JPH0618878U - Ice storage structure of ice machine - Google Patents

Abstract

(57) [Summary] [Purpose] To reduce the number of parts and to perform assembly work efficiently. [Structure] The ice storage 14 includes a pair of side walls, a rear surface wall 80, and a bottom surface 81. An ice storage chamber 83 is defined below the inside of the ice storage 14. A notch is formed at the upper end of the side wall to which a bracket for suspending and supporting the ice making unit 15 is fixed. The rear wall 80 is provided with a drainage receiving portion 19 for collecting the ice making water discharged from the water tray 16. A storage unit 82 defined at the bottom of the ice storage 14 is provided with an ice block releasing device 13
The screw 63 for carrying out the ice block is stored. Storage part 8
A discharge port 14a for discharging the ice block 21 conveyed by the screw 63 to the outside is opened in the vicinity of the front side end portion of 2.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an ice storage structure of an ice making machine. More specifically, the ice making operation is performed by immersing a large number of ice making projections protruding from the lower surface of an ice making substrate in ice making water in an ice making chamber defined inside a water tray. In an ice-making machine that is designed to form an inverted dome-shaped ice block around the ice-making protrusions, an ice storage for storing the ice-blocks is installed in the ice-making substrate, water tray, etc. The present invention relates to an ice storage structure in which the receiving part and the like are integrally formed so that the number of parts can be reduced and the assembling work can be performed efficiently.

[0002]

[Prior art]

 Many types of ice-making machines have been proposed as automatic ice-making machines for continuously producing a large number of ice blocks such as ice cubes, and an appropriate method is adopted according to the application. For example, a large number of partition plates are arranged vertically and horizontally to define a large number of ice making small chambers that open downward, and ice water is jetted and supplied to the corresponding ice making small chambers from the water tray arranged below it. Do not use a closed cell type ice making machine that forms ice cubes in each ice making chamber that is cooled by an evaporation pipe connected to the freezing system, or the water tray, and put ice making water from below into these ice making chambers. By spraying, the ice-making machine of the open cell type that forms ice cubes in each small chamber, or one side of the ice-making plate placed upright, and the ice-making water is made to flow down from above to make the ice-making plate surface. A water-flowing type ice making machine that forms a large number of kamaboko-shaped ice blocks is known.

The above-mentioned three types of ice making machines are each equipped with an ice making water tank for storing a required amount of ice making water, and the ice making water in the tank is pumped to the ice making unit of the ice making unit. Alternatively, a forced circulation mechanism is adopted in which the ice making water supplied to the upright ice making plate and not frozen is collected in the tank and then sent again to the ice making unit. Therefore, these ice makers require additional equipment such as an ice making water tank and a pump that circulates ice making water, which complicates the configuration, raises the manufacturing cost, and contributes to the increase in size. On the other hand, as disclosed in, for example, Japanese Patent Application Laid-Open No. 52-69046, ice-making projections are formed by storing ice-making water in a water tray at a required level and projecting from the lower surface of an ice-making substrate provided with an evaporation pipe. A simple ice-making machine has been already proposed in which an ice block is formed around the ice-making projections by immersing the ice-making water in the ice-making water. Since this ice machine does not require a mechanism for pumping circulation of ice making water between the water tray and the ice making water tank during the ice making operation, it can be structurally simplified and the production cost can be suppressed. It has the advantage of being able to manufacture an ice machine with a small size.

[0004]

[Problems to be solved by the device]

 In the above-mentioned ice making machine, the ice making unit is arranged above the box formed by the heat insulating wall, and the ice storage for the ice blocks is arranged below the ice making unit. Inside this ice storage, there is a drainage receiving part (manifold) for receiving the ice making water remaining in the water tray and discharging it when the water tray tilts after the ice making operation is completed. Arranged and fixed. In addition, a pipe piped inside the ice storage is connected to the drainage receiver, so that the drainage received by the drainage receiver is discharged to the outside of the machine through a pipe. As described above, since the drainage receiving part is manufactured separately, the number of parts is increased, and the work of arranging the drainage receiving part and the pipe inside the ice storage is complicated, and it takes time to assemble. there were. In addition, it is necessary to form a part to install the ice making unit in the box located above the ice storage, which causes a problem of increasing the number of processing steps.

Further, in the ice making machine, the ice blocks stored in the ice storage are taken out through a scoop or the like by opening the opening / closing door arranged in the box body. It is pointed out that it may come into contact with the stored ice blocks, resulting in unsanitary conditions.

[0006]

[The purpose of the device]

 The present invention resides in an ice making machine in which an ice making protrusion cooled by an evaporation pipe is immersed in ice making water stored in an ice making chamber in a water tray to form an ice block around the ice making protrusion. In view of the above-mentioned drawbacks, it has been proposed to suitably solve this, and an object thereof is to provide an ice storage structure that can reduce the number of parts and efficiently perform an assembly operation.

[0007]

[Means for Solving the Problems]

 In order to overcome the above-mentioned problems and achieve the intended purpose, the present invention provides an evaporation pipe connected to a refrigeration system including a compressor, a condenser, etc., and this evaporation pipe is arranged on the upper surface and a large number on the lower surface. An ice making unit consisting of an ice making substrate in which the ice making parts of the above are suspended from each other at predetermined intervals, and a water tray which is always kept in a horizontal posture and in which the ice making parts are immersed in the ice making water in the ice making chamber defined inside. In the ice making machine configured to tilt the water tray obliquely downward when the ice making water is frozen around the ice making unit to form a required ice block, a pair of side walls spaced apart from each other by a predetermined distance, The rear wall formed at the rear end of the side wall, the bottom formed at the bottom of the side wall, and the storage section form an ice storage compartment that opens forward and upward. Storing the ice blocks produced by the facing ice making unit An ice storage chamber is defined, and a drain receiving portion for collecting ice making water discharged from the water tray when the water tray is tilted is formed on the rear wall, and the rear wall and the drain receiving portion are formed. It is characterized in that the water tray is in contact with the continuous edge portion of and is held in an inclined posture.

[0008]

【Example】

 Next, an ice storage structure of an ice making machine according to the present invention will be described below with reference to the accompanying drawings with reference to preferred embodiments. For convenience of explanation, the terms “front and rear” and “left and right” are referred to when the ice making machine is viewed from the front.

(Regarding Schematic Configuration of Ice Maker) FIGS. 1 and 10 are a cross-sectional view and a perspective view schematically showing an overall configuration of an ice maker in which an ice storage structure according to an embodiment is adopted. The inside of the casing 10 constituting the ice making machine main body is a lower machine room 12 in which a refrigerating machine such as a compressor CM and a condenser 11 is housed, and an ice lump discharging device 13 located above the lower machine room 12 and surrounded by a heat insulating material. It is basically configured by an ice storage unit 14 in which is provided and an ice making unit 15 disposed above the inside of the ice storage unit 14. As will be described later with reference to FIGS. 1 and 4, the ice making unit 15 includes a water tray 16 for storing ice making water at a predetermined level, and an ice making substrate 18 having an ice making protrusion 17 immersed in the ice making water. When the water tray 16 is switched to the deicing operation, the water tray 16 tilts at a predetermined angle to discharge the ice making water in the water tray 16 to the outside through the drainage receiver 19 and the drainage pipe 20, and the ice blocks 21 are stored in the ice storage. It can be discharged to the ice storage chamber 8 3 defined inside 14.

(Regarding External Structure of Case) As shown in FIG. 10, the case 10 includes a main frame 22 surrounding each of the above-mentioned members, and a front panel 23 provided in front of the frame 22. It has a slim shape with an extremely short width. The front panel 23 is made of synthetic resin in a shape shown in the figure, and an opening 23a corresponding to the discharge port 14a of the ice block 21 formed in the ice storage 14 is directed downward at a substantially middle position in the height direction. Has been established (see Figure 1). Below the opening 23a, a container-shaped mounting table 24 is detachably mounted, and when the ice block 21 is taken out, a receiver such as a cup is mounted on the mounting table 24. A large number of slits 24a are formed on the upper surface of the mounting table 24 so as to prevent water droplets falling from the discharge port 14a from collecting and contaminating the surroundings. The front panel 23 extending above the opening 23a, the power lamp L and ice block release first push button 25 of the switch SW ₁ for is provided, ON operating the switch SW ₁ Press pusher button 25 During the operation, the ice lump releasing device 13 is operated to release the ice lump 21 stored in the ice storage chamber 83 through the outlet 14a and the opening 23a.

An opening (not shown) communicating with the lower machine room 12 is opened on the bottom surface of the housing 10, and the opening is covered by a filter member 26 detachably mounted on the housing 10. It is supposed to be done. The filter member 26 functions to collect dust in the outside air introduced into the machine chamber 12 for air cooling of the condenser 11 and prevent the cooling ability from being lowered due to clogging of the condenser 11. The filter member 26 is configured so that it can be easily attached and detached from the front side of the casing 10.

(Regarding Ice Storage) As shown in FIG. 2, the ice storage 14 is formed in a box shape that opens upward and forward, and the left and right side walls 77, 77 have upper end portions thereof spaced apart by a predetermined distance in the longitudinal direction. As a result, substantially V-shaped notches 77a, 77a are formed. A screw hole 77b is formed on one slope of the notch 77a at a right angle to the slope, and the bracket 32 installed between the notches 77a, 77a facing left and right is fixed via a screw 78. It is supposed to do. The ice making substrate 18 is suspended and supported by the bracket 32. By mounting the bracket 32 between the cutouts 77a, 77a, the bracket 32 is prevented from protruding upward from the upper ends of the side walls 77, 77 as shown in FIG. Further, an opening 79 formed in the front surface of the ice storage 14 is configured such that a cover body 27, which will be described later, is detachably arranged and is closed.

The rear wall 80 of the ice storage 14 has a drain receiving part 19 extending rearward at the upper part thereof, and a drain pipe connected to the outside of the ice storing 14 at the lower end of the drain receiving part 19. 20 are connected for communication (see FIG. 1). That is, the drainage receiver 19 collects the ice-making water discharged from the water tray 16 when the water tray 16 disposed in the ice storage compartment 14 is tilted during the deicing operation, and then the drainage pipe 20 is used to collect the ice-making water. It functions to be discharged to the outside of the aircraft via Note that the continuous edge portion of the drainage receiving portion 19 and the vertical rear surface wall 80 functions as a stopper for holding the water tray 16 in an inclined posture, as shown in FIG. Further, on the rear surface of the drainage receiving portion 19, there is formed a through hole 19a into which an ice making water supply pipe 74 described later is inserted.

As shown in FIG. 3, the bottom of the ice storage 14 has a bottom surface 81 that inclines downward from the lower end of the rear surface wall 80 toward the front side, and a bottom surface 81 connected to the bottom surface 81 toward the front side. And a storage section 82 that is inclined upwards. The bottom 81, the storage section 82, and the both side walls 77, 77 define an ice storage chamber 83. A screw 63 for carrying out the ice block of the ice block discharging device 13 is stored in the storage part 82, and a free end of a shaft of the screw 63 is rotatably fitted into a recess 64 formed at a corresponding position. It has become. A discharge port 14a that opens downward is formed near the front end of the storage part 82, and the ice block 21 conveyed by the rotation of the screw 63 is discharged to the outside through the discharge port 14a. Has been done. The storage portion 82 is formed in a semi-circular shape that allows the ice block 21 to be smoothly carried out by the rotation of the screw 63. Further, as shown in FIG. 3, the inclination angle of the storage section 82 is set to the same angle as the slope on the front side of the cut section 77a and the bottom surface of the drainage receiving section 19, and the ice storage 14 is made of synthetic resin. It can be molded more integrally.

(Cover Body) As shown in FIG. 1, the cover body 27 is detachably arranged in the front opening 79 of the ice storage 14, and the water tray in the ice making unit 15 is provided on the front side of the cover body 27. A tilting actuator motor AM of 16, a rocking motor RM of a rocking plate 28 (described later), and a discharging motor GM of the ice block discharging device 13 are collectively arranged. The motors AM, RM, GM and the members attached to the motors arranged on the cover body 27 can be easily maintained by removing the front panel 23. Further, when assembling the automatic ice maker, the cover body 27 can be attached to the ice storage 14 with the motors AM, RM, GM preliminarily arranged on the cover body 27, so that the time required for assembly can be shortened. There is an advantage that can be achieved.

(Regarding Ice Making Unit) FIG. 5 is a detailed vertical cross-sectional view of the ice making unit 15. The water tray 16 has the shape shown in FIG. 4 and has an ice making chamber 29 defined therein. Ice-making water can be stored at a predetermined level inside. That is, the ice making chamber 29 is defined by the rectangular bottom surface 16a of the water tray 16 and the wall surfaces 16b, 16c, 16d, 16e that stand upright on all four sides, and is located outside the upright wall 16e located on the right side in FIG. Is formed integrally with a plurality of shaft support portions 30 aligned along the longitudinal direction. As shown in FIG. 7, the shaft support portion 30 is rotatably inserted into through holes 32a and 32a formed in brackets 32 and 32 provided on the upper end of the ice storage 14, so that the water tray 16 is supported by the shaft support portion 30. It is configured to be rotatable in the lateral direction (widthwise direction of the ice making machine) about the support portion 30. Further, an ice making water supply pipe 49 is detachably arranged at an appropriate position of the ice making substrate 18, and a supply pipe 74 communicating with the ice making water supply source via a water supply valve WV to the ice making water supply source (not shown). Are connected. Then, by opening the water supply valve WV, a predetermined amount of ice making water is supplied to the ice making chamber 29 via the supply pipe 74 and the water supply pipe 49. The ice-making unit 15 can be easily removed from the bracket 32 by removing the cover body 27 from the ice storage 14, which has an advantage of easy assembly and maintenance.

Further, a square hole 30a is formed in the shaft support portion 30 located on the front surface side, and a square shaft 33a projecting from a shaft end of a turning support shaft 33, which will be described later, is fitted therein. The swivel support shaft 33 is rotatably supported by the cover body 27, and the water tray 16 supports the shaft support portion 30 as the actuator motor AM disposed on the cover body 27 rotates. As the center, it is constructed so that it can tilt downward and return upward. Since the water tray 16 is tilted in the width direction of the ice making machine, the lateral width of the ice making machine can be shortened as described above.

(Regarding Tilt Mechanism of Water Dish) At the position corresponding to the shaft support portion 30 of the water tray 16 in the cover body 27, a cylindrical bearing portion 34 projecting toward the front side is provided in a protruding manner. The swivel support shaft 33 is rotatably inserted into a through hole formed in the shaft support 33, and an angular shaft 33a protruding from the shaft end is fitted into the angular hole 30a of the shaft support portion 30. A lever piece 33b extending in the radial direction is integrally formed at the front end of the pivot shaft 33, and an engaging projection 33c is provided on the front side of the lever piece 33b. As shown in FIGS. 4 and 5, in the actuator motor AM provided on the cover body 27 via the bracket 35, a required diameter, which is partially cut in the circumferential direction, is formed on the rotary shaft extending to the front surface side of the bracket 35 in the actuator motor AM. A cam plate 36 made of a circular plate is arranged so as to rotate integrally. One end of a connecting rod 37 is eccentrically supported on the front surface of the cam plate 36, and a lever piece 33b formed on the swivel support shaft 33 is inserted into a long hole 37a formed in the other end of the connecting rod 37. The engaging protrusion 33c is slidably loosely fitted. Therefore, by rotating the actuator motor AM in a predetermined direction (counterclockwise in the embodiment), the swivel support shaft 33 reciprocally rotates at a required angle via the cam plate 36 and the connecting rod 37. 16 is tilted and tilted back.

At the front end portion of the engaging projection 33c, an elliptical restriction portion 33d that can be inserted into the elongated hole 37a of the connecting rod 37 is provided so as to extend in the radial direction with respect to the projection 33c. The connecting rod 37 is configured so as not to be easily disengaged from the engaging protrusion 33c in a state where the engaging protrusion 33c is inserted into the elongated hole 37a. An engaging piece 33e with which one end of a torsion spring 39 (all of which will be described later) engages a mounting jig 38 in which the swinging motor RM is arranged in a predetermined direction is engaged with the rear surface of the lever piece 33b. It is projected. The engaging piece 33e functions to switch between a state in which the biasing force of the torsion spring 39 acts on the mounting jig 38 and a state in which the biasing force does not act on the mounting jig 38 as the water tray 16 tilts and returns to tilt.

(Drainage Structure of Water Tray) As shown in FIGS. 4 and 5, the water tray 16 has a water discharge portion for discharging the ice making water in the ice making chamber 29 to the outside when the water tray 16 is tilted. Has been formed. That is, in the vicinity of the tilting lower end side of the upright wall 16c located on the rear side of the water tray 16, an auxiliary chamber 46 that is recessed toward the rear side is defined, and the auxiliary chamber 46 is provided outside (rear side) of the auxiliary chamber 46. A drainage pipe 47 of length is connected in communication. Below the drainage pipe 47, the drainage receiving portion 19 formed in the ice storage 14 faces. The auxiliary chamber 46 and the ice making chamber 29 are defined by a dam plate 48 which is lower than the upright wall 16c. Therefore, the ice making water supplied to the water tray 16 overflows from the upper end surface of the dam plate 48 and can be discharged to the drain receiving portion 19 via the drain pipe 47. In other words, the dam plate 48 holds the ice making water stored in the ice making chamber 29 at a predetermined level.

When the water tray 16 is tilted downwardly by switching to the deicing operation, the drain pipe 47 is connected to the edge of the drainage receiving portion 19 and the rear wall 80 as shown in FIG. It abuts, holds the water tray 16 in an inclined state, and discharges ice-making water to the drainage receiving portion 19 via the drainage pipe 47. At the position where the water tray 16 stops tilting, a part of the ice making water remains as it is due to the dam plate 48, and this residual water is mixed with the water supplied from the ice making water supply pipe 49 for the next ice making operation. As a whole, it can accelerate the temperature decrease of ice making water.

An ice making substrate 18 is horizontally suspended and supported above the inside of the ice storage via the brackets 32, 32, and a refrigeration system housed in the machine room 12 is provided on an upper surface of the ice making substrate 18. The evaporation pipes 31 derived from are arranged in a meandering manner. Further, a large number of ice-making projections 17 are provided on the lower surface of the ice-making base plate 18 so as to hang down at required intervals. During the ice-making operation, the ice-making projections 17 are immersed in the ice-making water stored in the water tray 16. It is like this. Then, by operating the refrigeration system, heat is exchanged with the refrigerant in the evaporation pipe 31, and the ice making protrusions 17 are cooled and held at 0 ° C. or less, so that ice blocks 21 are gradually formed around the ice making protrusions 17. become. It should be noted that the ice making substrate 18 is provided with a plurality of through holes 18a so as to improve heat exchange efficiency and achieve weight reduction.

(Regarding the Cam Control Mechanism) As shown in FIG. 6, the first cam portion 50 and the second cam portion 51 are provided on the back surface of the cam plate 36 disposed in the actuator motor AM, which faces the bracket 35. Are formed to be displaced in the radial direction. Further, the bracket 35 is provided with a second switch SW ₂ and a fourth switch SW ₄ corresponding to the first cam portion 50 and the second cam portion 51, respectively, and at a required timing as the actuator motor AM rotates. A cam operation is applied to control tilting stop and return stop of the water tray 16 by the motor AM, opening of a hot gas valve, and opening and closing of a water supply valve WV for replenishing ice making water. That is, the first cam portion 50 and the second cam portion 51 are formed by arcuate projections of a required radius that project in the axial direction. The lever piece 52 extending from the second switch SW ₂ contacts the first cam portion 50 and is separated from the first cam portion 50 at a required timing. When the lever piece 52 of the second switch SW ₂ comes into contact with the cam portion 50, the switch is turned on. The second switch SW ₂ controls tilting stop and return stop of the water tray 16 by the actuator motor AM, and also controls the opening of the hot gas valve.

A lever piece 53 extending from the fourth switch SW ₄ abuts on the second cam portion 51 and separates at a required timing. When the lever piece 53 of the fourth switch SW ₄ comes into contact with the cam portion 51, the switch is turned on and the opening of the water supply valve WV is controlled.

(Regarding Oscillating Plate and Oscillating Mechanism) Inside the ice making chamber 29 of the water tray 16, an upright wall 16d which is a tilted end side (left side) of the water tray 16 in a rectangular bottom plate 54a is formed. Oscillating plates 54 each having vertical rising portions 54b, 54c, 54d are formed on the three sides excluding the side opposite to the oscillating plate 54 so that they can be oscillated vertically by the rotation of the oscillating motor RM. It has become. The bottom plate 54a and the right rising portion 54b of the swing plate 54 are provided with a large number of circular or quadrangular through holes 55 at required intervals. The peripheral dimension of the swing plate 54 is set to be slightly smaller than the internal dimension of the bottom surface 16a of the ice making chamber 29, and the projections 56, 56 formed on both sides in the upper longitudinal direction of the rising portion 54b are attached to the water tray 16. It is rotatably pivotally supported via pins 57, 57 (see FIG. 4). Then, with the rocking plate 54 pivotally supported on the water tray 16, the rocking plate 54 is placed in close contact with the bottom surface of the ice making chamber 29 as shown in FIG. The through hole 55 is provided so as to face between the adjacent ice making projections 17, 17.

As shown in FIG. 5, an inverted L-shaped engaging piece 58 is integrally formed with a rising portion 54 c located on the front side of the rocking plate 54, and an upper horizontal portion 58 a thereof forms an upright wall 16 b of the ice making chamber 29. It extends beyond. Further, an elongated hole 27a extending in the vertical direction is formed in the cover body 27 at a position corresponding to the upper horizontal portion 58a, and a swing member 59 rotated by the swing motor RM is formed in the elongated hole 27a. It is slidably inserted. An oscillating protrusion 59a is eccentrically provided at a position of the oscillating member 59 facing the back side of the cover body 27, and this can engage with and disengage from the upper horizontal portion 58a of the oscillating plate 54 from below. There is. Therefore, when the rocking member 59 is rotated counterclockwise, the rocking protrusion 59a rotates while being engaged with the upper horizontal portion 58a, and the rocking plate 54 is lifted from the bottom surface of the ice making chamber 29 by a required distance. At the same time, when the rocking protrusion 59a is disengaged from the upper horizontal portion 58a, the rocking plate 54 falls to the bottom surface of the ice making chamber 29 under its own weight. That is, if the rocking motor RM is rotated during the ice making operation, the rocking plate 54 repeats the vertical rocking in the ice making chamber 29 with the pins 57, 57 as the center, thereby making the ice making water. It can be moved at all times to prevent the production of cloudy ice. Since the rocking plate 54 has a through hole 55, the ice making water flows vertically and horizontally through the through hole 55, so that more vigorous movement can be obtained.

Further, the rocking plate 54 tilts integrally with the tilting of the water tray 16 during the deicing operation, but at the right rising portion 54 b of the rocking plate 54 above the ice making substrate 18. An upright piece 60 is formed that extends. By engaging the upright piece 60 with the ice making substrate 18 while the rocking plate 54 is tilting together with the water tray 16, the rocking plate 54 is separated from the water tray 16 and its tilting posture is kept constant. Held in.

(Mounting Structure of Swing Motor RM) As shown in FIGS. 4 and 5, one end of a flat plate-shaped mounting jig 38 is rotatably attached to the bearing portion 34 protruding from the cover body 27. The swinging motor RM is disposed on the front side near the end of the mounting jig 38 which is supported and is separated from the pivotal support. The motor RM is connected to the cam portion 59b of the swinging member 59 protruding from the through hole 27a to the front side. Further, a projecting piece 38a is formed on the front surface side of the mounting jig 38 facing between the pivotal support part and the swinging motor RM, and one end of one of the torsion springs 39 mounted on the bearing part 34 is formed at the lower end of the projecting piece 38a. The end 39a is engaged. An engaging piece 33e formed on the lever piece 33b faces the protruding piece 38a, and the other end 39b of the torsion spring 39 is engaged with the upper end of the engaging piece 33e. The upper end of the engaging piece 33e faces above the upper end of the protruding piece 38a of the mounting jig 38 when the water tray 16 is supported in a horizontal posture. Therefore, at this time, the mounting jig 38 is always urged to rotate in the time direction with the bearing portion 34 as a fulcrum under the elastic force of the torsion spring 39. Then, when a required external force is applied to the swing motor RM, the attachment jig 38 can rotate about the bearing portion 34 by a required angle.

That is, in the torsion spring 39, the rocking protrusion 59 a of the rocking member 59 is engaged with the engaging piece 58 of the rocking plate 54 while the water tray 16 maintains the horizontal posture during the ice making operation. It functions to hold it in a possible working position. When the water tray 16 is tilted by switching from the ice making operation to the deicing operation, the upper end of the engaging piece 33e of the lever piece 33b moves below the upper end of the projecting piece 38a of the mounting jig 38. At times, the end portion 39b of the torsion spring 39 reaches the upper end of the protruding piece 38a. Therefore, when the water tray 16 is tilted, the torsion spring 39 does not exert an urging force on the mounting jig 38.

A long hole 38b extending in the up-down direction is formed in an end portion of the attachment jig 38 which is separated from the pivotal support portion, and a regulation pin corresponding to the cover body 27 is provided in the long hole 38b. 61 is slidably inserted. The regulation pin 61 functions to regulate the range of rotation of the mounting jig 38, and the lower end of the elongated hole 38b is always in contact with the regulation pin 61 under the elastic force of the torsion spring 39, so that the swinging member is movable. It is designed so that 59 is exposed to the operating position (see FIG. 6).

(Switches SW ₅ and Th ₁ for detecting ice making and deicing completion) The cover body 27 is provided with a fifth switch SW ₅ for detecting ice making completion such as a micro switch via a bracket 70. The lever piece 62 is provided so as to face the descending locus of the cam portion 59b of the swing member 59, and comes into contact with the cam portion 59b as the mounting jig 38 (swing motor RM) rotates. The switch can be switched. That is, when the ice making operation progresses and the ice blocks 21 grow around the ice making protrusions 17, the rocking plate 54 comes into contact with the ice blocks 21 when it moves upward, and the engaging pieces 58 and the rocking protrusions 59a move. Through this, a downward reaction force is applied to the swing motor RM. Therefore, the mounting jig 38, on which the swinging motor RM is disposed, rotates counterclockwise around the bearing 34 as a fulcrum, and the cam 59b moves the lever piece of the fifth switch SW _{5 in} the course of the rotation. By pressing 62, the completion of ice making in the ice making unit 15 is detected.

If the swinging motor RM is stopped at the same time when the lever piece 62 of the fifth switch SW ₅ is pressed, the swinging projection 59a that abuts on the engaging piece 58 of the swinging plate 54 swings. This hinders the tilting of the moving plate 54. In Accordingly embodiment, the cam portion 59b of the swinging member 59, rocking motor RM is formed a notch 59c which does not press the lever piece 62 of the fifth switch SW ₅ in a state of being rotated by the cutout portion 59c The swinging protrusion 59a is configured to be controlled so as to be separated from the tilt locus of the engaging piece 58. The notch 59c is located at a position corresponding to the lever piece 62 of the fifth switch SW ₅ when the swinging projection 59a faces a position separated from the upper horizontal portion 58a of the engaging piece 58. The cam portion 59b is formed in a related relationship. That is, even after the lever piece 62 of the fifth switch SW ₅ is pressed by the rotation of the swinging motor RM, the motor RM is rotated and the cutout portion 59c corresponds to the lever piece 62 of the switch SW ₅ . The rocking motor R M is set to stop when the lever piece 62 is released from the pressing position. As a result, the swinging projection 59a is separated from the tilting locus of the engaging piece 58 on the swinging plate 54, and the tilting of the swinging plate 54 is not obstructed.

As shown in FIG. 5, a thermoswitch Th ₁ for detecting the completion of deicing is arranged on the upper surface of the ice making substrate 18 in the ice making unit 15. This thermo switch Th _{1 functions} to detect a sudden temperature rise when the ice block 21 drops from the ice making projections 17 during deicing operation, close the hot gas valve, and rotate the actuator motor AM. To do.

(Ice Lump Discharge Device and Ice Storage Completion Detection Switch) An ice lump discharge motor GM is provided in the lower front portion of the cover body 27, and an ice lump carry-out screw 63 rotatably driven by the motor GM is provided. It is arranged so as to face the inside of the storage portion 82 of the ice storage 14. As described above, the shaft end portion of the screw 63 is rotatably fitted into the recessed portion 64 provided at the corresponding position of the accommodating portion 82 so as to rotate at the fixed position. The discharging motor GM rotates only while the push button 25 provided on the front panel 23 is pressed to turn on the first switch SW ₁ , and the screw 63 causes the ice block 21 stored in the ice storage box 14 to move. It is designed to be conveyed to the discharge port 14a.

As shown in FIG. 1, on the back surface of the cover body 27, a regulation plate 65 that corresponds to the position of the screw 63 and faces the inside of the ice storage chamber from the position where the discharge port 14a is formed is rotatably suspended. It is set up. The regulation plate 65 is pressed by the ice lump 21 conveyed by the screw 63 to open the discharge port 14a to allow the ice lump 21 to be discharged, and when the ice lump discharge device 13 is stopped, it is in the initial position. It returns and closes the discharge port 14a, and functions to prevent outside air from entering the ice storage chamber 83 through the discharge port 14a. Further, a separating plate 68 is disposed in the cover body 27 in the vicinity of the regulating plate 65, and the separating plate 68 prevents the ice blocks 21 stored in the ice storage chamber 83 from being discharged from the discharge port 14a. It functions to return a part of the ice block 21 conveyed by the screw 63 to the ice storage chamber 83 to prevent the discharge port 14a from being clogged. A discharge pipe 69 is communicatively connected to a portion of the ice storage 14 near the position where the recess 64 is formed, and the melted water from the ice block 21 is discharged to the outside of the storage.

A detection plate 66 is rotatably supported on the lower surface of the water tray 16, and as shown in FIG. 8, the detection plate 66 always has its open end side with respect to the bottom surface of the water tray 16. It is held in a state of being separated downward. Further, a _third switch SW ₃ for detecting the completion of ice storage is arranged on the front surface of the water tray 16, and a lever piece 67 of this switch SW ₃ has a protrusion 66a formed at the front end of the detection plate 66. Therefore, it is always pressed. When the water plate 16 is tilted, the detection plate 66 comes into contact with the ice block 21 and rotates clockwise with respect to the water plate 16 that continues to rotate (the open end is close to the bottom surface of the water plate 16). to the time), the projecting piece 66a turns oN operation moving the switch SW ₃ spaced from the lever piece 67, is set to detect the ice storage completion. Incidentally, the projection piece 66a of the detection plate 66, by setting so as to abut against the third lever piece 67 of the switch SW ₃ at the time of non-detection of the ice blocks 21, the water tray 16該検intellectual plate 66 by any cause like When falling off, the automatic ice maker is stopped to prevent the ice block 21 from being manufactured in a state where the completion of ice storage cannot be detected. In addition, the open end of the detection plate 66 is formed in a comb shape to reduce the load applied when the detection plate 66 contacts the ice block 21.

[0037]

[Operation of the embodiment]

 Next, the operation of the ice storage structure of the ice making machine according to the embodiment will be described. When assembling the automatic ice maker, the ice storage 14 is arranged and fixed above the lower machine chamber 12 through appropriate means. As shown in FIG. 7, the brackets 32, 32 on which the ice making substrate 18 is arranged are positioned at the corresponding notches 77a, 77a, respectively, and the respective ends are fixed via the screws 78. Further, by inserting the corresponding shaft support portion 30 of the water tray 16 into the through holes 32a, 32a formed in the brackets 32, 32, the ice making substrate 18 is horizontally supported above the inside of the ice storage 14, and The water tray 16 is tiltably supported. At this time, the drainage pipe 47 formed in the water tray 16 faces the inside of the drainage receiving portion 19 of the ice storage 14, as shown in FIG.

In addition, the supply pipe 74 inserted into the through hole 19 a formed in the drainage receiving portion 19 is connected to the water supply pipe 47 provided on the ice making substrate 18, and the drainage pipe 20 is connected to the drainage receiving portion 19. To continue. Further, the cover body 27 in which the actuator motor AM, the swinging motor RM, and the discharging motor GM are arranged is attached to the opening 79 of the ice storage 14. At this time, as shown in FIG. 4, the angular shaft 33a of the swivel support shaft 33 projecting to the back surface of the cover body 27 is fitted into the angular hole 30a in the shaft support portion 30 of the water tray 16, thereby It is possible to tilt and return the water tray 16 by the actuator motor AM. Further, the shaft end of the screw 63 of the ice block discharging device 13 is fitted in the recess 64 of the accommodating portion 82 and attached. When the cover body 27 is arranged in the ice storage 14, the swinging projection 59 of the swinging member 59 is provided on the upper horizontal portion 58a of the engaging piece 58 of the swinging plate 54 held in the horizontal posture. It faces downwards.

As described above, after the ice-making unit 15 and the cover body 27 having the motors AM, RM, and GM are arranged in the ice storage unit 14, the main frame 22 and the front panel 23 that form the casing 10 are arranged. By installing and, the assembly of the ice machine is completed. Then, the ice blocks 21 produced by the ice making unit 15 by the ice making operation are discharged to the ice storage chamber 83 as the water tray 16 tilts obliquely downward and the ice making projections 17 are heated by the deicing operation. To be done. As shown in FIG. 1, the bottom surface 81 of the ice storage 14 is inclined downward toward the storage portion 82, so that the ice blocks 21 discharged into the ice storage chamber 83 are efficiently stored in the storage portion 82 facing the screw 63. And can be reliably carried out by the screw 63.

When the water tray 16 is tilted, the drainage pipe 47 formed on the water tray 16 is connected to the rear edge 80 of the rear wall 80 of the ice storage 14 and the drainage receiving portion 19 as shown in FIG. The water tray 16 abuts and the tilted posture is maintained. Then, the ice making water remaining in the water tray 16 without being frozen around the ice making protrusions 17 by the ice making operation is discharged to the drain receiving portion 19 via the drain pipe 47. The ice-making water collected by the drainage receiver 19 is discharged to the outside of the machine through the drainage pipe 20.

[0041]

[Effect of device]

 As described above, according to the ice storage structure of the ice making machine according to the present invention, the drainage receiving portion for discharging the ice making drainage to the outside of the machine is integrally formed in the ice storage, and the water receiving tray is provided in the receiving portion. Since it has an additional function of holding it in a tilted position, it is possible to reduce the number of parts and reduce the manufacturing cost. Further, since the mounting portion of the ice making unit is integrally formed in the ice storage, it is possible to reduce the processing man-hours and efficiently perform the assembling work of each component. Moreover, since the ice storage can be integrally molded of synthetic resin, it is possible to further reduce the manufacturing cost. Further, by disposing a screw for carrying out the ice blocks in the ice storage, it is possible to take out the ice blocks without touching the ice blocks with the fingers of the operator, and there is an advantage that the ice blocks can always be kept hygienic.

[Brief description of drawings]

FIG. 1 is a schematic vertical cross-sectional view of an ice making machine adopting an ice storage structure according to an embodiment.

FIG. 2 is a schematic perspective view of an ice storage according to an embodiment.

FIG. 3 is a vertical sectional view of the ice storage.

FIG. 4 is a schematic perspective view showing a partially disassembled state of the ice making unit arranged in the ice storage according to the embodiment.

5 is a cross-sectional view of an essential part of the ice making unit shown in FIG.

FIG. 6 is a front view of relevant parts showing a state in which a tilting mechanism of a water tray and a swinging mechanism of a swing plate are partially cut away.

FIG. 7 is a schematic perspective view showing an ice making unit arranged in an ice storage.

FIG. 8 is a partially cutaway front view of the ice making unit.

FIG. 9 is a partially cutaway side view showing a state where the water tray is tilted in the ice making unit.

FIG. 10 is an external perspective view of an ice making machine.

[Explanation of symbols]

11 ... Condenser, 14 ... Ice storage, 15 ... Ice making unit, 1
6 ... Water tray 17 ... Ice making protrusion, 18 ... Ice making substrate, 19 ... Drainage receiving part, 2
1 ... Ice block 27 ... Cover body, 29 ... Ice making chamber, 31 ... Evaporating tube, 63 ...
Screw 77 ... Side wall, 77a ... Notch, 79 ... Opening, 80 ... Rear wall 81 ... Bottom, 82 ... Storage, 83 ... Ice storage room, CM ... Compressor

Claims (4)

[Scope of utility model registration request] 1. An evaporation pipe (31) connected to a refrigeration system including a compressor (CM), a condenser (11), and the like, and the evaporation pipe (31) is arranged on the upper surface and a large number of pieces are formed on the lower surface. The ice making substrate (18) in which the ice making unit (17) is suspended from the ice making unit (17) at a predetermined interval, and the ice making unit in the ice making chamber (29) defined inside holds the ice making unit in the above-mentioned ice making unit.
Ice making unit (15) consisting of water tray (16) in which (17) is immersed
When the ice making water is frozen around the ice making unit (17) to form a required ice block (21), the ice tray configured to tilt the water tray (16) diagonally downward, A pair of side walls (77,77) spaced apart from each other and the side walls (77,7).
7) An ice storage (80) formed at the rear end, and a bottom (81) and a storage (82) formed at the bottom of the side walls (77, 77) open forward and upward ( 14) to form an ice storage chamber (83) for storing the ice blocks (21) produced by the ice making unit (15) facing the inside above the inside of the ice storage (14), When the water tray (16) tilts on the rear wall (80), the water tray (16)
A drain receiving part (19) for collecting the ice making water discharged from (16) is formed, and the water tray (16) is provided at a connecting edge portion of the rear wall (80) and the drain receiving part (19). The ice storage structure of the ice making machine, characterized in that it is configured so as to contact with and hold it in an inclined posture. 2. The ice storage structure of the ice making machine according to claim 1, wherein the both side walls (77, 77) are formed with mounting portions (77a, 77a) of the ice making unit (15). 3. The ice storage (14) is composed by setting the bottoms of the mounting portion (77a), the drainage receiving portion (19) and the storage portion (82) so as to be inclined at the same angle toward the front side. The ice storage structure of the ice making machine according to claim 2, wherein the ice storage structure can be integrally molded with resin. 4. A screw (63) for carrying out an ice block, which is arranged in a cover body (27) for closing the front opening (79) of the ice storage (14), is rotatably provided in the storage section (82). Claim 1 to be stored,
The ice storage structure of the ice machine described in 2 or 3.