrees Celsius per second at step 220 and the second derivative of the temperature of casing 170 with respect to time is about zero degrees Celsius per second squared.
If the operating state of ice making assembly 160 is the nucleating state (at step 370), controller 190 changes the operating state of ice making assembly 160 from the nucleating state to the ice making state if the first derivative of the temperature of casing 170 with respect to time is about zero degrees Celsius per second at step 220. Conversely, controller 190 changes the operating state of ice making assembly 160 from the nucleating state to the insufficient cooling state if the temperature of casing 170 is greater than about zero degrees Celsius at step 210 and the first derivative of the temperature of casing 170 with respect to time is greater than about zero degrees Celsius per second at step 220.
If the operating state of ice making assembly 160 is the insufficient cooling state (at step 380), controller 190 changes the operating state of ice making assembly 160 from the insufficient cooling state to the cooling to freezing state if the temperature of casing 170 is greater than about zero degrees Celsius at step 210 and the first derivative of the temperature of casing 170 with respect to time is less than about zero degrees Celsius per second at step 220.
Turning now to
In the recover mode, controller 190 operates or turns on heater 180. Motor 174 and fan 176 are deactivated or turned off in the recover mode, e.g., such that ice making assembly 160 is not generating or producing ice nuggets. With heater 180 active, heater 180 can melt ice in casing 170, e.g., in order to prevent or limit jamming of auger 172 in casing 170. Controller 190 operates ice making assembly 160 in the recover mode when the operating state of ice making assembly 160 is unknown, the freezing over state or the recovering state (e.g., if the temperature of casing 170 is not greater than a predetermined recovery temperature).
In the make ice mode, controller 190 operates or turns on motor 174 and fan 176. Heater 180 is deactivated or turned off in the make ice mode, e.g., such that ice making assembly 160 generates or produces ice nuggets. With motor 174 and fan 176 active, chilled air from fan 176 can cooling casing 170 and auger 172 can scrape ice from the inner surface of casing 170. Controller 190 operates ice making assembly 160 in the make ice mode when the operating state of ice making assembly 160 is the cooling to freezing state, the ice making state, the nucleating state, the insufficient cooling state, the drifting state, the super-cooling state or the recovering state (e.g., if the temperature of casing 170 is greater than or equal to the predetermined recovery temperature).
In
In
During a fourth portion, t4, of the super-cooling operation cycle, the temperature of casing 170 is less than zero degrees Celsius, but the temperature of casing 170 is increasing such that the first derivative of the temperature of casing 170 with respect to time is positive during the fourth portion t4 of the super-cooling operation cycle. Thus, the operation state of ice making assembly 160 is the nucleating state during the fourth portion t4 of the super-cooling operation cycle. Similarly, the temperature of casing 170 is less than zero degrees Celsius during a fifth portion, t5, of the super-cooling operation cycle, and the temperature of casing 170 is stable such that the first derivative of the temperature of casing 170 with respect to time is about zero degrees Celsius per second during the fifth portion t5 of the super-cooling operation cycle. Thus, the operation state of ice making assembly 160 is the ice making state during the fifth portion t5 of the super-cooling operation cycle.
In
During a fourth portion, t4, of the freezing over operation cycle, the first derivative of the temperature of casing 170 with respect to time is about zero degrees Celsius per second, and the second derivative of the temperature of casing 170 with respect to time is also about zero degrees Celsius per second squared during the fourth portion t4 of the freezing over operation cycle. Thus, the operation state of ice making assembly 160 is the ice making state during the fourth portion t4 of the freezing over operation cycle. Conversely, the temperature of casing 170 is less than zero degrees Celsius during a fifth portion, t5, of the freezing over operation cycle, and the temperature of casing 170 is decreasing such that the first derivative of the temperature of casing 170 with respect to time is negative during the fifth portion t5 of the freezing over operation cycle. Thus, the operation state of ice making assembly 160 is the freezing over state during the fifth portion t5 of the freezing over operation cycle.
As may be seen in
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.
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