JP6131457B2 - Ice making equipment and refrigerator - Google Patents

Description

  The present invention relates to a technique for efficiently deicing ice produced from an ice tray in an ice making device of a domestic refrigerator-freezer.

  Conventionally, as an ice making device for this kind of refrigerator, there is an ice making section provided on both sides of an ice making tray to facilitate ice detachment using heat during water supply (see, for example, Patent Document 1).

  11, FIG. 12 and FIG. 13 show a conventional ice making device described in Patent Document 1. In FIG.

  11 to 12, the ice making device 57 is disposed in a freezer 58 of a refrigerator / freezer 58 and includes a double-sided square ice tray 60 having a housing 59. A first ice cube cavity 62 is provided on the first side surface 61 of the housing 59. A second ice cube cavity 64 is provided on the second side surface 63 of the housing 59.

  Further, the ice making device 57 is provided with a solenoid 66 attached to the freezer 58 by a bracket 65, and rotates the housing 59 via the plunger 67, the pinion 68, and the first end shaft 69.

  The ice making device 57 further includes a water injection pipe 70, and a predetermined amount of water supplied from the pipe 71 is injected into the first ice cube cavity 62 or the second ice cube cavity 64. In addition, a heater 72 for defrosting is disposed in the vicinity of the pipe 71 to appropriately heat the water to be supplied.

  As shown in FIG. 13, the side surface 73 of the first ice cube cavity 62 and the side surface 74 of the second ice cube cavity 64 are adjacent to each other.

  Water supplied via the pipe 71 and the water injection pipe 70 is stored in the first ice cube cavity 62 and is made by the cold air in the freezer 58. After completion of ice making, the housing 59 is rotated by rotating means such as a solenoid 66, the first ice cube cavity 62 is directed downward, and the empty second ice cube cavity 64 is directed upward. Here, water is again supplied from the water injection pipe 70 to the second ice cube cavity 64. The heat of the supplied water is transferred to the ice in the first ice cube cavity 62 through the side surface 73 and the side surface 74. This heat is intended to melt the ice surface in the first ice cube cavity 62 and help to disengage the ice from the first ice cube cavity.

JP-A-8-189737

However, in the conventional configuration, in order to fill all the ice cube cavities with water from a single water injection pipe, a cut is made in the housing for each ice cube cavity, but the ice removal method by twisting the ice cube tray Therefore, there are cases where a plurality of ices are connected to each other and deiced. In ice making methods that are usually used in medium to large refrigerators, there are few that use an ice dispenser mechanism, and it is often impossible to expect the ice connected during the transfer of ice to be separated.

  SUMMARY OF THE INVENTION The present invention solves the above-described conventional problems, and an object thereof is to provide an ice making device and a refrigerator that can prevent ice from being connected and reliably remove ice.

In order to solve the above-described conventional problems, an ice making device of the present invention includes a water supply tank disposed in a refrigerator compartment, a water supply pump that sends water from the water supply tank, and a water pump that is connected to the water supply pump to carry water downward. A water supply means comprising a water supply pipe, an ice tray, an ice making mechanism for rotating the ice tray, a drive motor provided in the ice making mechanism, and an ice provided in the ice making mechanism. In an ice making device comprising an ice detecting lever for detecting the presence or absence, a housing to which the ice making tray and the ice making mechanism are attached, and a plurality of water supply ports provided in the housing, the ice making plate is twisted for ice removal The ice making mechanism is configured to perform water supply to the ice making tray from a plurality of locations, and when the ice making operation is performed by the deformation of the ice making tray due to the heat of the water supply to the ice making tray, Previous By oscillating a plurality of times at a certain angle to the ice tray, reliable ice removal to ensure separation of the ice can be realized.

  The ice making device of the present invention can ensure ice separation while ensuring ice separation.

Front view of a refrigerator provided with an ice making device in Embodiment 1 of the present invention Side surface sectional drawing of the refrigerator provided with the ice making apparatus in Embodiment 1 of this invention Sectional drawing which shows the principal part which shows the water supply means and ice making apparatus in Embodiment 1 of this invention The perspective view of the ice making apparatus in Embodiment 1 of this invention The perspective exploded view of the ice making device in Embodiment 1 of this invention Side surface sectional drawing of the ice making apparatus in Embodiment 1 of this invention Sectional drawing of the principal part of the ice tray which shows the ice-making state in Embodiment 1 of this invention Side surface sectional drawing of the ice tray which shows the deicing state in Embodiment 1 of this invention Main part perspective sectional drawing of the ice tray in Embodiment 2 of this invention Main part perspective sectional drawing of the ice tray in Embodiment 3 of this invention Side sectional view of a conventional ice making device Plan view of ice tray in conventional ice making equipment Side sectional view of an ice tray showing the deicing state in a conventional ice making device

According to a first aspect of the present invention, there is provided a water supply means comprising a water supply tank disposed in a refrigerating chamber, a water supply pump for sending water from the water supply tank, a water supply pipe connected to the water supply pump for discharging water downward, and ice making An ice tray, an ice making mechanism for rotationally driving the ice making tray, a drive motor provided in the ice making mechanism, an ice detecting lever provided in the ice making mechanism for detecting the presence or absence of ice, In an ice making device comprising an ice tray, a housing to which the ice making mechanism is attached, and a plurality of water supply ports provided in the housing, the ice removing operation is performed without twisting the ice tray, and Water supply is performed from a plurality of locations, and during the ice removal operation, when the ice making mechanism is deiced due to the deformation of the ice making plate due to the heat of water supplied to the ice making plate, the ice making mechanism performs the ice making plate a plurality of times at a certain angle. Niwata By swinging Te, to prevent coupling of the ice, it is possible to provide ice making apparatus that can reliably ice removal.

  According to a second invention, in the first invention, the ice tray is provided with an ice making section on both sides, and the ice tray is micro-deformed using heat at the time of water supply without performing a twisting operation. Can be deiced.

  According to a third invention, in the first or second invention, a stepping motor is used as the drive motor, and the ice tray is swung after water supply. The amount of water in each ice making section is kept uniform and substantially the same. The size of ice making is possible.

4th invention is a refrigerator provided with the ice making apparatus as described in any one of Claim 1 to 3, and provides the refrigerator provided with the ice making apparatus which prevents the connection of ice and can deicing reliably. Can do.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a front view of the refrigerator according to Embodiment 1 of the present invention. FIG. 2 is a side sectional view of the refrigerator according to Embodiment 1 of the present invention. FIG. 3 is a cross-sectional view of the main part showing the water supply means and the ice making device according to Embodiment 1 of the present invention.

1 to 3, the refrigerator 1 has a storage room optimally adjusted in temperature according to the type and period of food to be stored, that is, a refrigerator room 2 adjusted to a refrigeration temperature, and an ice making room 3 adjusted to a freezing temperature. An upper freezer compartment 4, a lower freezer compartment 5, and a vegetable compartment 6 adjusted to the refrigeration temperature are arranged.
In each storage room, a door that closes the front opening of the storage room and allows food to be taken in and out, that is, a refrigerator left door 7, a refrigerator right door 8, an ice making door 9, and an upper freezer door 10 is provided. And the lower freezer compartment door 11 and the vegetable compartment door 12 are arrange | positioned. Among these, the refrigerating room left door 7 and the refrigerating room left door 8 are rotary doors whose ends are pivotally supported, and other ice making doors 9, an upper freezer compartment door 10, a lower freezer compartment door 11, The vegetable compartment door 12 is a drawer-type door that can be opened and closed linearly in the front direction.

  The refrigerator compartment 2 and the ice making chamber 3 and the refrigerator compartment 2 and the upper freezer compartment 4 are separated by a first partition wall 13 having heat insulation properties. Similarly, the lower freezer compartment 5 and the vegetable compartment 6 are separated by a second partition wall 14 having heat insulating properties. Furthermore, the ice making chamber 3, the upper freezer compartment 4, and the lower freezer compartment 5 are separated by a partition 15 having heat insulation properties. This partition 15 is provided over the entire width of the freezer compartment. Although not shown, the ice making chamber 3 and the upper freezing chamber 4 are also separated by a partition wall. The ice making room 3, the upper freezing room 4, and the lower freezing room 5 are divided as storage spaces, but communicate with each other as the storage room air, and are adjusted to substantially the same freezing temperature. Yes.

  A plurality of refrigerator compartment shelves 16 on which food is placed are provided in the refrigerator compartment 2, and a plurality of door shelves 17 are provided on the refrigerator compartment left door 7 and the refrigerator compartment right door 8. In addition, an ice storage case 18 for storing ice is provided in the ice making chamber 3, and a first freezing case 19 is provided in the upper freezing chamber 4. In addition, a second freezing case 20 and a third freezing case 21 are provided in the lower freezing chamber 5, and the third freezing case 21 can slide on the second freezing case 20 in the front-rear direction. It has a simple structure. Further, a first vegetable case 22 and a second vegetable case 23 are provided in the vegetable compartment 6, and the second vegetable case 23 can slide on the first vegetable case 22 in the front-rear direction. It has a structure.

  A compressor 24 is disposed on the upper back of the refrigerator 1 and is connected to a condenser (not shown), a capillary tube (not shown), and an evaporator 25 by a refrigerant pipe (not shown). A defroster heater 26 is provided below the evaporator 25.

The front surface of the evaporator 25 is covered with an evaporator cover 27, and a freezer compartment duct 28 is disposed in front of the evaporator cover 27. Further, the evaporator cover 27 is provided with a freezing fan 29 for sending cold air to each storage chamber. An air path damper 30 that varies the amount of cold air into the refrigerating chamber 2 is provided at the rear of the first partition wall 13. A refrigerating room duct 31 is provided on the back of the refrigerating room 2, and the cold air that has passed through the air path damper 30 is introduced into the refrigerating room 2 and distributed between the refrigerating room shelves 16. Yes. In addition, a vegetable room duct 32 is provided on the back surface of the vegetable room 6 and functions to introduce cold air that has passed through a part of the freezer room duct 28 into the vegetable room 6.

  An evaporating dish 33 for storing and evaporating water defrosted by the defrosting heater 26 is disposed at the lower portion of the refrigerator 1.

  A control board 34 is provided on the rear surface of the refrigerator 1, and is electrically connected by a compressor 24, a freezer compartment fan 29, an air path damper 30, a water supply means 35, an ice making device 36, and a harness (not shown). Connected and plays a role of controlling the operation of each device.

  The water supply means 35 is disposed on the lower left side of the refrigerator compartment 2 and on the first partition wall 13, and includes a water supply tank 37, a water supply pump 38, and a water supply pipe 39. The water supply pipe 39 is piped downward from the water supply pump 38 and opens into the ice making chamber 3 through the first partition wall 13.

  The ice making device 36 includes an ice making tray 40, an ice making mechanism 41 that rotates the ice making tray 40, an ice detecting lever 42 that is attached to the ice making mechanism and detects the amount of ice stored, and a housing that holds the ice making tray 40 and the ice making mechanism 41. 43.

  FIG. 4 is a perspective view of the ice making device according to Embodiment 1 of the present invention. FIG. 5 is an exploded perspective view of the ice making device according to Embodiment 1 of the present invention. FIG. 6 is a side sectional view of the ice making device according to Embodiment 1 of the present invention.

  4 to 6, the ice making mechanism 41 is provided with a stepping motor 45 connected to the drive shaft 44. The drive shaft 44 is connected to the rear end of the ice tray 40, and the ice making mechanism 45 is operated in accordance with the operation of the stepping motor 45. The dish 40 is rotated. Further, a shaft 46 is provided at the front end of the ice tray 40 and is inserted into the bearing portion 47 of the housing 43.

  The ice tray 40 is provided with a first ice making section 48 composed of a plurality of ice making sections and a second ice making section 49 composed of a plurality of ice making sections, and the first ice making section 48 and the second ice making section 49 A heat insulating part 50 is provided between them. As a material of the ice tray 40, a material having good heat conductivity is preferable, and aluminum or a resin having good heat conductivity is preferably used. Further, the heat insulating portion 50 may be filled with a material such as foamed polyethylene, or an air layer may be formed. Further, the water repellent treatment is applied to the inner surfaces of the plurality of ice making sections in the first ice making portion 48 and the second ice making portion 49. In addition, the outer peripheral part 51 of the 1st ice making part 48 and the 2nd ice making part 49 is set higher than the partition 52 between each ice making division.

  A water supply groove 53 for receiving water from the water supply pipe 39 is formed on the top surface of the housing 43. The water supply groove 53 is provided with a plurality of water supply ports 54 corresponding to the respective ice making sections of the first ice making section 48 or the second ice making section 49, thereby enabling individual water supply to each ice making section. . Further, a cool air discharge port 55 is provided at the rear of the top surface of the housing 43 and is connected to an ice making duct 56 provided in the first partition wall 13, so that the cold air sent out by the freezing fan 29 reaches the upper part of the ice making tray 40. Led.

  FIG. 7 is a cross-sectional view of the main part of the ice making tray showing the ice making state in the first embodiment of the present invention.

  In FIG. 7, state A shows a state immediately after supplying water to the first ice making unit 48, and state B shows a state after completion of ice making in the first ice making unit 48.

  FIG. 8 is a side cross-sectional view of the ice tray that shows the deicing state according to the first embodiment of the present invention.

  In FIG. 8, state C shows a state in which the ice tray 40 is inverted after completion of ice making in the first ice making unit 48, and state D supplies water to the second ice making unit 49 after the ice tray 40 is inverted. 3 shows a state where ice is deiced from the inside of the first ice making unit 48.

  The operation and action of the refrigerator configured as described above will be described below.

  Evaporation is performed by the operation of the cooling system configured in the refrigerator 1, that is, the compressor 24, the condenser (not shown), the capillary tube (not shown), the evaporator 25, and the control board 34 that controls the compressor 24. Air is cooled in the vessel 25.

  The generated cold air is sent out of the evaporator cover 27 by the operation of the refrigeration fan 29. A part of the sent out cool air is sent upward, passes through the air path damper 30, and is distributed and discharged into the space between the refrigerator compartment shelves 16 by the refrigerator compartment duct 31. At this time, the air path damper 30 is controlled to be opened and closed by the control board 34, and plays the role of adjusting the inside of the refrigerator compartment 2 to an appropriate temperature. The cold air that has cooled the stored items in the refrigerator compartment 2 passes through a suction port (not shown) provided in the refrigerator compartment duct 31 again, is led to a lower portion of the evaporator 25 through a return air passage (not shown), It is cooled again in the evaporator 25.

  A part of the cool air sent out from the freezing fan 29 is branched forward and sent out into the upper freezer compartment 4 and the lower freezer compartment 5 through the freezer compartment duct 28. This cold air cools the stored items in the first freezing case 19, the second freezing case 20, and the third freezing case 21, and the cold air that has circulated in the warehouse passes through the suction port at the lower part of the freezer compartment duct 28. Return to the evaporator 25.

  Similarly, a part of the cold air sent out from the freezing fan 29 is discharged from the vegetable compartment duct 32 into the vegetable compartment 6 to cool the stored items in the first vegetable case 22 and the second vegetable case 23, and It returns to the evaporator 25 through the vegetable room return air path (not shown) provided in the second partition wall 14.

  A part of the cold air sent upward from the freezing fan 29 is sent through the ice making duct 56, passes through the cold air discharge port 55, and is discharged into the ice making device 36 and further into the ice making chamber 3. The cold air freezes the water in the ice tray 40 and returns to the evaporator 25 from the suction port at the bottom of the freezer compartment duct 28 while cooling the stored ice in the ice storage case 18.

  Next, operations related to ice making will be described.

  The water supply pump 38 operates in response to an instruction from the control board 34 and sends the water in the water supply tank 37 toward the water supply pipe 39. The water that has passed through the water supply pipe 39 is poured into a water supply groove 53 provided on the top surface of the housing 43, passes through a plurality of water supply ports 54, and is supplied to a plurality of ice making sections in the first ice making unit 48. At this time, the plurality of water supply ports 54 are individually supplied to a plurality of opposed ice making sections, and there is no movement of water between adjacent ice making sections at the time of water supply.

  After the water supply, the ice tray 40 is swung at a predetermined angle a plurality of times in the left-right direction by the operation of the stepping motor 45 in the ice making mechanism 41. As a result, the water in each ice making section in the ice making section gets over the partition 52 between each ice making section, and the amount of water is made uniform. The swing angle by the stepping motor 45 is controlled so that water does not spill from the outer peripheral portion 51 of the ice tray 40.

The water supplied to the ice making section is deprived of heat from the surroundings and freezes. However, a heat insulating section 50 is provided between the first ice making section 47 and the second ice making section 49 of the ice tray 40. Further, since the cold air discharge port 55 is located above the ice making tray 40 and the cold air flows above the first ice making portion 48, it freezes from the upper side to the lower side of the ice making section. (FIG. 7, state A) For this reason, the ice is deformed downward in a convex state as the freezing progresses. As a result, the surface is slightly lifted in the ice making compartment, and peeling from the inner surface of the ice making compartment becomes easy. (FIG. 7, state B)
If the water in the first ice making unit 48 is frozen in this way and the completion of ice making is detected by some means, the stepping motor 45 in the ice making mechanism 41 is driven by the instruction of the control board 34, and the ice making tray 40 is reversed. To do. (FIG. 8, state C)
Bracket 65 freezer 58 In this state, the water supply pump 38 operates again, and water is supplied into the plurality of ice making sections of the second ice making unit 49 this time. At this time, the ice tray 40 is disposed in a frozen atmosphere, and the temperature is approximately -18 ° C to -20 ° C. On the other hand, the water supply tank 37 is disposed in a refrigerated atmosphere, and the water inside the water supply tank 37 is maintained at approximately 3 ° C. to 5 ° C. The temperature difference between the water immediately after water supply to the second ice making unit 49 and the ice tray 40 is about 21K to 25K, and the second ice making unit 49 is thermally expanded by this temperature difference.

  On the other hand, the first ice making unit 48 is less likely to transmit heat of the water supply due to the presence of the heat insulating unit 50, and the thermal expansion timing is delayed as compared with the second ice making unit 49. As a result, the second ice making portion 49 is warped upward and, conversely, the first ice making portion 48 is warped downward and concave. By deforming downward in this concave state, the inner surface of the ice making section of the first ice making section 48 is deformed, and a force that promotes deicing from the ice making section is applied to the frozen ice. The ice in the ice making compartment is slightly lifted as shown in FIG. 7, state B, and is iced downward along with the deformation of the inner surface of the ice making compartment and stored in the ice storage case 18. (FIG. 8, state D) Although this ice making operation is performed automatically and continuously, the amount of ice in the ice storage case 18 is regularly measured by the ice detecting lever 42 and reaches the specified amount. Is controlled to pause the ice making operation.

  In this way, ice removal is performed by utilizing the deformation of the ice tray 40 due to the heat of the water supply, but the operation of the refrigeration fan 29 is stopped for a certain period of time before water supply or after water supply, and the ice tray 40 is cooled by cold air. Suppress. By doing so, the thermal expansion of the second ice making part 49 due to the heat of the water supply is ensured.

  Further, when the ice tray 40 is inverted and water is supplied to the second ice making section 49, the ice making mechanism 41 is driven, and the ice tray 40 is swung a plurality of times at a certain angle. Thereby, the deicing of the ice in the ice making section in the first ice making unit 48 is promoted. The swing angle of the ice tray 40 is set to an angle that prevents water supplied to the ice making section in the second ice making section 49 from spilling. At this time, since the ice tray 40 is driven by the stepping motor 45 in this embodiment, the swing angle and speed can be controlled relatively easily without adding parts.

  The plurality of ice making sections in the first ice making section 48 and the second ice making section 49 are subjected to water repellency treatment on their surfaces, so that the friction between the ice making section inner surface and the frozen ice is reduced, It can be easily peeled off from the inner surface of the ice making compartment.

  As described above, the present embodiment includes a housing having a plurality of water supply ports, an ice tray, an ice making mechanism for rotating the ice tray, and a drive motor provided in the ice making mechanism. By performing individual water supply from the plurality of water supply ports, an ice making section connecting portion for water supply becomes unnecessary, enabling independent individual ice making and preventing deicing while the ice is connected.

  Further, in the present embodiment, by using a stepping motor as the drive motor, the ice tray can be easily swung by a certain angle and the number of times in each ice making section in the ice tray. And making ice with uniform size.

(Embodiment 2)
FIG. 9 is a perspective sectional view of an essential part of the ice tray according to Embodiment 2 of the present invention.

  In FIG. 9, the ice tray 40 is provided with a first ice making unit 48 and a second ice making unit 49 each having a plurality of ice making sections, as in the case of the first embodiment. Between the first and second ice making parts 49, a heat insulating part 50 is provided. In the present embodiment, the ice making sections in the first ice making section 48 and the second ice making section 49 are arranged in a line in the longitudinal direction in parallel with the rotation axis. In the case of the first embodiment, there are a plurality of rows parallel to the rotation axis, but by arranging them in a row, the rotation area of the ice tray 40 can be made small, and a space-saving ice making device is realized. Can do. In addition, since operation | movement, an effect | action, and effect in this Embodiment are the same as that of Embodiment 1, description is abbreviate | omitted.

(Embodiment 3)
FIG. 10 is a perspective sectional view of an essential part of the ice tray according to Embodiment 3 of the present invention.

  In FIG. 10, the ice tray 40 is provided with a first ice making section 48 and a second ice making section 49 each having a plurality of ice making sections, as in the first embodiment. In the present embodiment, the ice tray 40 is integrally formed, has an air layer therein, and insulates the air between the first ice making portion 48 and the second ice making portion 49. As a method of forming the ice tray 40, resin blow molding, gas assist injection molding, or the like can be considered. However, if there is an air layer between the ice making portions, the effect is not changed. In addition, two ice trays formed by normal injection molding may be bonded together, or both may be fixed to form an air layer. By adopting such a molding method, the weight of parts and the number of parts can be reduced, and an ice making device including a simple and low-cost ice tray can be provided. In addition, since operation | movement, an effect | action, and effect in this Embodiment are the same as that of Embodiment 1, description is abbreviate | omitted.

  As described above, the refrigerator according to the present invention includes an ice making device that can reliably separate independent ice, so that it is not only a household refrigerator, but also a commercial ice making machine and various industrial ice making devices. Etc. can be applied.

DESCRIPTION OF SYMBOLS 1 Refrigerator 2 Refrigeration room 3 Ice making room 35 Water supply means 36 Ice making apparatus 37 Water supply tank 38 Water supply pump 39 Water supply pipe 40 Ice tray 41 Ice making mechanism 42 Ice detection lever 43 Housing 45 Stepping motor (drive motor)
48 First ice making part 49 Second ice making part 54 Plural water inlets

Claims (4)

A water supply means comprising a water supply tank disposed in the refrigerator compartment, a water supply pump for delivering water from the water supply tank, and a water supply pipe connected to the water supply pump for discharging water downward; A plate, an ice making mechanism for rotating the ice making plate, a drive motor provided in the ice making mechanism, an ice detecting lever provided in the ice making mechanism for detecting the presence of ice, the ice making plate and the ice making mechanism In an ice making device comprising a housing attached with a plurality of water supply ports provided in the housing, the ice removing operation is performed without twisting the ice making tray, and water is supplied to the ice making tray from a plurality of locations. but, when the ice removing operation, when the ice removing a variant of the ice tray by the water supply of heat to the ice tray, the ice making mechanism is swung a plurality of times at a certain angle to the ice tray Door ice making device which was characterized by. The ice making device according to claim 1, wherein the ice tray includes an ice making part on both sides. The ice making device according to claim 1 or 2, wherein a stepping motor is used as the drive motor, and the ice tray is swung after water supply. A refrigerator provided with the ice making device according to any one of claims 1 to 3.