JP4822803B2 - Storage with automatic ice maker - Google Patents

Description

  The present invention relates to a storage provided with an automatic ice making machine and an ice storage container, and more particularly to a storage provided with an ice detecting lever for detecting the amount of ice in the ice storage container by vertical movement based on an electric mechanism.

An automatic ice maker configured to rotate the ice tray with an electric mechanism to drop the ice in the ice tray downward is disposed in the ice making chamber, and an ice storage container that can be pulled out of the ice making chamber is directly below the ice tray. Some refrigerators detect the full state of ice in an ice storage container by means of an ice detecting lever that moves down into the ice storage container by an electric mechanism for every deicing operation. (For example, patent document 1).
JP 2005-257176 A

  The present invention is also applicable to a case where the size of the ice produced by the ice tray of the automatic ice making machine is small enough to enter from the mouth of a PET bottle (polyethylene terephthalate bottle). It is assumed that the ice is not drawn out of the groove when the ice storage container is pulled out, and the ice storage container can be pulled out smoothly.

In the storage of the first invention, an automatic ice maker configured to rotate the ice tray by an electric mechanism to drop the ice in the ice tray downward is disposed in the ice making chamber, and the ice tray is directly outside the ice making chamber. In the storage provided with an ice storage container that can be pulled out, the ice making cell of the ice tray is partitioned by the partition wall into the same size so as to make small ice entering from the mouth of the PET bottle, and by the descending operation based on the electric mechanism the provided ice detecting lever which detects the amount of ice stored in the ice storage container, wherein the rear wall of the ice storage container, wherein the ice detecting lever lowered state forms a groove top opening that can enter this groove, the ice storage The front end mouth that is the inside of the container is smaller than the size of the ice, and the bottom surface and the left and right side surfaces are formed in an inclined surface from the front end mouth toward the rear end mouth , and the bottom surface of the front end mouth is in a normal position. Descended Than Kikenkori lever is formed in a lower position, the horizontal width of the front end frontage is characterized by than the lateral width of the ice detecting lever is slightly wider.

In the storage of the second invention , the groove has a front end width L2 of the groove that is 2 to 3 times L1 of the left and right thickness L1 of the ice detecting lever, and the rear end width of the groove. L3 is 5 to 7 times L1.

In the first aspect of the invention, even when the ice storage container is pulled out with the ice detection lever in the lowered position, the ice storage container can be pulled out stably without colliding with the rear wall of the ice storage container. In addition, it is possible to provide a technique for preventing the ice detection lever from being damaged by the collision and the rear wall of the ice storage container from being damaged. Also, when the ice storage container once pulled out is inserted into the ice making chamber with the ice detection lever in the lowered position, the ice detection lever enters from the rear of the widened groove, so Breakage and damage to the rear wall of the ice storage container can be prevented. Moreover, even when the ice is small enough to enter from the mouth of a PET bottle (polyethylene terephthalate bottle), the small ice does not fall out of the groove when the ice storage container is pulled out. Therefore, it is possible to save the conventional labor of breaking large ice and entering from the mouth of the PET bottle, and it becomes extremely convenient when combined with an automatic ice making machine that makes small ice.

In the second invention, in addition to the effect of the first invention, the width of the front edge of the groove is limited to a size that prevents the ice from popping out and does not hinder the vertical movement of the ice detecting lever. The width of the rear edge is wide enough to prevent damage to the ice detection lever due to collision and damage to the rear wall of the ice storage container when the ice storage container is inserted into the ice making chamber. This has the effect of smoothing the detection and pulling out and inserting of the ice container.

In the present invention, an automatic ice maker configured to rotate an ice tray by an electric mechanism to drop the ice in the ice tray downward is arranged in the ice making chamber, and can be pulled out of the ice making chamber directly under the ice tray. The ice making cell of the ice tray is partitioned by a partition wall in the same size so as to make small ice entering from the mouth of the PET bottle, and the ice storage container is moved by a lowering operation based on the electric mechanism. the ice detecting lever which detects the amount of ice formed in the rear wall of the ice storage container, the ice detecting lever lowered state forms a groove top opening that can enter this groove, and the ice storage container inner The front end opening is smaller than the size of the ice, and the bottom surface and the left and right side surfaces are formed in a shape of an inclined surface extending from the front end opening toward the rear end opening , and the bottom surface of the front end opening is lowered to a normal position. Ice detection Is formed in the low position than over the lateral width of the front end frontage is reservoir, characterized in that than the lateral width of the ice detecting lever is slightly wider. Examples of the invention are described below.

  Next, an embodiment in which the storage of the present invention is a refrigerator-freezer will be described. FIG. 1 is a front view of a refrigerator-freezer, FIG. 2 is a longitudinal side view of an ice making chamber and a freezer compartment in which an automatic ice maker for a refrigerator refrigerator is installed, FIG. 3 is a front view of an automatic ice-maker portion of a refrigerator-freezer, and FIG. FIG. 5 is a front perspective view of the automatic ice maker portion with the ice compartment door of the refrigerator-freezer opened (drawn), and FIG. 5 shows the state where the ice-maker door of the refrigerator-freezer is opened (drawn) and the entire automatic ice maker is slightly pulled out. FIG. 6 is an exploded perspective view of the automatic ice maker, FIG. 7 is a plan view of an ice tray of the automatic ice maker, FIG. 8 is a side view of the ice tray, FIG. 9 is a rear perspective view of the automatic ice maker, FIG. Fig. 11 is a vertical side view of an automatic ice making machine in which the ice tray is stored, Fig. 11 is a top perspective view of the ice tray placed in the ice storage container, and Fig. 12 is a vertical front view of the ice tray placed in the ice storage container. Fig. 13 is a rear view showing the relationship between the automatic ice maker and the ice storage container. Longitudinal side view showing the relationship between the ice detecting lever movement groove formed in the rear wall of the chromatography and the ice container, Figure 15 is a side view of a PET bottle, FIG. 16 is a top view of a PET bottle body.

  The refrigerator-freezer 1 which concerns on Example 1 is the structure which partitions off the inside of the refrigerator-freezer main body 2 of front opening, and forms several storage chambers, and the front surface of each of these storage chambers can be opened and closed with a door. The refrigerator-freezer main body 2 has a heat insulating structure in which a foam heat insulating material 2C is filled between an outer box (outer wall plate) 2A and an inner box (inner wall plate) 2B. A refrigerator compartment 3, a freezing temperature compartment 5, and a vegetable compartment 4 are partitioned and provided in the refrigerator main body 2 from the top. The freezing temperature chamber 5 is formed with an ice making chamber 6 having a front opening maintained at the freezing temperature at the upper portion by a partition plate (partition plate) 41, and a freezing chamber 5A maintained at the freezing temperature at the lower portion. Yes. An automatic ice maker 7 is attached to the upper part of the ice making chamber 6, and an ice storage container 8 having an upper opening is disposed below the automatic ice maker 7. A freezer compartment 5B is defined on the side of the ice making chamber 6.

  The refrigerating chamber 3 located in the upper part and the freezing temperature chamber 5 (in the figure, the ice making room 6 and the freezing small room 5B) located in the lower part are partitioned by a heat insulating partition wall. The heat insulating partition wall 28 is a heat insulating material 31 in which polyurethane resin is foam-filled between an injection-molded synthetic resin upper plate 29 and an injection-molded synthetic resin lower plate 30, foamed polystyrene or the like previously molded into a predetermined shape, etc. The heat insulating structure provided with the heat insulating material 31 is formed.

  An automatic ice making machine 7 is attached to the upper part of the ice making chamber 6, and an ice storage container 8 having an upper surface opening is disposed immediately below the automatic ice making machine 7. The front opening of the ice making chamber 6 is opened and closed by a pull-out door 14 supported by the support device 18 so as to be movable in the front-rear direction together with the ice storage container 8. The support device 18 is configured such that the rails 16 of the left and right support members 19 extending horizontally from the back side of the door 14 are placed on rollers 17 attached to the left and right walls of the ice making chamber 6. 8, the left and right sides of the ice storage container 8 are placed on the left and right support members 19 so as to be removable upward. With this configuration, with the automatic ice maker 7 left in the ice making chamber 6, the ice storage container 8 is pulled out to the front of the ice making chamber 6 as the pull-out door 14 is pulled out. As shown in FIG. 2, the ice storage container 8 has an ice making tray 7B of the automatic ice making machine 7 entering the upper surface opening by the left and right side walls 8A and the front wall 8B higher than the lower rear wall 8C. With the size of the automatic ice maker 7 wrapped around, the ice maker 7 is stored in the ice making chamber 6 with the drawer 14 being pulled forward in front of the lower rear wall 8C with the ice making chamber 6 left in the ice making chamber 6. The container 8 is pulled out. Therefore, the ice storage container 8 is exposed to the front surface side of the refrigerator-freezer main body 2 in a state in which the pull-out door 14 is sufficiently pulled out, and is attached to the support member 19 so as to be removable upward from the support member 19. It is placed.

  The front opening of the refrigerator compartment 3 is opened and closed by a revolving refrigerator door 10 that is rotated laterally by hinge devices 21 </ b> A and 21 </ b> B on one side of the refrigerator refrigerator body 2. The front opening of the vegetable compartment 4 is opened and closed by a drawer-type door 11 that is supported so as to be movable in the front-rear direction together with the vegetable container by a support device using a combination of left and right rails and rollers, as in the ice making compartment 6. Like the ice making chamber 6, the front opening of the freezing chamber 5 </ b> A is a drawer-type door 12 that is supported so as to be movable in the front-rear direction together with the container 15 by a support device that is a combination of left and right rails and rollers provided in the freezing chamber 5 </ b> A. It is opened and closed at. Similar to the ice making chamber 6, the front opening of the freezer compartment 5B is formed in a drawer type door 13 that is supported in the freezer compartment 5B so as to be movable in the front-rear direction together with the container of the upper surface opening by a support device using a combination of left and right rails and rollers. Open and close.

  Reference numeral 20 denotes a refrigerant compressor installed in a machine room provided at the bottom of the refrigerator-freezer main body 2. The refrigerant compressed by the compressor 20 is condensed by a condenser (not shown), and a decompression unit such as a capillary tube is provided. After passing through the evaporator (cooler) 24 and evaporating, the refrigerant is returned to the compressor 20 and compressed again, and a refrigeration cycle is constituted by these. A blower 25 circulates the cold air cooled by the evaporator (cooler) 24 to the freezing room 5A, the ice making room 6 and the freezing room 5B constituting the freezing temperature room 5, and further to the refrigerating room 3 and the vegetable room 4 through a duct. It is. The freezer compartment 5A, the ice making compartment 6 and the freezer compartment 5B are configured to be cooled by circulating the cool air cooled by the evaporator (cooler) 24 by the blower 25, while the refrigerator compartment 3 and the vegetables The chamber 4 may be configured to be cooled by circulating the cool air cooled by another evaporator (cooler) connected to the refrigeration cycle by another blower.

  The automatic ice maker 7 includes an electric mechanism 7A and an ice tray 7B that is rotationally driven by the electric mechanism 7A, and the electric mechanism 7A and the ice tray 7B together with the automatic attachment / detachment of the power supply line to the electric mechanism 7A are combined with the refrigerator 1 It is configured to be removable by a drawer outside. The ice tray 7B is formed of a twistable synthetic resin material such as polypropylene and has a long shape in the front-rear direction, and a plurality of ice-making cells 7B1 are formed in one row with the longitudinal direction as a row. It is in the form of arrangement. The ice storage container 8 is made of a white, transparent, translucent or other color synthetic resin, and has a box shape with a top opening that is longer in depth than the left and right width.

  Reference numeral 9 denotes a water supply container (also referred to as a water storage container) for storing ice-making water to be supplied to the ice tray 7B of the automatic ice making machine 7. The water supply container 9 has a rectangular shape whose depth is longer than the horizontal width, and is a small chamber partitioned in the refrigerator compartment 3 And is cooled at the temperature in the refrigerator compartment 3. By opening the front door 10 of the refrigerator compartment 3, the water supply container 9 can be taken out to the front of the refrigerator 1 and the upper lid 9A can be opened to inject new water. The ice making water may be pumped from the water supply container 9 by a pump and supplied to the ice tray 7B of the automatic ice making machine 7. In the embodiment, however, the ice making water is supplied from a water supply channel 51 that vertically penetrates the heat insulating partition wall 28 by a natural fall method. The structure supplied to the ice tray 7B of the automatic ice making machine 7 is shown.

  A solenoid 52 is disposed around the water supply channel 51 made of synthetic resin, and an operation rod disposed in the water supply channel 51 is raised by energization of the solenoid 52, and an open / close valve 53 provided at the bottom of the water supply container 9 is provided. When pushed up, the water supply hole 54 at the bottom of the water supply container 9 is opened, and ice-making water is supplied from the water supply channel 51 to the ice tray 7B. Then, when the solenoid 52 is not energized, the on-off valve 53 is lowered by a spring force to close the water supply hole 54 at the bottom of the water supply container 9.

  The automatic ice maker 7 includes an electric mechanism 7A and an ice tray 7B that is rotationally driven by the electric mechanism 7A in the main body member 100. The main body member 100 of the automatic ice maker 7 constitutes a frame in which the members are combined. It will be referred to as member 100. In the housing member 100, an electric mechanism 7A and an ice tray 7B are disposed in front of the electric mechanism 7A. The rear part of the housing member 100 is provided with an electrical connector 120 that is detachably connected to an electrical connector provided on the refrigerator-freezer main body 2 side. The housing member 100 can be pulled out to the front of the ice making chamber 6 using the supporting portion 200 as a rail and can be stored in the ice making chamber 6. With such a configuration, the automatic ice maker 7 including the electric mechanism 7A and the ice tray 7B can be removed by pulling forward of the refrigerator 1 and can be stored in the refrigerator 1.

  A specific configuration related to this will be described below. A partition plate 40 between the ice making chamber 6 and the freezer compartment 5B is attached to the left and right middle portions of the synthetic resin lower plate 30 of the heat insulating partition wall 28 constituting the ceiling wall of the ice making chamber 6 and the freezer compartment 5B. Support portions 200 are formed on the left and right side portions near the ceiling wall portion of the chamber 6 so as to perform a rail function in the front-rear direction. Although the support part 200 is formed by integral molding with the lower plate 30, a structure in which the support part 200 is formed in a rail form extending in the front-rear direction integrally or separately from the left and right walls of the ice making chamber 6 may be used. The left and right flange portions 100A of the housing member 100 are placed on the support portion 200 so that they can be pulled out in the front-rear direction. For this reason, the left and right support portions 200 can be referred to as the left and right rail portions 200.

  The housing member 100 is formed with an automatic ice making unit 101 surrounded by front and rear and left and right walls 101A, 101B, 101C, 101D and a bottom wall 101E. The housing member 100 is formed with an auxiliary ice making portion 105 that accommodates an auxiliary ice tray 7C made of synthetic resin that can be manually twisted so that it can be pulled out forward. The auxiliary ice tray 7C can be manually twisted to take out the ice in the ice making cell 7C1. The automatic ice making unit 101 and the auxiliary ice making unit 105 are adjacently arranged on both the left and right sides with the right wall 101D of the automatic ice making unit 101, which is a partition wall therebetween, as a boundary. The auxiliary ice making unit 105 is surrounded by the front and rear and left and right walls 105A, 105B, 105C (same as 101D), 105D and the bottom wall 105E, and the auxiliary ice tray 7C is placed on the bottom wall 105E so as to be slidable back and forth. . Further, from the form of the housing member 100, the main right side wall 105D and the right bottom wall 105E of the auxiliary ice making unit 105 have a structure in which the integrated members Q are combined.

  The front part of the automatic ice making unit 101 forms the storage part 102 of the ice tray 7B, and the rear part of the automatic ice making part 101 forms the storage part 103 of the electric mechanism 7A. The housing member 100 is made of a synthetic resin, and includes a main body member base (hereinafter referred to as a housing main body) 100B and a cover 106 that covers the upper surface thereof. The cover 106 is attached to the housing main body 100B with screws at the fixing portion 106B so as to cover the automatic ice making portion 101 and the auxiliary ice making portion 105, and forms an upper wall of the housing member 100. Therefore, the storage portion 102 of the ice tray 7B is an area surrounded by the cover 106, the front wall 101A, the left and right walls 101C, 101D, and the bottom wall 101E. The storage portion 103 of the electric mechanism 7A is an area surrounded by the cover 106, the rear wall 101B, the left and right walls 101C, 101D, and the bottom wall 101E. The auxiliary ice making section 105 is an area surrounded by the cover 106, the front wall 105A, the left and right walls 105C, 105D, and the bottom wall 105E. In order to improve the cooling from the bottom surface of the ice tray 7B, an opening R is formed in the bottom wall 101E of the storage portion 102, and in order to improve the cooling from the bottom surface of the auxiliary ice tray 7C, an auxiliary An opening S is formed in the bottom wall 105E of the ice making unit 105.

  In the storage portion 102 of the ice tray 7B, a frame-shaped ice tray support 104 that supports the ice tray 7B is placed on the bottom wall 101E so as to be slidable in the front-rear direction. In the electric mechanism 7A, an electric motor and a speed reduction mechanism that is a combination of a plurality of gears rotated by the electric motor are housed in a case, and a drive shaft 110 that rotates at a reduced speed by the speed reduction mechanism projects in the horizontal direction on the front surface of the case. ing. In the electric mechanism 7A, the left and right engaging claws 7A1 formed on the front upper part of the case are held by the storage portion 103 in a state where the engaging portions 7A1 of the cover 106 are engaged.

  A shaft portion 70 is formed at the front portion of the ice tray 7B, and a bearing portion 71 that rotatably supports the shaft portion 70 of the ice tray 7B is formed at the front portion of the ice tray support 104. The bearing portion 71 is opened upward, and the shaft portion 70 of the ice tray 7B can be taken out and placed on the bearing portion 71 in the vertical direction. A driven shaft 72 is formed at the rear of the ice tray 7B. The drive shaft 110 of the electric mechanism 7A and the driven shaft portion 72 of the ice tray 7B are non-circular and detachable in the front-rear direction so that the non-circular portion of the drive shaft 110 is detachably fitted in the driven shaft portion 72 in the front-rear direction. A coupling power transmission unit 80 is configured. The ice tray 7B has a configuration in which a plurality of ice making chambers (ice making cells) 7B1 are arranged in a plurality of rows with the longitudinal direction as a row, and the longitudinal axis of the ice tray 7B in a state where the refrigerator-freezer 1 is installed in a horizontal state. P, that is, along the axis P passing through the central axis of the shaft 70 and the central axis of the driven shaft 72, the front shaft 70 of the ice tray 7B is placed on the bearing 71 and the rear of the ice tray 7B. In the state where the driven shaft portion 72 is coupled to the drive shaft 110 of the electric mechanism 7A, the ice tray 7B is in a substantially horizontal installation state in which the ice making chamber (ice making cell) 7B1 is opened upward. As a result, the ice tray 7B is rotatably supported along the axis P and is rotated by the electric mechanism 7A.

  At the rear of the ice tray support 104, a circular hole support portion 73 is formed in which a driven shaft portion 72 provided at the rear of the ice tray 7B is supported in a penetrating state. The driven shaft portion 72 at the rear part of the ice tray 7B may be formed simultaneously with the ice tray 7B, but in this embodiment, the driven shaft member in which the front shaft 77 is fitted to the protruding shaft 74 at the rear portion of the ice tray 7B. 75. The driven shaft member 75 is attached with the upper and lower elastic claws 76 engaged with the protruding shaft 74. Since the driven shaft portion 72 is loosely fitted to the support portion 73, the electric mechanism 7A is pulled by pulling the ice tray 7B forward while the shaft portion 70 of the ice tray 7B is slightly lifted from the bearing portion 71. The driven shaft portion 72 of the ice tray 7B is detached from the drive shaft 110, and the ice tray 7B can be detached from the ice tray support 104 in this state.

  In addition, when the ice tray 7B is placed on the ice tray support 104, pulling the ice tray support 104 forward removes the driven shaft 72 from the drive shaft 110, and the ice tray 7B has a front portion. With the shaft portion 70 placed on the bearing portion 71, the rear driven shaft portion 72 is placed on the support portion 73. In this state, the ice tray 7B is held in a substantially horizontal state, and the ice tray 7B is prevented from falling off. In this state, the ice tray 7B can be removed upward from the ice tray support 104. Thus, since the ice tray 7B can be held in a substantially horizontal state in a state where the ice tray support 104 is pulled out, the ice tray 7B is placed on the ice tray support 104 and moved to the normal position of the housing body 100B. When the slide shaft is housed, the driven shaft portion 72 and the drive shaft 110 can be smoothly coupled.

  A drawer handle 78 is rotatably attached to the front surface of the ice tray support 104. The handle 78 is positioned in front of the front wall 104A so as to keep a distance from the front wall 104A of the ice tray support 104, and an upper part is rotatably supported by a shaft 78A, and an applied spring (not shown) force is provided. Thus, the locking projection 79 protruding upward is engaged with the locking portion 81 formed on the cover 106. Due to this engaged state, the ice tray support 104 is kept in the normal position of the storage portion 102 of the ice tray 7B of the housing body 100B, and the drive shaft 110 of the electric mechanism 7A and the driven shaft portion of the ice tray 7B. 72 is fitted and power transmission is possible.

  When the ice tray support 104 is pulled forward from the housing member 100, the handle 78 is rotated by pulling it forward (forward) against the spring force, and the locking projection 79 is disengaged from the locking portion 81. Therefore, the ice tray support 104 can be pulled forward from the housing member 100. A stopper device 111 is provided to prevent the ice tray support 104 from falling off the housing member 100 in a state where the entire top surface of the ice tray 7B is pulled out so as to be almost exposed. As described above, the ice tray 7B can be detached from the ice tray support 104 with almost all the ice tray 7B pulled out.

  In the stopper device 111, when the ice tray support 104 is pulled out, the locking protrusion 113 of the elastic locking piece 112 provided on the bottom rear portion of the ice tray support 104 is formed on the front portion of the bottom wall 101E of the housing member 100. In this mechanism, the ice tray support 104 is prevented from being pulled out by coming into contact with the stopper 114 at the rear end. When removing the ice tray support 104 from the state stopped by the stopper device 111, the ice making tray support 104 is removed in a state where the elastic locking piece 112 is manually pushed up from below and the locking projection 113 is removed from the stopper portion 114. This is accomplished by pulling out the front of the housing member 100.

  As described above, the ice tray 7B can be taken out of the ice making chamber 6 with the electric mechanism 7A left in the ice making chamber 6. Therefore, even when the ice tray 7B is washed with water, the electrical components are not splashed with water. It is a configuration. As a configuration that exhibits this effect, since the electric mechanism 7A for rotationally driving the ice tray 7B is housed in the rear portion of the automatic ice making unit 101, the cold air cooled by the evaporator (cooler) 24 is converted into the ice tray 7B. It cannot be introduced into the ice tray 7B from behind. For this reason, in order to introduce the cool air cooled by the evaporator (cooler) 24 from the cool air passage 91 to the ice tray 7B, the cool air introduction path 90 is formed so as to bypass the automatic ice making machine 7. The cold air introduction path 90 is depressed at a portion corresponding to the auxiliary ice making unit 105 of the cover 106, and automatic ice making is performed so that the cold air supplied from the cold air passage 91 flows into the ice tray storage unit 102 from the side of the ice tray 7B. A cold air introduction path 90 is bent at the side of the portion 101.

  The cold air cooled by the evaporator (cooler) 24 flows from the cold air passage 91 to the cold air introduction passage 90 by the blower 25 and also flows from the cold air passage 92 to the freezer compartment 5A. The cold air that has flowed into the cold air introduction path 90 is diverted by the flow dividing wall 90 </ b> A and flows into the ice making tray storage unit 102 from the opening on the right side of the ice tray storage unit 102. The cold air flowing into the freezer compartment 5A cools the freezer compartment 5A, then returns to the periphery of the evaporator (cooler) 24 from the suction port 93, and is cooled again to circulate as described above.

  The ice tray storage unit 102 and the auxiliary ice making unit 105 communicate with each other through a cold air passage so that the cold air on the ice tray 7B passes to the auxiliary ice tray 7C. That is, the cold air that has flowed into the ice tray receiving section 102 from the cold air introduction path 90 formed by recessing the portion corresponding to the auxiliary ice making section 105 of the cover 106 flows around the ice tray 7B to cool the ice tray 7B. The water in it can be frozen. A wall in which a part of the cold air is a vent hole 83 formed in the right side wall of the ice tray support 104 and a partition wall between the ice tray storage portion 102 and the auxiliary ice making portion 105 that are opened at a position overlapping the vent hole 83. The auxiliary ice tray 7C in the auxiliary ice tray 105 is cooled through the vent hole 84 formed in 101D (same as 105C) to freeze the water in the auxiliary ice tray 7C, so that the hollow portion S and the right side wall 105D It flows out from the vent hole 87 to the ice making chamber 6. Further, the other portions of the cold air that flowed around the ice tray 7B are a portion that flows out from the hollow portion R to the ice making chamber 6 below, and a vent hole 85 formed in the left side wall of the ice tray support 104. There is a portion that flows out to the ice making chamber 6 through the vent hole 86 formed in the left side wall 101C of the ice tray storage unit 102 that is opened at a position overlapping with the vent hole 85. The cold air that has flowed out into the ice making chamber 6 flows into the freezing chamber 5A through a gap around the bottom plate 47 of the ice making chamber 6 and returns to the surroundings of the evaporator (cooler) 24 through the suction port 93 and is cooled again. Repeat the above cycle.

  As described above, the automatic ice maker 7 is supported by the left and right rail portions 200 provided in the ice making chamber 6 in which the housing member 100 is the freezing temperature chamber so as to be slidable in the front-rear direction. For this reason, the automatic ice maker 7 can be pulled out of the ice making chamber 6 by pulling out the housing member 100, and can be stored by sliding. In order to store and hold the automatic ice making machine 7 in a regular position in the ice making chamber 6, a lock device 95 is provided for holding the housing member 100 in the regular position. The locking device 95 is pivotable on the front wall of the housing member 100, and a locking recess 97 formed by recessing upward in the synthetic resin lower plate 30 of the heat insulating partition wall 28 constituting the ceiling wall of the ice making chamber 6. It is comprised in combination with the lock lever 96 attached to.

  The housing member 100 can be held in the normal position by engaging the upper end of the lock lever 96 with the locking recess 97 while the housing member 100 is stored in the normal position. Further, the housing member 100 can be pulled out from the ice making chamber 6 in a state where the lock lever 96 is rotated and removed from the locking recess 97.

  The ice making water supplied from the water supply channel 51 to the ice making tray 7B is supplied to one of the ice making cells 7B1 of the ice making tray 7B and is sequentially supplied from there to the other ice making cells 7B1. Therefore, a water supply hole 106A is formed in the cover 106 at a position corresponding to one ice making cell 7B1 at the rear of the ice tray 7B, and the lower end of the water supply path 51 corresponds to the water supply hole 106A. A groove 106 </ b> D is formed in the cover 106 so as to open rearward from the water supply hole 106 </ b> A so that the lower end of the pipe forming the water supply path 51 does not hit the cover 106 when the housing member 100 is pulled forward.

  As described above, the automatic ice making machine 7 is attached to the housing member 100 disposed along the upper wall 30 of the ice making chamber 6 so as to be disposed in the vicinity of the upper wall of the ice making chamber 6, and the freezing temperature chamber. Are supported by the left and right rail portions 200 provided in the ice making chamber 6 so as to be slidable in the front-rear direction. For this reason, the electric line which electrically connects the electrical equipment part and control circuit part by the side of the refrigerator-freezer main body 2 and the electric mechanism 7A is a detachable connector mechanism. This specific configuration will be described below.

  The housing member 100 is provided with an automatic ice maker 7 side connector 120, and a connector (not shown) to which electric power is supplied from an electrical component (not shown) of the refrigerator / freezer main body 2 through a lead wire to the refrigerator / freezer main body 2 side. Not shown). The automatic ice maker 7 side connector 120 connected to the electric mechanism 7A is provided to protrude rearward from the rear portion of the housing member 100, specifically, to the housing main body 100B. The connector on the refrigerator-freezer body 2 side is attached to the synthetic resin lower plate 30 so as to be close to the upper wall 30 of the ice making chamber 6. In order for the automatic ice making machine 7 to be housed in the refrigerator-freezer 1, the left and right portions 100 </ b> A of the housing member 100 are placed on the support portion 200 and pushed in, so that the automatic ice-making machine 7 reaches a predetermined position in the refrigerator-freezer 1. 120 is connected to a connector on the refrigerator-freezer body 2 side. In order to facilitate the pushing-in of the housing member 100, the combination of the housing member 100 and the support portion 200 is given a little flexibility, so that the connection of both connectors has a little flexibility. By doing so, the connection between both connectors becomes smooth.

  As this specific configuration, the terminal portion of the connector 120 is constituted by a protruding pin, and the connector on the refrigerator refrigerator body 2 side is a terminal portion in the form of a hole into which the protruding pin is inserted. Even if the housing member 100 is slightly displaced up and down, left and right, the inlet of the connector hole on the freezer refrigerator body 2 side is slightly widened so that the protruding pin of the connector 120 can easily enter the connector hole on the refrigerator refrigerator body 2 side. is there. Further, the connector 120 has a flexible mounting structure so that the connector 120 can move slightly in the vertical and horizontal directions.

  In the automatic ice making machine 7, the housing member 100 is supported by the left and right rail portions 200 provided in the ice making chamber 6 which is a freezing temperature chamber so as to be slidable in the front-rear direction. The ice making chamber 6 can be used as a freezer for storing frozen food by removing it from the chamber 6 and also removing the ice storage container 8 from the ice making chamber 6.

  By pulling out the housing member 100, the automatic ice making machine 7 is removed from the ice making chamber 6. Therefore, in this state, a connector cover (not shown) is provided to cover the terminal portion of the connector on the refrigerator-freezer main body 2 side. In the state where the housing member 100 is pulled out from the ice making chamber 6, this connector cover covers the terminal portion of the connector on the side of the refrigerator refrigerator 2, and the housing member 100 is left and right to store the housing member 100 in the ice making chamber 6. By sliding backward along the rail part 200, it is pushed up along the inclined surface of the upper surface of the pair of left and right operating parts 133 projecting rearward of the housing member 100, and the terminal part of the connector on the refrigerator / refrigerator main body 2 side is pushed up. It is a configuration that gradually becomes exposed.

  The pair of left and right operating pieces 133 are disposed close to both the left and right sides of the connector 120 to protect the connector 120, and the cover portion 134 of the housing member 100 is configured to cover the pair of left and right operating pieces 133 from both the left and right sides and the lower side. It is provided on the rear wall. When the housing member 100 is pulled out, the cover part 134 protects the connector 120 and the pair of left and right operating pieces 133 from collision with other objects.

  The ice making operation of the automatic ice making machine 7 includes an ice making process and a deicing process controlled by a control circuit unit provided in the refrigerator 1. When the ice making process is started in a state where a sufficient amount of ice making water is contained in the water supply container 9 set at a predetermined position in the refrigerator compartment 3, the solenoid 52 is energized for a predetermined time by the control circuit unit, and is opened and closed. The valve 53 opens the water supply port 54, and a predetermined amount of ice making water required for one ice making is automatically supplied to the ice making tray 7B by natural fall.

  By supplying water to the ice tray 7B, the water in the ice tray 7B is frozen, and when the timer means of the control circuit unit has passed for a certain period of time, or the ice tray sensor detects the lowered temperature of the ice tray 7B when ice is formed. Then, the control circuit unit shifts from the ice making process to the deicing process. When the deicing process is started, the electric mechanism 7A is started and the ice tray 7B is rotated counterclockwise in FIG. 8 and inverted, and the protrusion 7B20 provided at the front portion of the ice tray 7B is the ice tray support 104. The ice tray 7B is twisted by coming into contact with the stopper portion 104B, and the ice in the ice tray 7B is dropped to the ice storage container 8 below. After this twisting, the ice tray 7B is returned and rotated clockwise in FIG. 6 to return the ice tray 7B to the horizontal state. In this state, the next ice making process starts automatically, and after supplying water again, the above operation is performed. By performing such an ice making operation cycle, ice is stored in the ice storage container 8. In the deicing step, the ice tray 7B may be rotated clockwise.

  The amount of ice in the ice storage container 8 is detected by the ice detecting lever 140 that is lowered by the electric mechanism 7A at every ice making process, every deicing process, or every predetermined time (for example, every 30 minutes). The ice detecting lever 140 is arranged on the side of the ice tray 7B so as not to obstruct the rotation of the ice tray 7B. In the ice detecting standby state, the ice detecting lever 140 is at the standby position 140B raised as shown in FIG. Then, in accordance with the ice detecting operation, the inside of the ice storage container 8 is lowered through the opening R, and as shown in FIG. 2, the detecting portion 140A becomes substantially horizontal at the lowest lowered position that is the ice detecting position, and the amount of ice is detected. To do. When the amount of ice in the ice storage container 8 becomes full, the ice detecting lever 140 is restricted from descending by the ice, so this state is electrically detected and the ice tray before entering the next ice making process. It is a mechanism to stop water supply to 7B.

  As a method for detecting the fullness of the ice amount, when the ice in the ice storage container 8 is full, the ice detection lever 140 is prevented from descending to the lowest position by the ice, so the electric mechanism 7A at this time There is a method in which the increase in the motor current is detected and the control circuit unit determines that the motor current is full. As another method, a switch that operates when the ice detecting lever 140 reaches the lowest position is provided, and this switch is operated within a predetermined time after the ice detecting lever 140 starts to descend by the control circuit unit. There is a method of determining that the switch is not full when the switch is operated and determining that the switch is full when the switch is activated within a predetermined time. As another method, there is a method in which the control circuit unit determines that the ice detecting lever 140 is full when it does not reach the lowest position even after a predetermined time has elapsed since the start of the descending operation. Other methods may also be used.

  As shown in FIGS. 11 and 12, in the ice storage container 8, the ice tray 7B removed from the automatic ice maker 7 is placed horizontally on the side (lateral side) immediately below the ice tray 7B of the automatic ice maker 7. For this purpose, a placement unit 210 is provided in the ice storage container 8 so that ice can be made here. The placement unit 210 may be one using a side wall of the ice storage container 8 or may be formed of a member different from the ice storage container 8. In the embodiment, a form in which the side walls of the ice storage container 8 are used to support the left and right flange portions of the ice tray 7B is shown.

  That is, a step portion 211 extending in the front-rear direction in a substantially horizontal state is formed at the upper and lower intermediate portions of the inner surface of the side wall (right side wall in FIGS. 11 and 12) of the ice storage container 8. One of the mounting portions 210 is formed by a standing wall 212 which is parallel to the step portion 211 at substantially the same height. The gap between the step portion 211 and the standing wall 212 is such that the flange portions 213 and 214 on both the left and right sides of the ice tray 7B are placed with the bottom of the ice making cell 7B1 entering between the step portion 211 and the standing wall 212. It is constituted so that. In the figure, the flange portions 213 and 214 on both the left and right sides are in a form in which the front and rear portions thereof are placed.

  The standing wall 212 can be formed by a fixed partition wall that partitions the inside of the ice storage container 8 to the left and right. In the embodiment, the standing wall 212 is formed by a movable partition wall 212 that can change the mounting position of the standing wall 212. The movable partition wall 212 has a length extending over support ribs 215A and 215B formed to protrude from the inner surface of the front wall 8B and the rear wall 8C of the ice storage container 8, and corresponds to a pair of front and rear support ribs 215A and 215B. A vertical groove 218 is formed at the front end and the rear end of the partition wall 212. Therefore, the vertical groove 218 is fitted and attached to the support ribs 215A and 215B by inserting the partition wall 212 from above with the vertical grooves 218 corresponding to the support ribs 215A and 215B.

  In order to facilitate the placement of the ice tray 7B, the ice tray 7B is slidable back and forth while being placed on the step portion 211 and the partition wall 212. And the height of the step part 211 and the standing wall 212 which comprise the mounting part 210 so that the mounted ice tray 7B may become the height hold | maintained in the position lower than the highest part of the surrounding wall of the ice storage container 8. FIG. Is set. As described above, with the automatic ice making machine 7 left in the ice making chamber 6, that is, in a state where the housing member 100 is set in the ice making chamber 6, the ice storage container is drawn along with the drawer door 14 being pulled forward. 8 is also pulled out, so that the rear wall 8C is low so as not to obstruct the drawer, and the other side wall 8A and the front wall 8B are particularly in a state where the ice tray 7B has entered so that ice falling from the ice tray 7B does not jump out. It is formed so as to cover the automatic ice making machine 7. For this reason, the height of the stepped portion 211 and the standing wall 212 is slightly lower than the lowest rear wall 8C, and the ice tray 7B is supported at substantially the same height as the rear wall 8C, as shown in FIGS. In this configuration, the ice tray 7B is supported at a substantially central portion above and below the side wall 8A.

  By supporting the ice tray 7B at such a position, the ice tray 7B is in a support state that does not interfere with the bottom of the housing 100 positioned above the ice tray 7B. A space is formed between the side wall 8A and the partition wall 212 below the ice tray 7B supported at such a position. This space can be used as an ice storage chamber, and the space on the side of this space, that is, the left part of the standing wall 212 in the figure may be used as an ice storage chamber, but the housing 100 is pulled out and removed. When the inside of the ice storage container 8 is used as a storage room for frozen food, it can also be used as a storage room for frozen food.

  In addition to the pair of front and rear support ribs 215A and 215B, the front and rear walls 8B and 8C of the ice storage container 8 are provided with a pair of front and rear support ribs 216A and 216B and a pair of front and rear support ribs 217A and 217B. When the ice tray 7B is not placed in the ice storage container 8, it is convenient when the frozen food is divided and stored in the ice storage container 8 by attaching the movable partition wall 212 to the support ribs 216A and 216B. . Further, when the ice storage container 8 is used without being separated, the movable partition wall 212 may be removed, but there is a risk of losing it. In that case, the ice storage container 8 is attached to the support ribs 217A and 217B. Can be held close to the side wall 8A, and the inside of the ice storage container 8 can be widened for use.

  Further, when the auxiliary ice making unit 105 is formed in the housing 100 as described above, the auxiliary ice tray 7C is placed when the housing 100 is pulled out and removed, and the ice storage container 8 is used as a frozen food storage room. It can also be used in the same manner as the ice tray 7B by being placed on the portion 210, that is, placed on the step portion 211 and the standing wall 212. For this reason, the auxiliary ice tray 7C is configured in a form that can be placed on the step portion 211 and the standing wall 212 that constitute the placement portion 210 in the same manner as the ice tray 7B. As a result, the bottom of the ice making cell 7C1 of the auxiliary ice tray 7C enters between the step portion 211 and the standing wall 212 in a state where the auxiliary ice tray 7C is placed on the placement portion 210.

  As described above, since the placing unit 210 for placing the ice tray 7B or the auxiliary ice tray 7C removed from the automatic ice making machine 7 in the horizontal state is provided in the ice storage container 8, the automatic ice making machine 7 is made into the ice making machine. When the ice storage container 8 is used as a frozen food storage room after being detached from the chamber 6, an ice making part for taking out ice manually can be formed in the ice storage container 8, and the ice storage container 8 is used for storing frozen food and making ice. It can be used for two roles, improving convenience.

  In such a storage 1, the ice tray 7B, the ice storage container 8, and the ice detecting lever 140 according to the present invention will be described. First, as shown in FIG. 7, the ice tray 7B is an array of eight rows of eight ice making cells 7B1 arranged in a row, and each ice making chamber (ice making cell) 7B1 has the same size. This is a size for making small ice that can be inserted from the mouth 301 of the PET bottle 300. As shown in FIGS. 15 and 16, the PET bottle 300 has an inner volume of 300 ml (milliliter), 500 ml (milliliter), or 2000 ml (milliliter), and the size of the opening 301 that is opened and closed by the screw cap 302. Are the same, the outer diameter S2 of the threaded portion of the mouth 301 of the PET bottle 300 is about 28 mm, and the inner diameter S1 of the mouth 301 is about 20 mm. For this reason, it is preferable that the size of the ice made in each ice making chamber (ice making cell) 7B1 is slightly smaller than the inner diameter S1 of the mouth 301.

  The ice-making water supplied from the water supply channel 51 is supplied to a specific ice-making chamber 7B11 in the ice-making chamber (ice-making cell) 7B1 formed by the partition wall 7B5. The supplied ice-making water is supplied to each ice-making chamber. A water passage 7B2 is formed in the partition wall 7B5 between the ice making chambers (ice making cells) 7B1 by cutting out the central portion of the partition wall 7B5 so as to sequentially flow to the (ice making cell) 7B1. The water flow channel 7B2 is a predetermined partition wall between the vertical water flow channel 7B2A formed in all the partition walls 7B5 of the ice making chambers (ice making cells) 7B1 arranged in each row direction and the ice making chambers (ice making cells) 7B1 between the rows. And a lateral water passage 7B2B formed in the partition wall 7B5. As a result, the ice making water supplied to the specific ice making chamber 7B11 in the ice making chamber (ice making cell) 7B1 flows into the adjacent ice making chamber 7B1 through each water passage 7B2, and the ice making water further flows into the adjacent ice making chamber 7B1. Due to the relationship of flowing into the small chamber 7B1, the ice making water sequentially flows into the adjacent ice making small chamber 7B1, and each ice making small chamber 7B1 is filled with the ice making water. The ice tray 7B circulates the surrounding wall 7B6 higher than the ice making chamber 7B1 so that the ice making water supplied to the ice making chamber (ice making cell) 7B1 does not fall down. This supply of ice making water is time-controlled as described above.

  The specific ice making chamber 7B11 of the ice making chamber (ice making cell) 7B1 into which the ice making water supplied from the water supply channel 51 first enters is one end when viewed from the center in the length direction (front-rear direction in the figure) of the ice tray 7B. Any ice making chamber (ice making cell) 7B1 out of the ice making chambers 7B1 located on the side or the other end side (in the illustrated case, the rear half or the front half) may be supplied from the water supply channel 51. It is preferable that the ice making water is quickly distributed to each ice making chamber (ice making cell) 7B1. For this purpose, one of the ice making chambers 7B1 located on one end side or the other end side (in the illustrated case, the rear half or the front half) as viewed from the center of the ice tray 7B in the length direction (the front-rear direction in the figure). It is preferable that water is supplied from the water supply channel 51 to the ice making chamber (ice making cell) 7B11 located on the farthest side, and among them, one end side as viewed from the central part in the length direction (front-rear direction in the figure) of the ice making plate 7B Alternatively, an ice making chamber (ice making cell) located in a corner portion of the ice making chamber (ice cell) 7B1 located on the farthest side of the ice making chamber 7B1 located on the other end side (in the illustrated case, the rear half or the front half). The cell 7B1 may be the ice making chamber (ice making cell) 7B11 into which the ice making water supplied from the water supply channel 51 first enters. In the embodiment, an ice making chamber (ice making cell) 7B1 located at a corner portion of the ice making chamber 7B1 located at the rear end in the length direction (the front-rear direction in the figure) of the ice tray 7B is supplied from the water supply channel 51. An ice making chamber (ice making cell) 7B11 into which ice making water enters first is used.

  As described above, the amount of ice in the ice storage container 8 is detected by the lowering operation of the ice detecting lever 140. When the ice detecting lever 140 is lowered, the ice detecting lever 140 is moved as shown in FIG. Since it has entered a position lower than the rear wall 8C in the ice storage container 8, even when the ice storage container 8 is pulled out in this state, it must be prevented from colliding with the rear wall 8C of the ice storage container 8. For this reason, the rear wall 8C does not collide when the ice detecting lever 140 is lowered, and when the ice storing lever 140 is lowered, the rear wall 8C does not collide when the ice storage container 8 is pulled out. A moving groove (also referred to as an escape groove) 219 is formed in the rear wall 8C. The groove 219 penetrates the rear wall 8C and forms an upper surface opening.

  When the size of the ice made by the plurality of ice making cells 7B1 of the ice tray 7B is made small enough to enter from the mouth 301 of the PET bottle (polyethylene terephthalate bottle) 300, the size of the groove 219 is set. In the case of a size with a margin in consideration of the relationship with the ice detecting lever 140, when the ice storage container 8 is pulled out vigorously when the inside of the ice storage container 8 is full of ice, the ice is extracted from the groove 219. It must be designed not to spill. For this reason, it goes without saying that the ice detecting lever 140 does not collide with the ice storage container 8 at the lowest position lowered by the ice detecting operation. However, when the ice storage container 8 is pulled out, the ice detection is performed on the rear wall 8C of the ice storage container 8. When the lever 140 does not collide, and the ice storage container 8 is pulled out with the ice detection lever 140 lowered, and the ice storage container 8 is inserted into the ice making chamber again with the ice detection lever 140 lowered. In addition, the ice detecting lever 140 in the lowered state does not collide with the rear wall 8C of the ice storage container 8, and the insertion of the ice storage container 8 is not prevented, and the ice detecting lever 140 is not damaged. It is necessary to prevent the ice from falling from the groove 219 even when the ice storage container 8 is pulled out vigorously.

  By the way, it is desirable that ice be made in a uniform size, but the size is not always uniform due to lack of water supply, ice cracking, sublimation after ice making, etc. Smaller ice may also be present in the ice container 8. Such ice tends to fall from the groove 219. For this reason, in this embodiment, the automatic ice making machine 7 is disposed so that the ice detecting lever 140 does not extend from the front side (front side) of the refrigerator-freezer 1 to the rear side, but extends from the rear side to the front side. That is, when the automatic ice making machine 7 is arranged so that the ice detecting lever 140 extends from the front side (front side) to the rear side, the groove 219 that is the escape of the lowered ice detecting lever 140 is from the rear side to the front side. As a shape that widens toward the end, it is necessary to absorb the blur at the tip of the ice detecting lever 140. However, when the groove 219 has a shape that is widened by an inclined surface from the rear to the front as described above, the expanded inclined surface serves as a guide for the above-mentioned small ice pop-out, and when the pull-out door 14 is opened and closed, This ice is guided outside the ice storage container 8 to help spill out.

  In the present embodiment, in order to suppress the occurrence frequency of such a situation, the automatic ice maker 7 is disposed so that the ice detecting lever 140 extends from the rear part of the refrigerator-freezer 1 to the front side (front side), and the groove 219 is provided. Is shaped to spread from the front to the rear. In other words, the passage groove 219 has a shape in which the inclined surfaces 220A and 220B are formed from the rear end to the front end so that the bottom and side faces thereof are narrower than the rear end. Further, the width L2 of the front end of the passage groove 219 is slightly wider than the left and right thickness L1 of the ice detecting lever 140 so as to cope with the shake of the ice detecting lever 140.

  Further, the groove 219 is deeply formed so that the bottom level P2 of the groove 219 is lower than the lower end level P1 of the ice detecting lever 140 in a state where it is lowered to the normal position. When the ice storage container 8 is inserted into the ice making chamber with the ice detecting lever 140 lowered, the ice detecting lever 140 in the lowered state is in a horizontal position where the detecting portion 140A is at the lowest lowered position as shown in FIGS. Of course, even when the tip of the detection portion 140A is slightly tilted downward due to errors in assembly or the like, when the ice storage container 8 is inserted into the ice making chamber, the insertion can be performed safely. Therefore, the passage groove 219 is formed so that the rear end depth T1 is further deeper than the front end depth T2, so that the passage groove 219 has a bottom surface from the rear end toward the front end. An inclined surface 220A is formed to rise.

  Thus, even when the ice storage container 8 is inserted into the ice making chamber when the tip of the ice detecting lever 140 is lowered due to an error such as assembly, the tip of the ice detecting lever 140 is inclined to the bottom surface of the passage groove 219. Since it is guided along 220A, the ice storage container 8 can be inserted into the ice making chamber without damaging the ice detecting lever 140. Further, when the ice storage container 8 is inserted into the ice making chamber, even if the tip of the ice detecting lever 140 is swayed from side to side, the passage groove 219 is preferably guided to the passage groove 219. The lateral width L3 of the rear end is formed wider than the lateral width L2 of the front end, and the side surface of the passage groove 219 forms an inclined surface 220B from the rear end toward the front end.

  In order to obtain the stable ice detection operation as described above and the stable insertion of the ice storage container 8 into the ice making chamber, the front edge width L2 of the passage groove 219 is L1 with respect to the left and right thickness L1 of the ice detection lever 140. 2 to 3 times, and the width L3 of the rear end of the passage groove 219 may be 5 to 7 times L1. As one example in this case, when the left and right thickness L1 of the ice detecting lever 140 is 3 mm, the front edge width L2 of the passage groove 219 is 6 mm, and the rear edge width L3 of the passage groove 219 is 15 mm. Preferred results were obtained at ˜20 mm.

  The automatic ice making machine of the present invention is not limited to the above embodiment, and the arrangement relationship of the refrigerator compartment, the freezing room, the ice making room, etc. of the refrigerator-freezer is not limited to the above form, and further, the configuration of the automatic ice making machine, etc. However, the present invention is not limited to the above-described form, and can be applied to various types of refrigerator-freezers without departing from the technical scope of the present invention.

It is a front view of the refrigerator-freezer of the present invention. Example 1 It is a vertical side view of the ice making room and the freezing room part which installed the automatic ice making machine of the refrigerator-freezer main body of this invention. Example 1 It is a front view of the automatic ice maker part of the refrigerator-freezer of this invention. Example 1 It is a front perspective view of the automatic ice maker part in the state where the ice making room door of the refrigerator-freezer of the present invention is opened (drawn). Example 1 It is a front perspective view of the state where the ice making room door of the refrigerator-freezer of the present invention is opened (drawn) and the automatic ice making machine is slightly pulled out. Example 1 It is a disassembled perspective view of the automatic ice making machine of this invention. Example 1 It is a top view of the ice tray of the automatic ice making machine of this invention. Example 1 It is a side view of the ice tray of this invention. Example 1 It is a back perspective view of the automatic ice making machine of this invention. Example 1 It is a vertical side view of the automatic ice making machine in which the ice tray of the present invention is stored. Example 1 It is an upper surface perspective view of the state which installed the ice tray in the ice storage container of the present invention. Example 1 It is a vertical front view of the state which installed the ice tray in the ice storage container of this invention. Example 1 It is a rear view which shows the relationship between the automatic ice maker part of this invention, and an ice storage container. Example 1 It is a vertical side view which shows the relationship between the ice detection lever of this invention and the movement groove | channel for ice detection levers formed in the rear wall of the ice storage container. Example 1 It is a side view of a PET bottle concerning the present invention. Example 1 It is a top view of the PET bottle main body regarding this invention. Example 1

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Refrigeration refrigerator 2 ... Refrigeration refrigerator main body 3 ... Refrigeration room 4 ... Vegetable room 5 ... Freezing room 5A ... Freezing room 6 ... Ice making room 7 ... Automatic ice making machine 7A · · Electric mechanism 7B · · Ice tray 7B1 for automatic ice making machine · · Ice making chamber (ice making cell)
7B2 ・ ・ Water channel 7B2A ・ ・ Vertical water channel 7B2B ・ ・ Horizontal water channel 7B5 ・ ・ Partition wall 7C ・ ・ Auxiliary ice tray 8 ・ ・ ・ Ice storage container 8A ・ ・ Side container side 8B ・ ・ In front of ice storage container Wall 8C ··· Rear wall of ice storage container 9 · · · Water supply container 24 · · Cooling device 25 · · Blower 28 · · Insulation partition wall of refrigerator compartment and ice making chamber 51 · · Water supply channel 52 · · Solenoid 53 · · Opening and closing valve 54..Water supply port 70..Shaft portion of ice tray 71..Bearing portion 72 ... Drive shaft portion of ice tray 80 ... Power transmission portion 95 ... Lock device 96 ... Lock lever 97 ...・ Locking recess 100. ・ Main body member (housing member)
100A .. Left and right parts of main body member (housing member) 100B.
101.. Automatic ice making unit 102.. Ice tray storage unit 103.. Electric mechanism storage unit 104.. Ice tray support 105. · · Elastic locking piece 114 · · Stopper portion 120 · · Refrigeration refrigerator main body side connector 140 · · Ice detection lever 200 · · Support portion (rail portion)
210 .. Placement part 211 .. Step part 212 .. Standing wall (partition wall)
219 .. Groove 220A .. Inclined surface 220B .. Inclined surface 300 ... PET bottle 301 ... PET bottle mouth

Claims (2)

An automatic ice maker configured to rotate the ice tray with an electric mechanism to drop the ice in the ice tray downward is disposed in the ice making chamber, and an ice storage container that can be pulled out of the ice making chamber is directly below the ice tray. In the provided storage, the ice making cell of the ice tray is partitioned by a partition wall in the same size so as to make small ice entering from the mouth of the PET bottle, and the amount of ice in the ice storage container by the lowering operation based on the electric mechanism An ice detecting lever is provided, and a groove is formed on the rear wall of the ice storage container so that the ice detecting lever in a lowered state can enter, and this groove has a front end opening on the inside of the ice storage container. The ice bottom is smaller than the size of the ice, and the bottom surface and the left and right side surfaces are formed in an inclined surface extending from the front edge to the rear edge , and the bottom surface of the front edge is lower than the ice detecting lever lowered to a normal position. Also Is formed at a position, the horizontal width of the front end frontage reservoir, characterized in that than the lateral width of the ice detecting lever is slightly wider. The groove has a front edge width L2 of 2 to 3 times L1 with respect to the left and right thickness L1 of the ice detecting lever. The storage according to claim 1, wherein the storage is doubled.

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