JP2012207821A - Ice making device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ice making device that can detect precisely whether ice in an ice tray is formed completely.SOLUTION: An ice making device 1 may include: an ice tray 10, a water-supply means 20 for supplying water to the ice tray 10, a capacitance sensor 60 having two or more electrodes 61 attached to the ice tray 10, and an ice frozen detecting section for detecting water supplied from the water supply means 20 to the ice tray 10 having been frozen on a basis of variation of an electrostatic capacity between the electrodes 61 of the capacitance sensor 60.

Description

  The present invention relates to an ice making device having a configuration for detecting a state in an ice tray.

  In Patent Document 1 below, the state in the ice tray (state where water is present / state where ice is present / empty state) is detected by reflection of light (light sensor) and temperature (temperature sensor). An ice making device is described.

JP 2011-012919 A

  However, the configuration in which the state inside the ice tray is detected by such light reflection and temperature sensors is easily affected by changes in the state of water and ice existing in the ice tray, the outside air temperature, etc. There is a possibility that the state in the dish cannot be accurately detected. Particularly, the configuration for detecting the state in the ice tray by reflection of light has a problem that the reflectance of light changes depending on the surface of water or ice in a undulating state, and the state cannot be detected accurately. The ice making room provided in the refrigerator may shake the ice making plate due to vibration caused by opening and closing the doors (including not only the doors of the ice making room), but the surface of water and ice in the ice making plate Often swells.

  In view of the above problems, an object of the present invention is to provide an ice making device that can accurately detect whether or not ice is completed in an ice making tray.

  In order to solve the above problems, an ice making device according to the present invention comprises an ice making tray, a water supply means for supplying water to the ice making tray, and an electrostatic capacity having two or more insulated electrodes attached to the ice making tray. The gist is provided with a sensor and an ice making detection unit that detects that water supplied from the water supply means to the ice tray is frozen by a change in capacitance between electrodes of the capacitance sensor. is there.

  An ice making device having such a configuration detects that water has frozen due to a change in capacitance between electrodes of the capacitance sensor. Therefore, it is not affected by fluctuations in the ice tray or changes in outside temperature. That is, it is possible to accurately detect the completion of ice in the ice tray.

  In addition, it is only necessary to further include an icing detection unit that detects that the ice in the ice tray is exhausted by a change in capacitance between the electrodes of the capacitance sensor.

  According to such a configuration, it is confirmed that the ice in the ice tray has disappeared (being deiced) due to the change in the capacitance between the electrodes of the capacitance sensor, that is, the ice tray is empty. It becomes possible to detect. That is, the same capacitance sensor can detect not only that the water has frozen and turned into ice, but also that the ice has disappeared from the ice tray. If it can be detected that the ice has disappeared from the ice tray, water can be supplied to the ice tray with the ice remaining, and problems such as overflow of water from the ice tray can be prevented.

  Moreover, what is necessary is just to further provide the water quantity detection part which detects the water quantity in the said ice-making tray supplied from the said water supply means by the change of the electrostatic capacitance between the electrodes of the said electrostatic capacitance sensor.

  According to such a configuration, it becomes possible to detect the amount of water in the ice tray by the change in capacitance between the electrodes of the capacitance sensor. It is possible to detect not only that the ice has disappeared (that is, that the ice has been removed), that is, the same capacitance sensor, but also how much water has been supplied, as well as that the water has been frozen.

  According to the ice making device of the present invention, it is possible to accurately detect the completion of ice in the ice making plate without being affected by the shaking of the ice making plate or a change in the outside air temperature.

1 is an external view of an ice making device according to an embodiment of the present invention. It is the figure which showed the inside of the box in which the member which comprises the ice tray drive means with which the ice making apparatus shown in FIG. It is the figure which showed typically the ice tray (a shaft-shaped part and protrusion are abbreviate | omitted), and is the figure which showed the example to which the electrode of the electrostatic capacitance sensor was attached along two surfaces of the opposing longitudinal direction. It is a time chart for demonstrating operation | movement of an ice making apparatus. It is a flowchart for demonstrating operation | movement (1st operation example) of an ice tray. It is a flowchart for demonstrating operation | movement (2nd operation example) of an ice tray. It is the figure which showed the ice tray typically (a shaft-shaped part and protrusion are abbreviate | omitted), and is the figure which showed the example to which the electrode of the electrostatic capacitance sensor was attached along two surfaces of the transversal direction which opposes. It is the figure which showed the ice tray typically (the shaft-shaped part and protrusion are abbreviate | omitted), and the figure which showed the example attached to the position where the electrode of a capacitance sensor opposes the outer surface of the part which comprises one cell It is. The figure which showed the ice tray typically (the shaft-shaped part and protrusion are abbreviate | omitted), and the figure which showed the example where the electrode of the electrostatic capacitance sensor was attached to the outer surface of the part which comprises one cell at right angles It is. It is the figure which showed the ice tray typically (an axial part and protrusion are abbreviate | omitted), and the example (FIG. 9 and FIG. 9) with which the electrode of the electrostatic capacitance sensor was attached to the outer surface of the part which comprises one cell. Is a diagram showing a different example. It is the figure which showed the ice tray typically (a shaft part and a projection are omitted), and shows the example where the electrode of the capacitance sensor was attached to each outer surface of two cells arranged in the short direction of the ice tray. It is a figure. It is the figure which showed the ice tray typically (a shaft part and a projection are omitted), the outer surface which constitutes the cell located in one end of the longitudinal direction and the short side of the ice tray, and the length of the ice tray It is the figure which showed the example in which the electrode of the electrostatic capacitance sensor was attached to each of the outer surface which comprises the cell located in the other end of a direction and the other end of a transversal direction, and the electrode opposed in the transversal direction. It is the figure which showed the ice tray typically (a shaft part and protrusion are omitted), and an electrode is attached to each of the outer surface of two cells located in the outermost side among a plurality of cells arranged in the longitudinal direction of the ice tray. It is the figure which showed the example. It is the figure which showed the ice tray typically (a shaft part and a projection are omitted), the outer surface which constitutes the cell located in one end of the longitudinal direction and the short side of the ice tray, and the length of the ice tray It is the figure which showed the example which the electrode of the electrostatic capacitance sensor was attached to each of the outer surface which comprises the cell located in the other end of a direction and the other end of a transversal direction, and the electrode opposed in the longitudinal direction. It is a figure for demonstrating the structure by which the electrode of the electrostatic capacitance sensor was attached to the ice tray via the displacement absorption member (enlarged sectional view of the part to which the electrode was attached). It is a schematic diagram for demonstrating the function of the electrode drive means to move the electrode of an electrostatic capacitance sensor. It is sectional drawing which showed the example attached in the state by which the electrode of the electrostatic capacitance sensor was pressed on the outer surface of the ice tray by the biasing member.

  Hereinafter, embodiments of the present invention will be described in detail. The ice making device 1 according to the present embodiment is a so-called “twisting type” ice making device 1 that twists and deforms the ice tray 10 to drop the ice in the ice tray 10 into the ice storage container 40. The “original position” in the following description refers to a state where the opening of the ice tray 10 (each cell 11) is substantially upward.

(Whole structure of ice making device)
First, the overall configuration of the ice making device 1 will be described. The ice making device 1 includes an ice making tray 10, water supply means 20 for supplying water to the ice making tray 10, ice making tray driving means for rotating the ice making tray 10, an ice storage container 40 for storing ice, and ice in the ice container. Ice detecting means for detecting whether the amount is greater than or less than a predetermined amount, a capacitance sensor 60 attached to the ice tray 10, the water supply means 20, the ice tray driving means, the ice detecting means, etc. And a control unit (not shown) for controlling.

  The ice tray 10 is an elastically deformable member integrally formed of a resin material that is an insulator. The ice tray 10 is formed with a plurality of cells 11 (2 × 5 = 10 in this embodiment) for making one ice, and a channel 111 is formed between adjacent cells 11. Yes. Therefore, the water that has flowed into one cell 11 flows into the adjacent cell 11 through this flow path 111.

  In addition, a wall portion 12 that is continuous in the circumferential direction is formed on the top of the ice tray 10 (the top of each cell 11). A connecting portion that connects the ice tray 10 to other members is formed on the surface of the wall portion 12 of the ice tray 10 in the short direction. The connecting portion formed on one short surface is a shaft-like portion 13 that is rotatably supported by the frame of the apparatus. The connecting portion formed on the other short side surface is a recess (not shown) into which the output shaft 33 of the ice tray driving means described later is fitted. Furthermore, a protrusion 14 is formed on one short side surface of the ice tray 10. When the ice tray 10 is rotated from the original position to a state in which the opening is directed downward (approximately 180 degrees) by the ice tray driving means, the protrusion 14 is positioned so as to hit the contact piece 80 formed on the frame of the apparatus. Is formed. That is, when the ice tray 10 rotates to a state where the opening is directed downward, the protrusion 14 strikes the contact piece 80 and is twisted (elastically deformed). Due to this deformation, ice produced in each cell 11 falls into the ice storage container 40.

  The water supply means 20 is configured to supply water to the ice tray 10 and includes one water supply port 21 and a valve 22 provided on the root side (upstream side of supplied water) from the water supply port 21. The control unit can open and close the valve 22 of the water supply means 20. That is, the control unit controls whether water is supplied to the ice tray 10 from one water supply port 21 or is stopped.

  The ice tray driving means is configured to rotate the ice tray 10 from the original position to the deicing position. The configuration of the ice tray driving means is not particularly limited as long as the ice tray 10 can be rotated approximately 180 degrees from the original position (rotated to the ice-off position). In the present embodiment, the same configuration as that described in JP-A-2001-304733 is applied. That is, the driving force of the motor 31 as a driving source is transmitted to the output shaft 33 through the toothed wheel train 32, and when the output shaft 33 rotates, the ice tray 10 connected thereto rotates. Such ice tray driving means is controlled by a control unit. That is, the motor 31 that is a drive source is controlled by the control unit.

  The ice storage container 40 is a box-shaped member positioned below the ice tray 10. Therefore, all the ice dropped due to the torsional deformation of the ice tray 10 rotated approximately 180 degrees is accommodated in the ice storage container 40.

  The ice detecting means detects whether the amount of ice in the ice storage container 40 is greater than or less than a predetermined amount, that is, whether the ice in the ice storage container 40 is sufficient. Thus, the configuration of the ice detecting means is not particularly limited as long as it can detect whether or not a predetermined amount or more of ice exists in the ice storage container 40. In the present embodiment, the same configuration as that described in JP-A-2001-304733 is applied. Briefly described is as follows.

  The ice detecting means uses a motor 31 as a driving source of the ice tray driving means as a driving source. Similar to the ice tray driving means, the drive source of the motor 31 is transmitted to the cam wheel 51 (configured integrally with the output shaft 33) via the toothed wheel train 32. When the cam wheel 51 is rotated, the ice detecting shaft 52 engaged with the cam is rotated by a cam structure (details are omitted) formed inside thereof. Since the ice detecting shaft 53 is connected to the ice detecting member 53 located above the ice storage container 40, the ice detecting member 53 is lowered by the rotation of the ice detecting shaft 52. At this time, if there is a predetermined amount or more of ice in the ice storage container 40, the ice in the ice storage container 40 prevents the ice detecting member 53 from descending to a position lower than a predetermined height, and a push switch (not shown) A signal is generated when the button is pressed. That is, a signal indicating that the ice in the ice storage container 40 is equal to or greater than a predetermined amount is generated. On the other hand, if there is only less than a predetermined amount of ice in the ice storage container 40, the descending of the ice detecting member 53 to a position lower than the predetermined height is not hindered, and the button of the push switch is not pressed. That is, if the signal that the button of the push switch is pressed is not generated, the ice in the ice storage container 40 is not less than a predetermined amount.

  The ice detecting means (excluding the ice detecting member 53) having such a configuration is accommodated in the same box 70 as the ice tray driving means and is disposed to face the surface of the ice tray 10 in the short direction.

  The capacitance sensor 60 has two or more electrodes 61 (conductors) attached to the ice tray 10. The electrodes 61 are insulated from each other. The electrostatic capacity sensor 60 detects the electrostatic capacity between the electrodes 61 that changes depending on the dielectric constant of the insulator existing between the electrodes 61. In other words, it is a sensor that determines the situation inside the ice tray 10 (whether the one present in the ice tray 10 is air (nothing exists) or water or ice, and the amount thereof). Specifically, since the dielectric constant of air is about 1.0, the dielectric constant of water is about 80, and the dielectric constant of ice is about 4.2, it is based on the change in capacitance due to the difference between these dielectric constants. 2 is a sensor for judging the state inside the ice tray 10. Although details of the shape and mounting position of the capacitance sensor 60 and the function of the sensor will be described later, as shown in FIG. 3, for example, the electrodes 61 are mounted along two opposing longitudinal surfaces of the ice tray 10. ing.

  The control unit controls the water supply means 20, the ice tray driving means, and the ice detecting means as described above. In addition, a water amount detection unit that detects the amount of water in the ice tray 10 by a change in capacitance between the electrodes 61 of the capacitance sensor 60, and ice making by a change in capacitance between the electrodes 61 of the capacitance sensor 60. An ice-making tray that detects that the water in the tray 10 has been frozen (the presence of ice in the ice-making tray 10) and the capacitance change between the electrodes 61 of the capacitance sensor 60. 10 has an ice-out detection unit that detects that the ice in the ice 10 has disappeared (the presence of air in the ice tray 10) (hereinafter, these may be collectively referred to as “detection unit”). These may have a configuration in which all functions are mounted on one controller, or each function may be mounted by being divided into a plurality of controllers.

(Operation of ice making device)
The operation of the ice making device 1 having the above configuration, that is, the operation control by the control unit will be described with reference to the time chart of FIG. 4 and the flowcharts of FIGS. In the ice making device 1 having the above configuration, if the control unit (program or detection unit), the capacitance sensor 60, or the like is changed, either the first operation example or the second operation example described below is used. It can also be applied.

1-1. First operation example (normal operation)
A first operation example will be described. In the first operation example, the following operations from step (1) to step (4) are repeated in order.

  In the step (1), after the ice removing operation is completed, it is confirmed that the ice tray 10 is in the original position, that is, the ice tray driving means is in the original position ("S1" in FIG. 5). The confirmation method may be any configuration. For example, by sensing the rotational position of the cam wheel 51 that rotates integrally with the output shaft 33 connected to the ice tray 10, it is determined whether or not the ice tray 10 is in the original position. After determining that the ice tray 10 is in its original position ("S1" Yes in FIG. 5), water supply by the water supply means 20 is started ("S2" in FIG. 5). That is, the valve 22 of the water supply means 20 is opened, and water is poured into the ice tray 10 from the water supply port 21. Thereby, (1) process is complete | finished.

  (2) The step is a step of pouring a predetermined amount of water into the ice tray 10. Specifically, as the water supply time elapses, the amount of air (dielectric constant about 1.0) occupying the ice tray 10 decreases and the amount of water (dielectric constant about 80) increases. The capacitance value measured by the capacitance sensor 60 increases. Then, water supply by the water supply means 20 is continued until the capacitance value measured by the capacitance sensor 60 is equal to or greater than the first threshold value (see FIG. 4), and the measured capacitance value is the first threshold value. In response to the fact that the water amount detection unit has detected the above ("S3" Yes in FIG. 5), water supply by the water supply means 20 is stopped assuming that a predetermined amount of water is poured into the ice tray 10 (FIG. 5). “S4”).

  Here, the “first threshold value” refers to a value set based on a capacitance value in a state where a predetermined amount of water is present in the ice tray 10. Specifically, it refers to the capacitance value in a state where the amount of water necessary for the size of the ice to be created exists in the ice tray 10. The capacitance value corresponding to the first threshold varies depending on the specifications of the apparatus such as the ice tray 10 to be used and the arrangement of the electrodes 61 of the capacitance sensor 60. Therefore, after the specification of the apparatus is determined, the capacitance value is measured in advance in a state where a predetermined amount of water is present in the ice tray 10, and the measured value is set as the first threshold value. Thus, when the step (2) is completed, the amount of water necessary for the size of the ice to be produced is in the ice tray 10.

  (3) In the process, first, the process waits until a predetermined amount of water poured into the ice tray 10 installed in an environment below freezing (less than 0 degrees Celsius) freezes. Specifically, (2) as the standby time after the end of the process elapses, the water (dielectric constant about 80) existing in the ice tray 10 changes to ice (dielectric constant about 4.2). Since (freezing gradually), the capacitance value measured by the capacitance sensor 60 decreases. Then, when the capacitance value measured by the ice making detection unit is less than the second threshold (see FIG. 4) (“S5” Yes in FIG. 5), it is determined that all the water in the ice tray 10 has become ice. To do.

  Here, the “second threshold value” refers to a value set based on a capacitance value in a state where a predetermined amount of water in the ice tray 10 is all ice. Specifically, it means a capacitance value in a state where a predetermined amount of water in the ice tray 10 is all ice, or a value obtained by adding a safety value to this capacitance value. The capacitance value for setting the second threshold varies depending on the specifications of the apparatus such as the ice tray 10 to be used and the arrangement of the electrodes 61 of the capacitance sensor 60. Therefore, after the specification of the apparatus is determined, the capacitance value is measured in advance in the state where ice frozen in a predetermined amount of water is present in the ice tray 10, and the measured value or this value is safe. A value obtained by adding the values is set as the second threshold value. The “safe value” is a value for preventing malfunction due to a measurement error. For example, when the capacitance value in a state in which a predetermined amount of water in the ice tray 10 measured in advance is all ice is set as the second threshold value as it is, the operation of the ice making device 1 is performed in step (3). If a measurement error occurs in the capacitance value measured by the capacitance sensor 60, the second threshold value is not reached even though all the water in the ice tray 10 is ice (second threshold value). May not be less than). Therefore, a capacitance value that is slightly higher than the capacitance value in a state in which a predetermined amount of water in the ice tray 10 that has been measured in advance becomes ice, that is, a capacitance value that includes a “safety value” is added. , May be set as the “second threshold”. Whether the capacitance value in a state where a predetermined amount of water in the ice tray 10 measured in advance is all ice is used as the second threshold value as it is, or a value obtained by adding a safety value is used as the second threshold value. May be set according to the accuracy of the capacitance sensor 60 to be used. In addition, when the value obtained by adding the safety value is used as the second threshold value, there is a possibility that a state in which the measured capacitance value is less than the second threshold value is not completely iced may occur. Then, after waiting for a predetermined time after becoming less than the second threshold value, the following ice detection operation may be performed.

  After the ice making detection unit detects that the capacitance value is less than the second threshold value, the ice detecting operation by the ice detecting means is started. As described above, if there is less than a predetermined amount of ice in the ice storage container 40, the descending of the ice detecting member 53 to a position lower than the predetermined height is not hindered. Therefore, even if the ice detecting shaft 52 rotates by a predetermined amount or more, a signal of a push switch (not shown) is not pressed and a signal is not generated. Thus, even if the ice detecting shaft 52 is rotated by a predetermined amount or more (the motor 31 is rotated to one side for a predetermined time), the button of the push switch (not shown) is not pressed, that is, the ice in the ice storage container 40 is less than a certain amount. Is detected ("S6" Yes in FIG. 5), the ice removing operation by the ice tray driving means is started ("S7" in FIG. 5). That is, the ice removing operation by the ice tray driving means triggered by the detection that “the electrostatic capacitance value has become less than the second threshold value” and “the ice in the ice storage container 40 is less than a certain amount” has been detected. To start. That is, by rotating the motor 31 in one direction, the ice tray 10 is rotated by about 180 degrees to twist and deform, and the ice is dropped into the ice storage container 40. Any method may be used to confirm that the ice tray 10 has been rotated about 180 degrees (rotated to the ice-off position). For example, a method similar to the method for confirming that the ice tray 10 is in its original position can be applied. Thereby, the step (3) is completed.

  In the step (4), the ice tray 10 is returned to the original position (“S1” in FIG. 5). That is, the ice 31 is returned to the original position by rotating the motor 31 in the other direction (reverse rotation). Then, the operation of the step (1) starts again. As described above, in the first operation example, the operations in the steps (1) to (4) are repeated.

1-2. First operation example (initial operation)
An initial operation when the first operation example is employed will be described. The initial operation is an operation when the control unit (detection unit) is initialized. In addition, as a case where a control unit is initialized, the case where it returns from the state which the electricity supply to the control unit stopped at the time of goods purchase, or a power failure, etc. can be considered.

  In the initial state (initialized state) (FIG. 5 “S′1”), when the measured capacitance value is equal to or greater than the second threshold (“S′2” Yes in FIG. 5), first, the above ( 3) Perform the operation of the process. That is, when the measured capacitance value is equal to or greater than the second threshold, water is present in the ice tray 10 (the water is not completely frozen and the water and ice are mixed). Therefore, it waits until the water in the ice tray 10 is frozen. Then, the ice making operation is performed when the ice making detection unit detects that the water in the ice tray 10 is frozen, that is, the measured capacitance value is less than the second threshold value. After performing the operation of the step (3) in this way, the normal operation is performed in the order described above, such as the step (4), the step (1), the step (2), and so on. As described above, when the capacitance value measured in the initial state is equal to or greater than the second threshold value, the water remaining in the ice tray 10 is temporarily frozen and deiced as ice, and then the normal operation is performed. Return.

  On the other hand, in the initial state, the measured capacitance value is less than the second threshold ("S'2" No in FIG. 5), and the ice in the ice storage container 40 is less than a certain amount by the ice detecting means. When this is detected, the ice removing operation is first performed by the ice tray driving means. That is, the measured capacitance value being less than the second threshold means that ice is present in the ice tray 10 (water is completely frozen) or the ice tray 10 is empty. Therefore, the ice tray driving means is operated in order to release the ice on the assumption that ice is present. That is, if ice is present in the ice tray 10, the ice is removed by the deicing operation, and the ice tray 10 is empty, and if the ice tray 10 is empty. The ice tray 10 remains empty (only the ice tray 10 in the empty state is rotated). As described above, the ice making tray 10 is emptied once by performing the ice removing operation, regardless of whether the ice is present in the ice making tray 10 or the state in which the ice making tray 10 is empty. It becomes the state of. After the deicing operation, the normal operation is performed in the order described above, such as (4) step, (1) step, (2) step. As described above, when the capacitance value measured in the initial state is less than the second threshold value and the ice detecting means detects that the ice in the ice storage container 40 is less than a certain amount, After the ice remaining in the ice tray 10 is deiced, the normal operation is resumed.

2-1. Second operation example (normal operation)
A second operation example will be described. In the second operation example, the following operations from step (1) to step (4) are repeated in order. As will be described below, the second operation example is different from the first operation example in that a “third threshold” is set.

  In the step (1), first, it is confirmed that the ice tray 10 is in the original position, that is, the ice tray driving means is in the original position ("S1" in FIG. 6). The confirmation method may be any configuration as in the first operation example. After determining that the ice tray 10 is in the original position, water supply by the water supply means 20 is started ("S2" in FIG. 6). That is, the valve 22 of the water supply means 20 is opened, and water is poured into the ice tray 10 from the water supply port 21. Thereby, (1) process is complete | finished.

  (2) The step is a step of pouring a predetermined amount of water into the ice tray 10. Specifically, as the water supply time elapses, the amount of air (dielectric constant about 1.0) occupying the ice tray 10 decreases and the amount of water (dielectric constant about 80) increases. The capacitance value measured by the capacitance sensor 60 increases. Then, water supply by the water supply means 20 is continued until the capacitance value measured by the capacitance sensor 60 is equal to or greater than the first threshold value (see FIG. 4), and the measured capacitance value is the first threshold value. When the water amount detection unit detects that the above has been reached ("S3" Yes in FIG. 6), water supply by the water supply means 20 is stopped assuming that a predetermined amount of water has been poured into the ice tray 10 (FIG. 6). “S4”).

  Note that the “first threshold value” refers to a value set based on a capacitance value in a state where a predetermined amount of water is present in the ice tray 10 as in the first operation example. As the setting method, the same method as in the first operation example can be used. Therefore, when the step (2) is completed, the amount of water necessary for the size of the ice to be produced is in the ice tray 10.

  (3) In the process, first, it waits until a predetermined amount of water poured into the ice tray 10 is frozen. Specifically, (2) as the standby time after the end of the process elapses, the water (dielectric constant about 80) existing in the ice tray 10 changes to ice (dielectric constant about 4.2). Since (freezing gradually), the capacitance value measured by the capacitance sensor 60 decreases. Then, the ice making detection unit detects that the capacitance value measured by the capacitance sensor 60 is less than the second threshold (see FIG. 4) (“S5” Yes in FIG. 6). It is determined that all the water in the dish 10 has become ice.

  The “second threshold value” is a value set based on a capacitance value in a state where a predetermined amount of water in the ice tray 10 is all ice, as in the first operation example. That means. As the setting method, the same method as in the first operation example can be used. Whether or not to set the value taking into account the “safety value” as the “second threshold value” can also be selected as appropriate.

  After detecting that the capacitance value measured by the capacitance sensor 60 is less than the second threshold value, the ice detecting operation by the ice detecting means is started. The ice detection operation can use the same technique as in the first operation example. When it is detected that the ice in the ice storage container 40 is less than a certain amount (“S6” in FIG. 6), the ice removing operation by the ice tray driving means is started (“S7” in FIG. 6). That is, the ice removing operation by the ice tray driving means triggered by the detection that “the electrostatic capacitance value has become less than the second threshold value” and “the ice in the ice storage container 40 is less than a certain amount” has been detected. To start. That is, by rotating the motor 31 in one direction, the ice tray 10 is rotated by about 180 degrees to twist and deform, and the ice is dropped into the ice storage container 40. Thereby, the step (3) is completed.

  (4) In the step, first, the ice tray 10 is returned to the original position. That is, the ice 31 is returned to the original position by rotating the motor 31 in the other direction (reverse rotation). Then, it is determined whether or not the inside of the ice tray 10 is empty (air is present; permittivity is about 1.0). Specifically, it is confirmed whether the measured capacitance value is less than the “third threshold” (see FIG. 4) (“S8” in FIG. 6).

  Here, the “third threshold value” refers to a value set based on a capacitance value in a state where the inside of the ice tray 10 is empty. Specifically, between the capacitance value in a state where the inside of the ice tray 10 is completely empty and the capacitance value in a state where ice remains in at least one cell 11 in the ice tray 10. The value of The capacitance value for setting the third threshold varies depending on the specifications of the apparatus such as the ice tray 10 to be used and the arrangement of the electrodes 61 of the capacitance sensor 60. Therefore, after the specification of the apparatus is determined, the capacitance value is measured in advance in a state where the ice tray 10 is empty and in a state where ice remains in at least one cell 11 in the ice tray 10. The obtained value is set as the second threshold value.

  When the ice making detection unit confirms that the measured capacitance value is less than the third threshold after the ice making tray 10 is returned to the original position ("S8" in FIG. 6 "Yes"), the ice making tray 10 The inside is empty, and the ice in the ice tray 10 is completely deiced by the deicing operation. Therefore, the operation of the step (1) is started again. On the other hand, after the ice tray 10 is returned to the original position, when the measured capacitance value is equal to or greater than the third threshold value (“S8” in FIG. 6), ice still remains in the ice tray 10. Therefore, the ice removing operation by the ice tray driving means is performed again. Then, the ice tray 10 is returned to the original position, and it is determined whether or not the capacitance value measured again is less than the third threshold value. If the measured capacitance value is less than the third threshold value, it means that the ice in the ice tray 10 is completely deiced by the deicing operation performed again. To start.

2-2. Second operation example (initial operation)
An initial operation when the second operation example is employed will be described.

  In the initial state (initialized state) (FIG. 6, “S′1”), when the measured capacitance value is equal to or greater than the second threshold (“S′2” Yes in FIG. 6), the first In the same manner as in the operation example, the operation of the above step (3) is first performed. That is, when the measured capacitance value is equal to or greater than the second threshold, water is present in the ice tray 10 (the water is not completely frozen and the water and ice are mixed). Therefore, it waits until the water in the ice tray 10 is frozen. Then, the ice making operation is performed when the ice making detection unit detects that the water in the ice tray 10 is frozen, that is, the measured capacitance value is less than the second threshold value. After performing the operation of the step (3) in this way, the normal operation is performed in the order described above, such as the step (4), the step (1), the step (2), and so on. As described above, when the capacitance value measured in the initial state is equal to or greater than the second threshold value, the water remaining in the ice tray 10 is temporarily frozen and deiced as ice, and then the normal operation is performed. Return.

  On the other hand, in the initial state, the measured capacitance value is less than the second threshold value and greater than or equal to the third threshold value ("S'3" Yes in FIG. 6), and further, the ice storage means 40 contains When it is detected that the amount of ice is less than a certain amount, the ice removing operation is first performed by the ice tray driving means. That is, when the measured capacitance value is less than the second threshold value and greater than or equal to the third threshold value, ice is present in the ice tray 10 (water is completely frozen). Therefore, the ice tray driving means is operated to release the ice. After the deicing operation, the normal operation is performed in the order described above, such as (4) step, (1) step, (2) step. As described above, when the capacitance value measured in the initial state is less than the second threshold value and the ice detecting means detects that the ice in the ice storage container 40 is less than a certain amount, After the ice remaining in the ice tray 10 is deiced, the normal operation is resumed.

  In the initial state, when the measured capacitance value is less than the third threshold (“S′3” in FIG. 6), first, the operation of the step (1) is performed. That is, when the measured capacitance value is less than the third threshold value, it means that the inside of the ice tray 10 is empty (the state where air is present). Start water supply to the inside. After performing the operation of the step (1) in this way, the normal operation is performed in the order described above, such as the step (2), the step (3), the step (4), and so on. As described above, when the capacitance value measured in the initial state is less than the third threshold value, it is determined that the inside of the ice tray 10 is empty, and (1) the operation of the step (water supply operation) is performed. Do.

  As described above, the second operation example is different from the first operation example in that it is determined whether or not the measured capacitance value is less than the third threshold value after the ice removing operation. Advantages (effects) of adopting each operation example include the following points.

  In the first operation example, “first threshold value” based on the dielectric constant of water being about 80 as a threshold value for triggering the operation and “based on the dielectric constant of ice being about 4.2” A “second threshold” is set. That is, it detects whether water is present in the ice tray 10 or whether ice is present (ice and empty state (air) are not distinguished). Since the dielectric constants of water and ice are greatly different and there is a large difference between the two threshold values, it is possible to use the capacitance sensor 60 and the detection unit (control unit) with low measurement accuracy. That is, the apparatus can be configured at low cost.

  Further, even when the state where ice is present in the ice tray 10 and the state where the ice tray 10 is empty are not distinguished, the capacitance value measured in the initial state is the second value. If the ice detection means detects that the ice in the ice storage container 40 is less than a certain amount, the ice removal operation is performed in any case. In addition, since the inside of the ice tray 10 becomes empty after the ice removing operation, the normal operation can be restored from the step (4).

  On the other hand, in the second operation example, in addition to the “first threshold value” and the “second threshold value”, a “third threshold value” based on the fact that the dielectric constant of air is about 1.0 is set. That is, in addition to the state where water is present in the ice tray 10 and the state where ice is present, the state where the ice tray 10 is empty is also distinguished and detected. Therefore, it can be detected whether or not the ice in the ice tray 10 is completely deiced after the deicing operation. Therefore, water supply can be started in a state where ice remains in the ice tray 10, and occurrence of problems such as overflow of water from the ice tray 10 can be prevented.

  Further, when distinguishing between the state where ice is present in the ice tray 10 and the state where the ice tray 10 is empty, the capacitance value measured in the initial state is less than the third threshold value. Since water supply operation (operation of (1) process) can be performed immediately in a certain case, an operation of rotating the empty ice tray 10 as in the initial operation when the first operation example is adopted ( The ice removal operation performed on the empty ice tray 10 does not occur.

  Moreover, even if it is a case where either a 1st operation example and a 2nd operation example are employ | adopted, compared with the conventional structure (structure using a temperature sensor) which presumes the state in the ice tray 10 from a temperature change, Excellent in the following points.

  In the case of the conventional configuration in which the state in the ice tray 10 is estimated from the temperature change, the water is present in the ice tray 10 and the ice tray 10 is empty and the ice tray 10 itself is relatively warm. It cannot be distinguished from the state (occurs when a product is purchased or a power outage occurs for a long time). Therefore, in such a case, assuming that water is present in the ice tray 10 for the time being, it waits until a sufficient time has passed for the water to become ice. You have to check if it changes to the existing state. That is, even if the ice tray 10 is empty, the ice tray 10 is empty unless it is confirmed that no ice is present in the ice tray 10 even if the time has elapsed. It cannot be judged. On the other hand, since the ice making device 1 according to the present embodiment can distinguish whether the water is present in the ice tray 10 or the empty state, the ice tray 10 in the initial state is empty. There is no waiting in

  Hereinafter, a preferred control example that can be applied in common to the first operation example and the second operation example will be described.

  In the first control example, in the step (3), the control unit stops energization to the detection unit (ice making detection unit) for detecting the capacitance by the capacitance sensor 60 for a certain time after the water supply is stopped. It is a technique to control to do. In other words, after a predetermined amount of water is supplied into the ice tray 10, the time until the water freezes is longer than a certain time (an essential ice making time that is not affected by conditions such as outside air temperature, hereinafter referred to as the minimum time). Is required. Therefore, since the ice is not completed during the minimum time after the water supply is stopped, it is meaningless to detect the capacitance. Therefore, if the energization of the detection unit is stopped for at least a certain time shorter than the minimum time, the power required for detecting the capacitance can be reduced accordingly.

  In the second control example, in the step (3), the control unit uses the capacitance sensor 60 until the deicing operation is finished after the measured capacitance value is less than the second threshold value. This is a method of controlling to stop energization to the detection unit that detects the capacitance. After it is detected that the measured capacitance value is less than the second threshold value, the deicing operation is performed until it is detected by the ice detection operation that the ice in the ice storage container 40 is less than a certain amount. The state where ice is present in the ice tray 10 is maintained as it is without starting. In some cases, it is considered that ice is not used at all, and the time during which the ice in the ice storage container 40 is equal to or larger than a certain amount of time becomes a long time. Further, since it is not necessary to detect the state in the ice tray 10 during the ice removing operation, it is preferable to stop energization to the detection unit during a short time. In this way, similarly to the first control example, it is possible to reduce the power required for detecting the capacitance.

When both the first control example and the second control example are employed, the control unit can detect the detection unit (water amount detection unit, ice making detection unit, and The ice outlet detection unit is energized (see FIG. 4).
(A) When detecting that the measured capacitance value is equal to or greater than the first threshold value (during the water supply to the ice tray 10 by the water supply means 20)
(B) When detecting that the capacitance value measured after the lapse of the predetermined time has become less than the second threshold value (c) In the case of adopting the second operation example, after the completion of the ice removal operation , When detecting whether the measured capacitance value is less than the third threshold

  In the third control example, in the step (3), when detecting whether or not the measured capacitance value is less than the second threshold value (when indicated by (b) above), the control unit This is a method of performing control so as to intermittently energize a detection unit (ice making detection unit) that detects capacitance by the capacitance sensor 60. There is no problem even if the timing for detecting whether or not the measured capacitance value is less than the second threshold value, that is, whether or not the water in the ice tray 10 is frozen (is completely iced). You don't have to detect the moment). Therefore, for example, by detecting the capacitance at regular time intervals, the detection unit is intermittently operated, so that it is necessary for detecting the capacitance, as in the first control example and the second control example. Power can be reduced.

(Configuration of capacitance sensor)
Hereinafter, the configuration of the capacitance sensor 60 will be described. First, the attachment position of the electrode 61 of the capacitance sensor 60 will be described.

1. Electrode Mounting Position The example of the mounting position shown in FIG. 3 is a configuration in which the electrode 61 is mounted along two opposing longitudinal surfaces of the ice tray 10. Specifically, it is the structure attached to the two outer surfaces of the longitudinal direction in the wall part 12 of the ice tray 10. In the ice making device 1 according to the present embodiment, a connecting portion for connecting the ice tray 10 to other members (the frame of the device and the output shaft 33) is formed in the short direction of the wall portion 12 (wall). Since nothing is provided in the longitudinal direction of the portion 12), the electrode 61 can be attached to a wide plane along the longitudinal direction. That is, the size of the electrode 61 in the planar direction (the area of the surface of the electrode 61 facing the water) can be approximately the same size (area) as the wall portion 12 in the longitudinal direction. Further, the distance between the electrodes 61 is substantially the same as the length of the ice tray 10 in the short direction. Therefore, with this configuration, the electrode 61 can be enlarged and the distance between the electrodes 61 can be shortened, so that the capacitance sensor 60 that exhibits excellent detection accuracy can be obtained. The ice making device 1 according to the present embodiment is a so-called “twisting type” ice making device 1, and the ice tray 10 is twisted and deformed during the ice removing operation. Therefore, when the present configuration is adopted, the ice tray 10 is twisted. In order to prevent the electrode 61 from being greatly deformed and damaged along with the deformation, the electrode 61 to which a damage prevention mechanism described later is applied is preferable.

  Further, in the case of the so-called “scraping type” ice making apparatus 1 (see, for example, US2010 / 0037633), the ice making tray 10 is connected to other members. It is also conceivable that the connecting portion for the purpose is formed on the longitudinal surface of the ice tray 10. Thus, if the structure in which the attachment of the electrode 61 is hindered is formed on the surface in the longitudinal direction of the ice tray 10, the electrode 61 is disposed in the short direction (wall 12 in the short direction). It is good also as a structure attached to (refer FIG. 7).

  The example of the attachment position shown in FIGS. 8 to 13 is a configuration in which the electrode 61 is attached in units of cells 11 of the ice tray 10. With such a configuration, there is an advantage that the deformation amount of the electrode 61 accompanying the torsional deformation of the ice tray 10 during the deicing operation is small as compared with the configurations shown in FIGS. 3 and 7. Each example will be specifically described below.

  The configuration shown in FIGS. 8 to 10 is such that an electrode 61 is attached to the outer surface of the portion constituting one cell 11 in the ice tray 10. That is, the electrode 61 is attached across the one cell 11.

  Specifically, in the configuration shown in FIG. 8, the electrode 61 is opposed to the outer surface of the portion constituting one cell 11 in the ice tray 10 (strictly, the tilted electrode 61 of the cell 11 is also tilted. It is the one arranged. With such a configuration, there is an advantage that the detection accuracy of the capacitance sensor 60 is excellent because the distance between the electrodes 61 is small.

  Further, in the configuration shown in FIGS. 9 and 10, the electrode 61 is orthogonal to the outer surface of the portion constituting one cell 11 in the ice tray 10 (strictly speaking, the tilted electrode 61 of the cell 11 is also tilted. It is the one arranged. If this configuration is adopted, both electrodes 61 can be positioned outside the ice tray 10, so that there is an advantage that wiring and the like are facilitated.

  When the configurations shown in FIGS. 8 to 10 are employed, one cell 11 to which the electrode 61 is attached is one or a plurality of cells 11 to which water supplied from the water supply port 21 of the water supply means 20 reaches the earliest. It is preferable that it is located in the position most distant from. In other words, it is preferably the cell 11 in which water flows last (a predetermined amount of water accumulates) when water is supplied to the ice tray 10. The capacitance sensor 60 detects that a predetermined amount of water is present in the cell 11 into which water flows most recently (the measured capacitance value is equal to or greater than the first threshold value). This is because a predetermined amount of water is also present in the other cells 11. That is, the amount of water supplied to the ice tray 10 can be accurately controlled by controlling the amount of water supplied by the change in the capacitance of the cell 11 into which water flows most recently.

  In the configuration shown in FIGS. 11 to 13, one electrode 61 is attached to the outer surface constituting a certain cell 11, and another electrode 61 is attached to the outer surface constituting another cell 11 different from the certain cell 11. It is what was done. That is, the electrode 61 is attached so as to sandwich the plurality of cells 11.

  Specifically, in the configuration shown in FIG. 11, the electrodes 61 are attached to the outer surfaces of the two cells 11 arranged in the short direction of the ice tray 10. That is, both the electrodes 61 face each other in the short direction of the ice tray 10 (strictly speaking, the inclined electrode 61 of the cell 11 is also inclined). Such a configuration has an advantage that the detection accuracy of the capacitance sensor 60 is excellent because the distance between the electrodes 61 is relatively small. Moreover, since both the electrodes 61 can be located outside the ice tray 10, there is an advantage that wiring and the like are facilitated. In addition, since the space | interval of both the electrodes 61 becomes large, although there exists a possibility that it may be inferior to a detection precision from the structure shown in FIG. 11, you may employ | adopt a structure as shown in FIG. That is, the outer surface (the outer surface along the longitudinal direction) constituting the cell 11 located at one end in the longitudinal direction of the ice tray 10 and one end in the lateral direction, and the other end in the longitudinal direction of the ice tray 10 in the lateral direction. Even if the electrode 61 is attached to each of the outer surfaces (outer surfaces along the longitudinal direction) constituting the cell 11 located at the other end, and the electrode 61 is opposed in the short direction, the capacitance change in the ice tray 10 is changed. Can be detected.

  In addition, when adopting the configuration in which the electrode 61 is attached to each of the outer surfaces of the two cells 11 arranged in the short direction of the ice tray 10 shown in FIG. 11, either one cell 11 or both the cells 11 are It is preferable that the water supplied from the water supply port 21 of the water supply means 20 is located at a position farthest from one or a plurality of cells 11 that reach the earliest. This is because, as described above, the amount of water supplied to the ice tray 10 can be accurately controlled by controlling the amount of water supplied by the change in the capacitance of the cell 11 into which water flows most recently. Thus, even if it is the structure where the electrode 61 was attached so that the several cell 11 may be pinched | interposed, the electrode 61 may be attached to the one or several cell 11 located in the position most distant from the water supply port 21 of the water supply means 20 It is good to have a configuration as described above.

  In the configuration shown in FIG. 13, electrodes 61 are attached to the outer surfaces of the two outermost cells 11 among the plurality of cells 11 arranged in the longitudinal direction of the ice tray 10. With such a configuration, since both the electrodes 61 can be positioned outside the ice tray 10, there is an advantage that wiring and the like are facilitated. In addition, since the space | interval of both the electrodes 61 becomes large, although there exists a possibility of being inferior to a detection precision from the structure shown in FIG. 13, you may employ | adopt a structure as shown in FIG. That is, the outer surface (the outer surface along the short direction) constituting the cell 11 located at one end in the longitudinal direction and the short end of the ice tray 10 and the other end in the long direction and the short direction of the ice tray 10. The electrode 61 is attached to each of the outer surfaces (outer surfaces along the short side direction) constituting the cell 11 located at the other end of the cell, and even if the electrode 61 is opposed to the longitudinal direction, It is possible to detect changes.

  The mounting positions of the electrodes 61 described above are all configured such that the electrodes 61 are mounted on the outer surface of the resin ice tray 10 that is an insulator (the electrodes 61 are mounted in a state facing the space inside the ice tray 10). Including all configurations other than configurations). Accordingly, the water supplied to the ice tray 10 and the electrode 61 are separated from each other, and corrosion of the electrode 61 due to water is prevented.

2. Electrode Damage Prevention Mechanism In the case of the so-called “twisting” ice making device 1 as in this embodiment, the ice making tray 10 is twisted (elastically deformed) during the ice removing operation. Therefore, it is preferable to adopt a configuration in which an electrode 61 damage prevention mechanism as described below is applied so that the electrode 61 constituting the capacitance sensor 60 is not significantly deformed and damaged along with the twist deformation.

  In the first mechanism shown in FIG. 15, an electrode 61 constituting the capacitance sensor 60 is attached to the ice tray 10 via a displacement absorbing member 64. Specifically, the electrode 61 is attached to the ice tray 10 via the displacement absorbing member 64 in a state of being in close contact with the ice tray 10 and not being joined to the ice tray 10. The displacement absorbing member 64 is configured to hold the electrode 61 that is not joined to the ice tray 10. In this configuration, even if the ice tray 10 is deformed, the electrode 61 that is not joined to the ice tray 10 is not greatly deformed. From another point of view, even if the ice tray 10 is deformed, the displacement absorbing member 64 that is easier to deform than the ice tray 10 (soft) exists outside the electrode 61. It tries to maintain the state (natural state) as it is by pushing 64 and does not deform greatly.

  Therefore, if this configuration is adopted, damage to the electrode 61 due to the electrode 61 being greatly deformed can be prevented. Moreover, since the presence of the electrode 61 hardly contributes to the ease of deformation of the ice tray 10 including the electrode 61 as a whole, the thickness and material of the electrode 61 can be set freely, and the ice tray 10 can be deformed. The torque of the motor 31 can be reduced. The displacement absorbing member 64 is preferably formed of a material that can be easily deformed as long as the electrode 61 is not detached from the ice tray 10. Specifically, silicon resin can be exemplified. In addition, since the electrode 61 and the ice tray 10 are in close contact with each other (there is nothing between the electrode 61 and the ice tray 10), the above configuration is excellent in detection accuracy as the capacitance sensor 60.

  The second mechanism has a shape and configuration that easily deforms the electrode 61 itself constituting the capacitance sensor 60. Specifically, the electrode 61 attached to the ice tray 10 can be restored to the original state by the restoring force that the ice tray 10 that has been twisted and deformed during the ice removing operation tries to return to the original state. Examples of the electrode include a sheet of electrode 61 made of aluminum foil or copper foil, a conductive elastic body made conductive by kneading conductive carbon or metal powder, and a linear conductor meshed. The electrode 61 is formed in a shape (mesh shape), a cotton-like conductor in which fibrous conductors are randomly arranged, cut into a predetermined size, or the like and cut into a predetermined size. The change in capacitance can also be detected.

  By adopting such a configuration, it is possible to prevent the electrode 61 from being damaged due to the deformation of the ice tray 10. Moreover, since the rigidity of the electrode 61 hardly contributes to the ease of deformation of the ice tray 10 including the electrode 61 as a whole, the torque of the motor 31 for deforming the ice tray 10 can be reduced. In this configuration, the electrode 61 may be attached to the ice tray 10 by any method. For example, an attachment method using adhesion (using an adhesive or a double-sided tape), an attachment method using a fastening member such as a screw, and the like can be given.

  The third mechanism is the ice making device 1 further provided with electrode driving means for moving the electrode 61 of the capacitance sensor 60. Such electrode driving means can move the electrode 61 from the first position shown in FIG. 16 (a) to the second position shown in FIGS. 16 (b) and 16 (c). Be controlled.

  When water is supplied to the ice tray 10 by the water supply means 20 (until the water supply is stopped when the capacitance value measured from the start of water supply becomes equal to or higher than the first threshold) and the water in the ice tray 10 is When it is not frozen yet (until the measured capacitance value is less than the second threshold value after the water supply is stopped), the electrode driving means keeps the electrode 61 in contact with the ice tray 10; That is, the state is set to the first position shown in FIG. On the other hand, when the ice tray 10 is rotated by the ice tray driving means after the water in the ice tray 10 is frozen (immediately before the ice tray 10 is rotated), the electrode driving means moves the rotation path of the ice tray 10. The electrode 61 is moved to a position where the electrode 61 does not enter C (see FIG. 16C). That is, it is set to the state located in the 2nd position shown in Drawing 16 (b) and (c). When the ice removing operation is finished and the ice tray 10 returns to the original position, the electrode driving means moves the electrode 61 to a state where it is brought into contact with the ice tray 10 again. That is, the state is set to the first position shown in FIG.

  By adopting such a configuration, the electrode 61 is separated from the ice tray 10 while the ice tray 10 is elastically deformed, and therefore the electrode 61 can be prevented from being damaged due to the electrode 61 being largely deformed. . In addition, since the presence of the electrode 61 does not contribute to the ease of deformation of the ice tray 10 as a whole including the electrode 61, the thickness and material of the electrode 61 can be set freely, and the ice tray 10 can be deformed. The torque of the motor 31 can be further reduced. Furthermore, since the electrode 61 is not directly or indirectly attached to the ice tray 10, the ice tray 10 alone can be removed and cleaned without removing the wiring connecting the electrode 61 and the detection unit.

  In the fourth mechanism, as shown in FIG. 17A, the electrode 61 of the capacitance sensor 60 is pressed against the outer surface of the ice tray 10 by a biasing member 66 (spring or the like) connected to the outside. It is a state. The position of the electrode 61 when the urging member 66 has a natural length (the position of the electrode 61 when not in contact with the ice tray 10) is more than when it is pressed against the outer surface of the ice tray 10. It is slightly inside, and the tip side (ice tray 10 side) of the electrode 61 is chamfered. Specifically, the position of the electrode 61 and the biasing member 66 when the size of the chamfer in the thickness direction of the electrode 61 (thickness of the chamfered portion) is pressed against the outer surface of the ice tray 10 are natural. It is larger than the difference in the position of the electrode 61 when the length is long.

  During the ice removing operation, the ice tray 10 rotates while elastically deforming the urging member 66 so as to push the electrode 61 away. Since the tip end side of the electrode 61 is chamfered as described above, the electrode is not caught by 61 when the ice tray 10 returns to the original position. That is, as shown in FIG. 17B, the chamfered portion of the electrode 61 is pressed against the outer surface of the ice tray 10 so as to slide on the outer surface of the ice tray 10 (the state shown in FIG. 17A). )

If such a configuration is adopted, the electrode 61 is prevented from being deformed along with the elastic deformation of the ice tray 10. In other words, the biasing member 66 is deformed by the rotation of the ice tray 10 and the electrode 61 is not deformed, so that the damage due to the deformation of the electrode 61 is prevented. In addition, since the presence of the electrode 61 does not contribute to the ease of deformation of the ice tray 10 including the electrode 61 as a whole, the thickness and material of the electrode 61 can be freely set, and the motor for deforming the ice tray 10 The torque 31 can be reduced.
Further, a driving source for driving the electrode 61 as in the third mechanism is not necessary.

  The damage preventing mechanism for the electrode 61 described above can be applied to any position where the electrode 61 is attached. In particular, when the electrode 61 is attached along two opposing longitudinal surfaces of the wall portion 12 of the ice tray 10 shown in FIG. 3, the electrode 61 may be greatly deformed along with the elastic deformation of the ice tray 10. Therefore, the significance of applying the electrode damage prevention mechanism is significant.

  Further, in the case of the so-called “scraping type” ice making device 1, the ice making tray 10 is not elastically deformed, and thus a mechanism for preventing damage to these electrodes 61 is not necessary. That is, the electrode 61 having an arbitrary shape and thickness may be directly fixed at an arbitrary position on the ice tray 10.

  Although the embodiments of the present invention have been described in detail above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1 Ice making apparatus 10 Ice tray 11 Cell 13 Shaft-shaped part (connection part)
20 Water supply means 21 Water supply port 22 Valve 40 Ice storage container 60 Capacitance sensors 61, 61 Electrode 64 Displacement absorbing member 66 Biasing member

Claims (3)

An ice tray,
Water supply means for supplying water to the ice tray;
A capacitive sensor having two or more insulated electrodes each attached to the ice tray;
An ice making detection unit that detects that water supplied from the water supply means to the ice tray is frozen by a change in capacitance between electrodes of the capacitance sensor;
An ice making device comprising:   The ice making device according to claim 1, further comprising an ice-out detecting unit that detects that the ice in the ice tray has run out by a change in capacitance between electrodes of the capacitance sensor.   The water quantity detection part which detects the water quantity in the said ice tray supplied from the said water supply means by the change of the electrostatic capacitance between the electrodes of the said electrostatic capacitance sensor is further provided, It is characterized by the above-mentioned. Ice making equipment.

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