JPH09569U - Automatic ice machine - Google Patents

Abstract

(57) [Abstract] [PROBLEMS] To effectively prevent clouding of ice blocks. SOLUTION: The first ice making unit is provided with a swing plate 36 inside a water tray 26 that stores ice making water at a predetermined level so as to move the ice making water in the water tray by being swung by a swing mechanism 44. The third switch S is attached to the tilting mechanism 42 of the first ice making unit.
W ₃ is provided, and the third switch SW ₃ is turned on when the water tray 26 is tilted by the actuator motor AMR and reaches the bottom dead center, and is turned off when the water tray 26 is returned to the horizontal posture. Operate. When the third switch SW ₃ detects that the water tray 26 has returned to the horizontal posture, the swing mechanism 44
As a result, the rocking plate 36 is rocked.

Description

[Detailed description of the device]

[0001]

[Technical field to which the invention belongs]

 The present invention relates to an automatic ice maker, and more specifically, it immerses a large number of ice-making protrusions protruding from the lower surface of an ice-making substrate in ice-making water stored in a water tray, and the ice-making protrusions are surrounded by the ice-making protrusions. It relates to an automatic ice-making machine designed to form an inverted dome-shaped ice block.

[0002]

[Prior art]

 As an automatic ice maker that continuously manufactures a large number of ice blocks of the required shape, the ice making substrate is equipped with an evaporation pipe that stores ice making water at the required level in a water tray held horizontally and circulates and supplies the refrigerant. There is known a simple ice-making machine in which an ice-making protrusion protruding from the lower surface of the ice-making machine is immersed in the ice-making water to form an ice block around the ice-making protrusion that is kept cooled.

As described above, it is natural for an automatic ice-making machine that can form an ice block around the projections by simply immersing a large number of the ice-making projections cooled and held in the ice-making water in a water tray. During the ice making operation, the ice making water does not circulate at all and is kept in a so-called "stationary state". For this reason, the ice blocks gradually formed around the ice making protrusions become cloudy and opaque due to the influence of the air dissolved in the ice making water. The white turbidity of the obtained ice blocks is generally not a problem for the original use such as cooling of ice. However, when this cloudy ice is used for eating and drinking in coffee shops, restaurants, etc., it is clearly inferior in appearance to transparent and clear ice, and the price of goods as a whole is reduced.

Therefore, an oscillating plate is swingably disposed inside the water tray, and the oscillating plate is oscillated by an oscillating mechanism during the ice making operation to move the ice making water in the water tray. By adopting such a configuration, a configuration is adopted in which the cloud of ice formed around the ice making protrusion is prevented.

[0005]

[Problems to be solved by the device]

 In the automatic ice maker, when an ice block is formed on the ice making protrusion and the ice making operation is switched to the deicing operation, the water tray tilts to the bottom dead center to open the lower side of the ice making substrate, and the ice making operation completes the entire operation. When it is detected that the ice blocks have been deiced from the ice-making protrusions and the completion of the deicing operation is detected, the water tray returns to the horizontal position from the bottom dead center and the next ice-making operation is started. In this case, it is necessary to move the ice making water from the start of the ice making operation in order to effectively prevent clouding of the ice blocks formed around the ice making protrusions during the ice making operation. There was no suggestion of specific technology for doing so.

[0006]

[Purpose of the invention]

 The present invention has been made in view of the above-mentioned drawbacks inherent in the prior art, and was proposed to suitably solve the drawbacks, and an object thereof is to provide an automatic ice-making machine that can effectively prevent clouding of ice blocks. And

[0007]

[Means for Solving the Problems]

 In order to overcome the above-mentioned problems and achieve the intended purpose, the automatic ice making machine according to the present invention is provided with an evaporation pipe leading from a refrigeration system including a compressor, a condenser, etc. on the upper surface thereof. An ice-making substrate with a large number of ice-making parts hanging down from the bottom surface at a predetermined interval, and an ice-making machine body that is tiltably pivoted and always maintains a horizontal posture. The water tray soaked in the water tray, a swing plate housed in the water tray so as to swing freely, and a swing plate that swings by the swing mechanism to move the ice making water in the water dish; In an automatic ice making machine comprising an ice making mechanism that tilts from a horizontal position to a bottom dead center obliquely downward and returns to a horizontal posture from bottom dead center, the ice making mechanism tilts to bottom dead center. The water tray is provided with detection means for detecting that the water tray has returned to the horizontal posture, When the detecting means detects that the plate has returned to the horizontal posture, the rocking mechanism is operated to move the ice making water by the rocking plate.

[0008]

[Embodiment of the invention]

 Next, an automatic ice making machine according to the present invention will be described below with reference to the accompanying drawings, with reference to preferred embodiments.

FIG. 1 is a sectional view schematically showing the overall configuration of the automatic ice making machine according to the embodiment, and FIG. 2 is a front view of the automatic ice making machine. The inside of the casing 14 that constitutes the main body of the ice maker 12 shown in the figure is a lower machine room 18 in which a single refrigeration mechanism (refrigeration system) 17 including a compressor CM, a condenser 16 and the like is housed, and above the lower machine room 18. A box-shaped ice storage 22 that is located and surrounded by a heat insulating material and defines an ice storage chamber 20 inside, and a plurality of (two in the embodiment) ice making units (see FIG. 3) arranged inside the ice storage 22 ( The ice making mechanism) 24 and 25 are basically included. In the automatic ice making machine 12 of the embodiment, the heavy refrigerating mechanism 17 is arranged below the housing 14, so that the ice making machine itself has an advantage of being stable. Since the first ice-making unit 24 and the second ice-making unit 25 have the same configuration, only the configuration of the first ice-making unit 24 arranged on the left side in the front view will be described, and the same configuration of the second ice-making unit 25 will be described. The same reference numerals are given to the members. Regarding actuator motors and swing motors, which will be described later, those relating to the first ice making unit side are marked with “R”, and those relating to the second ice making unit side are marked with “L”. Shall be distinguished.

As shown in FIG. 3, the first ice making unit 24 is provided with a water tray 26 for storing ice making water at a predetermined level and an ice making protrusion (ice making portion) 28 immersed in the ice making water. An ice making substrate 30 provided with an evaporation pipe 33 derived from the freezing mechanism 17 is provided, and the water tray 26 tilts at a predetermined angle (tilts to a bottom dead center) when the deicing operation is switched to the water tray. The ice making water in 26 is discharged to the outside of the machine via the drainage receiving portion 31 and the drainage pipe 32, and at the same time, the ice blocks formed around the ice making protrusions 28 can be discharged to the ice storage chamber 20. That is, in the water tray 26, a drainage pipe 34 is disposed at a position facing above the drainage receiving portion 31 formed on the back side of the ice storage 22, and when the water tray 26 tilts to the bottom dead center. The ice making water in the water tray 26 is configured to be discharged from the drain pipe 34 to the drain receiving portion 31. In addition, a swing plate 36 is swingably arranged inside the water tray 26. The swing plate 36 is used to move the water when the water tray 26 tilts to the bottom dead center as shown in FIG. The plate 26 extends upward from the lower end of the tilting lower side and functions to guide the ice blocks falling from the ice making projections 28 to the ice storage chamber 20. As shown in FIGS. 2 and 4, since the water tray 26 is configured to rotate in its lateral direction, it is possible to reduce the area required for the water tray 26 to tilt. The machine size can be reduced, and the effective ice storage amount of the ice storage chamber 20 can be increased.

A supply pipe 50 disposed at an appropriate position of the ice making substrate 30 is connected to the discharge port of the first water supply valve WV ₁ disposed on the inner rear surface side of the casing 14, and the suction port is also connected to the suction port. A first water supply pipe 37, which is piped in the housing 14 and communicates with an external water supply system, is connected. Therefore, by controlling the opening / closing of the first water supply valve WV ₁ at an appropriate timing, a predetermined amount of ice making water is supplied to the water tray 26.

The rocking plate 36 is rocked up and down by the rotation of a rocking motor RMR, which will be described later, during the ice making operation, and imparts a motion to the ice making water stored in the water tray 26. It is configured to prevent the ice blocks formed on the ice making projections 28 from becoming cloudy. As shown in FIG. 3, the swing plate 36 is provided with a large number of through holes 36a having a circular shape or a quadrangular shape at required intervals. These through holes 36a are set so as to face between the adjacent ice-making protrusions 28 and 28, and the movement of the ice-making water at the position facing between the ice-making protrusions 28 and 28 when the swing plate 36 swings. Is made active and effectively prevents the ice blocks from becoming cloudy. Further, the rocking plate 36 switches the contact point of the sixth switch SW ₆ for detecting the completion of ice making, which will be described later, when the rocking plate 36 comes into contact with an ice block of a required size formed on the ice making protrusion 28 and its rocking is restricted. The unit 24 also has a function of detecting the completion of ice making.

A cover body 40 is removably arranged on the front side of the ice storage 22, and a first ice making unit is provided on the front side of the cover body 40 at a position corresponding to the first ice making unit 24 as shown in FIG. The tilting mechanism 42 of the water tray 26 in the unit 24 and the swinging mechanism 44 of the swinging plate 36 are collectively arranged. The tilting mechanism 42 includes an actuator motor AM R, the swinging mechanism 44 includes a swinging motor RMR, and both motors AMR and RMR are controlled based on the electric control circuit shown in FIG. Note that the tilting mechanism 42 and the swinging mechanism 44 are also arranged at positions corresponding to the second ice making unit 25. Further, an ice block discharging device 38 for discharging the ice blocks stored in the ice storage chamber 20 to the outside is provided in the middle of the position where the mechanisms corresponding to both units 24 and 25 are arranged. The ice lump discharging device 38 includes a screw 46 for carrying out an ice lump extending from the back surface of the cover body 40 into the ice storage chamber, and a motor GM arranged on the front surface of the cover body 40. By rotating the screw 46, the ice blocks stored in the ice storage chamber 20 are conveyed toward the front side. Further, an ice block discharge port 22a having a required opening size is opened on the bottom surface near the front end of the ice storage 22, and the ice block transported by the screw 46 is discharged to the outside through the ice block discharge port 22a. . A discharge pipe 47 is provided at the bottom of the ice storage 22, and the melted water from the ice blocks is discharged to the outside of the storage.

A front panel 48 is detachably attached to the front surface of the housing 14 so as to surround the mechanisms 42, 42, 44, 44 and the device 38 arranged on the cover body 40 of the ice storage 22. ing. Further, an opening 48a corresponding to the ice block discharge port 22a is formed in the front panel 48, and by pressing a push button 49 of the first discharge switch SW _{1 provided} on the panel 48, the ice block is released. The release device 38 operates to release the ice blocks in the ice storage to the outside through the ice block outlet 22a and the opening 48a. In the automatic ice maker 12 embodiment, as shown in the electrical control circuit of FIG. 6, the second switch SW ₂ for relationally select the first switch SW ₁ is arranged, selector Trevor of the switch SW ₂ By pressing the push button 49 with the switch 51 (disposed on the front panel 48) being switched, three types of supply of "ice block", "ice block + water", and "water" can be selected. ing. That is, the second water supply pipe 54 is branched and connected to the first water supply pipe 37, and the second water supply pipe 54 is connected to the suction port of the second water supply valve WV ₂ arranged in the cover body 40. . The discharge pipe 56 connected to the discharge port of the second water supply valve WV ₂ is configured to open at the ice block discharge port 22a. Therefore, by pressing the push button 49 of the first switch SW ₁ after switching the select lever 51 of the second switch SW ₂ arranged on the front panel 48 to one of the three types, only the ice block discharging device 38 operates. and if the "ice blocks" is supplied to a case where the ice mass emission device 38 and the second water supply valve WV ₂ open while actuated "ice cubes + water" is supplied, the second water supply valve WV only ₂ The case of opening and supplying “water” is selected. A receiving tray 53 is arranged below the opening 48a of the front panel 48 so that water or the like dripping from the openings 22a and 48a is received by the receiving tray 53 and then discharged out of the machine through the drain tray 55. It is configured. Further, the water flowing out from the drain pipe 32 and the drain pipe 47 is also collected in the drain tray 55 and discharged to the outside of the machine.

The tilting mechanism 42 of the first ice making unit 24 has a third switch SW as a detection means._ThreeAnd the fourth switch SW_FourAnd the third switch SW._ThreeIs ON when the water tray 26 reaches the bottom dead center (the position indicated by the chain double-dashed line in FIG. 4) by tilting the actuator motor AMR, and is OFF when the water tray 26 returns to the horizontal position. Is set to Also the fourth switch SW_FourIs the first water supply valve WV as shown in FIG.₁The water tray 26 is turned on at a timing required to return the water tray 26 from the bottom dead center to the horizontal posture, and the first water supply valve WV₁Is set to control the opening of the. The tilting mechanism 42 of the second ice making unit 25 is turned on when the water tray 26 is tilted by the actuator motor AML and reaches the bottom dead center, and is turned off when the water tray 26 is returned to the horizontal posture. Fifth switch SW as detecting means to operate_FiveAre arranged in a relational manner. And the third switch SW_ThreeAnd the fifth switch SW _Five When both are turned on, the hot gas valve HV is opened and the deicing operation is started. Further, at a position corresponding to the first ice making unit 24 on the cover body 40, a sixth switch SW for detecting the completion of ice making is provided.₆Is provided, and the switch SW₆When an ice block is formed on the ice-making protrusion 28, the contact is switched from the “a” side to the “b” side via the swing plate 36 to complete the ice-making in the first ice-making unit 24. It is configured to detect. The second ice making unit 25 side also has a similar function and has a seventh switch SW for detecting the completion of ice making.₇Is provided.

A detection plate 52 is rotatably supported on the lower surface of the water tray 26, and an eighth switch SW ₈ for detecting the completion of ice storage is arranged on the front surface of the water tray 26. ₈ is set to detect the completion of ice storage by turning on when the detection plate 52 comes into contact with an ice block already stored in the ice storage chamber 20 in the process of tilting the water tray 26 and the tilt is blocked. I am doing it. Further, a thermoswitch Th ₁ for detecting the completion of deicing is arranged on the upper surface of the ice making substrate 30, and this thermo switch Th ₁ is used when the ice making substrate 30 is lowered to a predetermined temperature by the ice making operation. Is set to the contact "b" side, and the contact is switched from the "b" side to the "a" side by detecting a rapid temperature rise when the ice block drops from the ice making protrusion 28 during the deicing operation. To be done. At this time, the hot gas valve HV is closed and the actuator motors AMR and AML are rotated. Since the detection plate 52, the eighth switch SW ₈ and the thermo switch Th ₁ may be arranged in either one of the first ice making unit 24 and the second ice making unit 25, in the embodiment, the first ice making unit is used. The case where the unit 24 is installed will be described. Further, the ice making machine 12 of the embodiment has a protection thermo-switch Th ₂ for water cutoff which is turned off to stop the operation of the ice making machine 12 when the ice making water is not supplied due to the water cutoff, and the outside air temperature becomes a predetermined value or less. In this case, an outside air thermostat Th ₃ which is turned on to stop the operation of the ice making machine 12 is provided.

FIG. 5 shows a schematic configuration of a refrigeration system in an automatic ice making machine. The vaporized refrigerant compressed by the compressor CM is condensed and liquefied by the condenser 16 through the discharge pipe, and the dryer 58. After being dehumidified by, the pressure is reduced by the capillary tube 60, flows into the evaporation pipe 33 of the first ice making unit 24 and the evaporation pipe 33 of the second ice making unit 25, and expands and evaporates all at once, and the respective ice making substrates Heat exchange is performed with 30, 30 to cool each substrate 30, 30 to below freezing. The vaporized refrigerant and the unevaporated liquefied refrigerant evaporated in the both evaporation pipes 33, 33 flow into the accumulator 62 in a gas-liquid mixed phase state, where they are separated from each other. Then, the vapor-phase refrigerant returns to the compressor CM via the suction pipe, and the liquid-phase refrigerant is stored in the accumulator 62. Further, a hot gas pipe 64 is branched from the discharge pipe of the compressor CM, and the hot gas pipe 64 is connected to the inlet sides of both the evaporation pipes 33, 33 via a hot gas valve HV. The hot gas valve HV is controlled to open only during deicing operation and to close during ice making operation. That is, the hot gas valve HV is opened during the deicing operation, and the high-temperature refrigerant discharged from the compressor CM is bypassed to both the evaporation pipes 33, 33 via the hot gas pipe 64, and the ice making base plates 30, 30 are made. Is heated to melt the iced surface of the ice blocks formed on the ice-making projections 28, 28, and each ice block is dropped by its own weight. Further, the high-temperature refrigerant flowing out from both the evaporation pipes 33, 33 flows into the accumulator 62, heats and evaporates the liquid-phase refrigerant accumulated in the accumulator 62, and as a gas-phase refrigerant, it is compressed from the suction pipe. Return to CM again. Note that the symbol FM in the drawing indicates a fan motor for the condenser 16.

FIG. 6 shows an electric control circuit of the automatic ice maker according to the embodiment. In the figure, a power switch SB is inserted between the power supply lines R and T. Also, between the line R and T, the power light L _1, the relay X ₁ and the first switch SW ₁ for ice cubes release connected in series, connected in series with normally open contacts X ₁ -a relay X ₁ The second switch SW ₂ for selection and the fifth switch SW ₅ for the actuator motor AML connected in series with the relay X ₃ are inserted in parallel. Note that the second switch S W ₂ for selection, the second water supply valve WV ₂ and the discharge motor GM is switchably connected state to connect only to the second feed water valve WV _2, only the discharge motor GM It can be switched to a connected state and a state in which both the second water supply valve WV ₂ and the discharge motor GM are connected. Between the normally closed contact X ₂ -b of the relay X ₂ connected to the line R and the line T, an in-operation lamp L ₂ indicating that the operation is in progress is inserted. Furthermore, the relay X ₂ to a connection point E between the fifth switch SW ₅ and the relay X ₃ are connected, between the relay X ₂ and the line T, the outside air thermo Th ₃ and ice storage completion detection 8 switches SW ₈ are inserted in parallel. Incidentally, the relay X _2, contact "b" side of the ninth switch S W ₉ for forced tilting to be described later is connected.

[0019] Between the normally closed contact X ₂ -b and line T of the relay X _2, normally closed contacts X ₃ -b ₁ relay X _3, in series to the normally closed contact X ₅ -b ₁ for the relay X ₅ actuator motor AML connected, normally closed contact X ₄ -b ₁ for the relay X _4, the actuator motor AMR are inserted in parallel connected in series to the normally closed contact X ₅ -b ₂ of the relay X _5. Incidentally, between the connection point E and the actuator motor AML, the normally open contact X ₅ -a ₁ of the relay X ₅ is interposed. The actuator motors third switch SW ₃ for AMR is connected to the normally closed contact X ₂ -b relay X ₂ is the A effectuator eta motor AMR through the normally open contact X ₅ -a ₂ of the relay X ₅ Connected. Between the third switch SW ₃ and the line T, a relay X ₄ and a first water supply valve WV ₁ connected in series with a fourth switch SW ₄ for supplying ice making water are inserted in parallel.

Further, between the thermal switch T h ₁ for deicing completion detecting the normally closed contact X ₂ -b relay X _2, of the relay X ₃ normally open contacts X ₃ -a and the relay X ₄ A normally open contact X ₄ -a is inserted in series, a fan motor FM for the condenser 16 is connected to the contact “a” side of the thermoswitch Th ₁ , and a hot gas supply to the contact “b” side. The hot gas valve HV is connected. Further, a protection thermoswitch Th ₂ for water cutoff and a relay X ₅ are connected in series to the contact “a” side of the seventh switch SW ₇ for detecting the completion of ice making on the side of the second ice making unit 25, and the contact “ b "side Ru is connected to the normally closed contact X ₂ -b relay X _2. The fan motor FM and the relay X ₃ are in parallel. Also the relays X _5, the contact "a" side of the ninth switch SW ₉ is connected for forced tilting of connecting to a power supply line T.

Between the contact “a” side of the sixth switch SW ₆ for detecting the completion of ice making on the side of the first ice making unit 24 and the line T, the normally open contact X ₅ −a ₃ of the relay X ₅ for swinging. motor R ML, with the normally closed contact X ₃ -b ₂ of relay X ₃ are interposed in series, the contacts "b" side is connected to the normally closed contact X ₂ -b a relay X _2. The seventh switch SW ₇ is connected to a connection point P between the normally open contact X ₅ -a _{3 of} the relay X ₅ and the swing motor RML. Between the normally closed contact X ₂ -b and line T of the relay X _2, normally-open contact X ₅ of the relay X ₅ - a _4, the swing motor RMR, the normally closed contact X ₄ -b ₂ of the relay X ₄ is It is inserted in series. Na us, to the connection point Q between the normally open contact X ₅ -a ₄ and the rocking motor RMR relay X _5, the sixth switch SW ₆ is connected. Further, the R relay SR and the compressor CM are inserted in series between the normally closed contact X ₂ -b of the relay X ₂ and the line T.

[0022]

Operation of the embodiment

 Next, the operation of the automatic ice maker according to the embodiment will be described. (Initial operation) When the power switch SB of the automatic ice machine is turned on and the power is turned on, the power lamp L₁And operating lamp L₂Are turned on, the compressor CM is started, and the refrigerant is supplied to the evaporation pipes 33, 33 of the first ice making unit 24 and the second ice making unit 25 through the cooling / freezing system of FIG. Also, relay X_Three, X_FiveEach normally closed contact X_Three-B₁, X _Five -b₁The actuator motor AML is rotated via the_Four, X_Five Each normally closed contact X_Four-B₁, X_Five-b₂The actuator motor AMR is rotated via the, and the water trays 26, 26 held in the horizontal postures of the units 24, 25 start to tilt obliquely downward. The fourth switch S is rotated by the rotation of the motor AMR._FourAfter the switch is turned off, the third switch S_ThreeIs activated and relay X_FourNormally-closed contact X that is energized and cooperates with it_Four-b₁, X_Four-b₂Is opened, and the contact is normally open X_Four-a closes. Further, the fifth switch S is driven by the rotation of the motor AML._FiveIs activated and relay X_ThreeNormally-closed contact X that is energized and cooperates with it_Three-b₁, X_Three-b₂Is opened, and the contact is normally open X_Three-a closes. At this time, the ninth switch SW for forcible tilting₉Is on the contact “a” side, and the thermoswitch Th is₁Is on the contact "a" side because no ice blocks are formed on the ice-making protrusions 28, so relay X_FiveIs activated, relay X_FiveNormally open contact X in cooperation with_Five-a₁, X_Five-a₂Closes, and the corresponding actuator motors AML, AMR are energized to continue rotation. As a result, the water trays 26, 26 return to the horizontal posture without stopping the tilting. Relay X_FiveIs a normally open contact X that cooperates with this_Five-a_Three, X_Five-a_FourIs self-held by closing. When the water trays 26, 26 return to the required positions, the fourth switch S_FourTurns on and the first water supply valve WV₁Is opened, and ice making water is supplied to the corresponding water trays 26, 26 through the supply pipes 50, 50.

With the rotation of the actuator motors AML and AMR, the third switch SW ₃ and the fifth switch SW ₅ are turned off, whereby the respective motors AML and AMR stop rotating and the water trays 26, 26 It is stopped in a horizontal position. When the relays X ₃ and X ₄ are deenergized, their normally closed contacts X ₃ -b ₂ and X ₄ -b ₂ are closed, and the swinging motors RMR and RML start their rotations. . Furthermore, by the third switch S W ₃ is OFF operation, first water supply valve WV ₁ stops the supply of ice making water is closed. However, the fourth switch SW ₄ maintains the ON state.

(Regarding Ice Making Operation) With the compressor CM energized by turning on the power, the refrigerant from the refrigerant circulation pipe of the refrigeration system causes the evaporation pipe 33 of the first ice making unit 24 and the evaporation pipe of the second ice making unit 25. The ice-making projections 28 provided on the corresponding ice-making substrate 30 are started to be cooled by the heat exchange action. Since the ice-making protrusions 28 are immersed in ice-making water, ice formation starts around the protrusions 28 and gradually grows to form an inverted dome-shaped ice mass as shown in FIG. During this ice making operation, the rocking motor R MR, RML continues to rotate, and the rocking plates 36,36 rock in the ice making water in the water trays 26,26 via the motors RMR, RML. Repeatedly, the ice making water is constantly moved, and the cloud of ice blocks formed on the ice making protrusions 28, 28 in both units 24, 25 is prevented.

(Regarding de-icing operation) A complete ice block is formed in an inverted dome shape on the ice-making protrusions 28, 28, and the rocking plates 36, 36 contact the ice block to prevent rocking. said detecting ice making completion detecting sixth switch SW ₆ and the seventh switch SW ₇ for, when each contact is switched from the "a" side to the "b" side, is self retained release of the relay X ₅ The actuator motors AMR and AML start rotating. As a result, the water trays 26, 26 of both ice making units 24, 25 start to tilt obliquely downward via the corresponding tilting mechanisms 42, 42. Due to this tilting, the ice making water in the water trays 26, 26 is discharged to the drainage receiving portion 31. The fourth switch SW ₄ is turned off during the process of tilting the water tray 26 of the first ice making unit 24. Then, the water tray 26 of the first ice making unit 24 tilts to the bottom dead center, the third switch S ₃ is turned on, and the relay X ₄ is energized to cooperate with it. Normally closed contact X ₄ -b ₁ , X ₄ -b ₂ open and the normally open contact X ₄ -a closes. Further, the water tray 26 of the second ice making unit 25 tilts to the bottom dead center, the fifth switch S ₅ is turned on, the relay X ₃ is energized, and the normally closed contact X ₃ -b ₁ cooperates with this. , X ₃ -b ₂ opens and the normally open contact X ₃ -a closes. At this time, the thermostat Th ₁ for detecting the completion of deicing is connected to the contact “b” side by the formation of ice blocks on the ice making protrusions 28. Therefore, the relay X ₅ is not energized, the actuator motors AMR, AML stop rotating, and the water trays 26, 26 stop tilting at the position where the bottom dead center is reached. Further, due to the tilting of the water trays 26, the ice blocks formed around the ice making protrusions 28 are exposed while being attached to the ice protrusions 28. The rocking plate 36 is positioned obliquely above the inner bottom surface of the water tray 26 and functions as a sliding chute for guiding the ice block to the ice storage chamber 20 when the ice block falls (Fig. 4).

At the same time when the water trays 26, 26 reach the tilting bottom dead center, the hot gas valve HV is opened and hot gas is supplied to the evaporation pipes 33, 33 instead of the refrigerant. As a result, the ice-making protrusions 28, 28 are rapidly heated through the ice-making substrates 30, 30. For this reason, the connection between the ice making projections 28, 28 and the ice blocks is released, and the ice blocks fall due to their own weight. Then, the upper surfaces of the rocking plates 36, 36 slide down and are guided and discharged into the above-mentioned ice storage chamber 20 located therebelow. Due to the falling of the ice blocks, the negative temperature load on the ice making substrates 30, 30 is released, and the temperature of the substrates 30, 30 rises all at once due to the hot gas flowing through the evaporation pipes 33, 33. This temperature rise is detected by the thermoswitch Th ₁ arranged on the side of the first ice making unit 24 and immediately switched to the contact “a” side, so that the relay X ₅ is energized and cooperates with it. When the open contacts X ₅ -a ₁ and X ₅ -a ₂ are closed, the rotations of the actuator motors AMR and AML are restarted. Further, the hot gas valve HV is closed and the supply of the refrigerant to the evaporation pipes 33, 33 is restarted. In the ice making machine 12 of the embodiment, when the water trays 26, 26 of the two ice making units 24, 25 all reach the tilting bottom dead center, hot gas is supplied to the respective evaporation pipes 33, 33. It is like this. That is, for example, even if the water tray 26 of one of the units 24 (25) reaches the tilting bottom dead center earlier, hot gas is not supplied to the steam pipes 33, 33, and thus the water of the other unit 25 (24) is not supplied. It is possible to prevent ice blocks from falling from the ice making projections 28 while the plate 26 is tilting and being accumulated in the water plate 26 without being guided and discharged to the ice storage chamber 20.

When the rotation of the motors AMR and AML is restarted, the water trays 26 and 26 are tilted via the tilting mechanisms 42 and 42 to start returning to the horizontal posture. In addition, when the rotation of the actuator motor AMR of the first ice making unit 24 is restarted, the fourth switch SW_FourIs turned on. As a result, the first water supply valve WV₁Open and replenish the water trays 26, 26 with ice making water. Then, by tilting the water tray 26, the third switch SW_ThreeTurns off and the first water supply valve WV₁Is closed to stop the supply of ice-making water and the actuator motor A MR is stopped. Also, the fifth switch SW_FiveTurns off and the actuator motor AML stops. This is the sixth switch SW for detecting the completion of ice making.₆And the seventh switch SW₇When the water trays 26, 26 tilt, each contact switches from the "b" side to the "a" side, and the relay X_FiveIs self-held and the relay X_FiveNormally closed contact X_Five-b ₁ , X_Five-b₂Is open. As a result, the water trays 26, 26 are stopped in a horizontal posture. The third switch SW_ThreeAnd the fifth switch SW_FiveTurns off and relay X_Three, X_FourNormally closed contacts X that cooperate with the_Three-b₂, X_Four-b₂Is closed, the rocking motors RMR and RML rotate, and the rocking plates 36 and 36 resume vertical rocking. The rocking motors RMR, RML are controlled so as to start rotating independently when the water trays 26, 26 of the units 24, 25 return to the horizontal postures, and thus are stored in the water trays 26, 26. The produced ice-making water can be effectively moved from the start of the ice-making operation to produce cloudy ice.

When the ice making operation is completed and the water tray 26 of the first ice making unit 24 is tilted while the ice making operation and the deicing operation are repeated and a predetermined amount of ice blocks is stored in the ice storage chamber 20, In the tilting process, the detection plate 52 comes into contact with the ice blocks to prevent tilting, whereby the eighth switch SW ₈ for detecting the completion of ice storage is turned on. When the fifth switch SW ₅ is turned on in this state, the relay X ₂ is energized to open the normally closed contact X ₂ -b cooperating with the relay X ₂ and rotate the actuator motors AMR, AML. Is stopped, and the energization of the compressor CM is also stopped. Further, the lamp L ₂ during the operation is turned off.

Here, when the contact of the ninth switch SW ₉ for forced tilting is switched from the “a” side to the “b” side, the water trays 26, 26 of both units 24, 25 are forcedly tilted down. The operation of the ice making machine 12 is stopped in a state where it is tilted to the dead point. For example, if the contact of the ninth switch SW ₉ is switched from the “a” side to the “b” side during the ice making operation, the self-holding of the relay X ₅ is released, and the first ice making unit 24 and the second ice making unit 25 are released. The rocking motors RMR and RML stop rotating, and the actuator motors AMR and AML are rotated to forcibly tilt the water trays 26 and 26 to the tilting bottom dead center. Then, when the fifth switch SW ₅ is turned on, the relay X ₂ is energized, the normally closed contact X ₂ -b cooperating with the relay is opened, and the rotations of the actuator motors AMR, AML are stopped. At the same time, the power supply to the compressor CM is stopped. When the contact of the ninth switch SW ₉ is switched from the “a” side to the “b” side while the water trays 26, 26 are tilting, the water trays 26, 26 reach the tilting bottom dead center. When the fifth switch SW ₅ is turned on, the operation of the ice making machine 12 is stopped.

When only “ice blocks” are to be taken out from the ice storage 22, the select lever 51 is switched so that the second switch SW ₂ is connected only to the discharging motor GM, and then the push button 49 is pressed. By pressing, the first switch SW ₁ is turned on, the relay X ₁ is energized, and the normally open contact X ₁ -a cooperating with it is closed. As a result, the discharging motor GM is energized to rotate the screw 46, and the ice blocks stored in the ice storage chamber 20 are discharged to the outside through the ice block discharge port 22a and the opening 48a. In addition, when switching the select lever 51 to specify the "lump of ice + water", since the second switch SW ₂ is connected to the release for motors GM and the second water supply valve WV _2, by and pressing the push button 49 The screw 46 is rotated by the discharging motor GM to discharge the ice blocks stored in the ice storage chamber 20 to the ice block discharge port 22a, and the second water supply valve WV ₂ is opened to allow the water to flow through the discharge pipe 56. It is discharged to the discharge port 22a. As a result, "coolness" is obtained. Further, when switching the select lever 51 to specify the "water", the second switch SW ₂ is connected only to the second water supply valve WV _2, the push button 49 second water supply valve WV ₂ is the pressing Succoth open Then, water is discharged to the ice block discharge port 22a through the discharge pipe 56.

[0031]

[Effect of the invention]

 As described above, according to the automatic ice making machine of the present invention, the rocking mechanism in the ice making mechanism operates from the time when the water tray returns from the tilting bottom dead center to the horizontal posture, so that the ice block produced by the ice making mechanism is operated. Can effectively prevent the white turbidity.

[Brief description of drawings]

FIG. 1 is a schematic vertical sectional view of an automatic ice making machine according to an embodiment.

FIG. 2 is a front view of the automatic ice maker according to the embodiment.

FIG. 3 is a schematic perspective view of an ice making unit in the automatic ice making machine according to the embodiment.

FIG. 4 is a schematic vertical sectional view of an ice making unit in the automatic ice making machine according to the embodiment.

FIG. 5 is a schematic explanatory view showing a refrigeration system of the automatic ice maker according to the embodiment.

FIG. 6 is an electric control circuit diagram of the automatic ice maker according to the embodiment.

[Explanation of symbols]

16 ... Condenser, 17 ... Freezing mechanism (freezing system) 24 ... 1st ice making unit (ice making mechanism), 25 ... 2nd ice making unit (ice making mechanism) 26 ... Water tray, 28 ... Ice making protrusion (ice making part), 30 ... Ice-making substrate 33 ... Evaporating tube, 36 ... Oscillating plate, 42 ... Tilt mechanism, 44 ...
Swing mechanism CM ... compressor, SW ₃ ... third switch (detecting means) SW ₅ ... fifth switch (detecting means)

Claims (1)

[Utility model registration claims] 1. An evaporation pipe (33) leading from a refrigeration system (17) including a compressor (CM), a condenser (16), etc. is arranged on the upper surface, and a large number of ice making parts (28) are formed on the lower surface. ) Protruding from the ice making substrate at a predetermined interval (30), and is always tilted by the body of the ice making machine to keep a horizontal posture at all times, and the ice making water stored in the ice making part (28) is The water tray (26) soaked and the rocking mechanism is housed inside the water tray (26) so that it can swing freely.
A rocking plate (36) which is rocked by (44) to move the ice-making water in the water tray (26), and the water tray (26) is tilted from a horizontal position toward the lower dead center diagonally. In an automatic ice making machine comprising an ice making mechanism (24, 25) consisting of a tilting mechanism (42) for returning from bottom dead center to a horizontal posture, the ice making mechanism (24, 25) is a water tray tilted to bottom dead center ( 26)
Detection means (SW ₃ , S
W ₅ ) is provided to detect that the water tray (26) has returned to the horizontal posture.
W _3, SW ₅₎ when detected, an automatic ice maker, characterized by being configured so as to move the ice-making water by the wobble plate by actuating the swing mechanism (44) (36).