CN1211713A - Automatic icing equipment - Google Patents
Automatic icing equipment Download PDFInfo
- Publication number
- CN1211713A CN1211713A CN98119179A CN98119179A CN1211713A CN 1211713 A CN1211713 A CN 1211713A CN 98119179 A CN98119179 A CN 98119179A CN 98119179 A CN98119179 A CN 98119179A CN 1211713 A CN1211713 A CN 1211713A
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- Prior art keywords
- ice
- mentioned
- making disc
- icing
- making
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C5/00—Working or handling ice
- F25C5/20—Distributing ice
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C1/00—Producing ice
- F25C1/22—Construction of moulds; Filling devices for moulds
- F25C1/24—Construction of moulds; Filling devices for moulds for refrigerators, e.g. freezing trays
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C5/00—Working or handling ice
- F25C5/18—Storing ice
- F25C5/182—Ice bins therefor
- F25C5/187—Ice bins therefor with ice level sensing means
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C2305/00—Special arrangements or features for working or handling ice
- F25C2305/022—Harvesting ice including rotating or tilting or pivoting of a mould or tray
- F25C2305/0221—Harvesting ice including rotating or tilting or pivoting of a mould or tray rotating ice mould
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25C—PRODUCING, WORKING OR HANDLING ICE
- F25C2600/00—Control issues
- F25C2600/04—Control means
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- Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Mechanical Engineering (AREA)
- Thermal Sciences (AREA)
- General Engineering & Computer Science (AREA)
- Production, Working, Storing, Or Distribution Of Ice (AREA)
Abstract
To execute an ice detecting operation even after an ice separation is conducted by carrying out the ice detecting operation before the ice separation. When an icemaking tray is forward rotated from a horizontal position, ice is separated. Meanwhile, when the tray is reversely rotated, an ice detecting lever is lowered, and whether ice in an ice storage case is fully filled or not is decided. In this case, a Hall integrated is turned on at the horizontal position and maximum twisted position of the tray. If the tray is in an ice detecting direction, the IC is turned off. When it is located in an ice detecting range, a position of the lever is sensed by the IC, and the lever senses the presence or absence of the ice.
Description
The present invention relates to be installed on the automatic icing equipment in the freezer.
In nearest freezer, be provided with automatic icing equipment.This automatic icing equipment is poured onto in the storage refrigerator ice that generates the water the supply system ice pan in the water tank in ice-making disc.
In order to control this automatic icing equipment, must obtain the information of ice-making disc position and the information of the storage ice amount of storage refrigerator, the information of ice-making disc position is used to control the rotation of the ice-making disc when icing, and the information of the storage ice amount of this storage refrigerator is used to judge whether to prepare ice.Thus, the position sensor of necessary installation and measuring disc spins position, and these two sensors of survey ice level sensor that detect storage ice amount.
Position sensor detects to the horizontal level of ice-making disc with owing to falling to ice the maximum twist position that ice-making disc is reversed, and this detection signal is sent to control part.Control part is judged the detection signal that position sensor transmits, if after making the rim ice the direction motion, control part receives detection signal, then this position is the maximum twist position, if after making ice-making disc recover the direction rotation along level, control part receives signal, and then this position is a horizontal level.
The detection of storage ice amount is to judge according to surveying the ice position detection signal that the ice level sensor detects the position gained of ice position bar, this surveys ice position bar when icing towards above return, when common, stretch into the storage refrigerator inside downwards.
But, in order to carry out above-mentioned control, must adopt position sensor simultaneously and survey these two sensors of ice level sensor, and dwindling for the whole volume of the automatic icing equipment that is used to increase storage ice amount, or the reduction of cost is that adverse influence is arranged, therefore, preferably make these sensors integrated.
So,, provide following automatic icing equipment (the clear 8-233419 document of TOHKEMY) as making these two sensors form the scheme of one.
Ice position-finding in the rotary course of this automatic icing equipment ice-making disc when icing, thereby, not only can carry out position probing, but also can be when filling with ice by 1 sensor, output signal in the short period of time, thus can detect filling with ice.That is, after making the ice-making disc edge ice the direction rotation,, so then make this ice-making disc at this moment, pass through certain hour then, when this sensor sends signal, then stop the rotation of ice-making disc along reverse rotation if unique sensor sends signal.
In addition, close in the common ice stadium of falling that does not reach the value of filling with in storage ice amount, owing to ice-making disc is not exported along the detection signal that fills with in the process of icing the direction rotation, so make ice-making disc along reverse rotation according to the signal of maximum twist position.When level is recovered, if only storage ice amount reaches the value of filling with and under the situation of output signal when icing, because this signal meeting certain time, equipment is ignored this signal like this, according to the signal more than the certain time on the level recovery position ice-making disc is stopped the rotation.
On the other hand, when storage ice amount reaches the value of filling with, if make ice-making disc from horizontal level, along icing the direction rotation, then in the process of rotation, after detection signal is filled with in output, make the rim reverse rotation from this position, after treating that it returns to horizontal level, export the signal of the sustainable certain hour of this position, ice-making disc is stopped the rotation.
That is to say, can judge its whether filled with water along icing time that direction rotation spent by making ice-making disc.
But, if adopt the automatic icing equipment of said structure, under normal conditions, in the rotary course in ice-making disc is recovered along the rotary course neutralization levels of icing direction, ice position bar moves up and down, the ice that once falls carries out 2 times survey ice bit motion, thereby can produce adverse influence to the life-span of ice position bar and its actuating mechanism like this.
In addition,, ice-making disc is reversed, therefore can be made the lost of life of ice-making disc even, when before supplying water, surveying the ice position, situation about not filling with is arranged for preparation next time ice with when falling to survey the ice position before the ice and be prerequisite.
In addition, owing to must monitor the rotational time of ice-making disc, or from the duration that sensor sends signal, be lower voltage so must make the motor voltage that drives the ice pan rotation.So, because in adopting the power of transformer circuit, the variation of source power supply voltage, or the increase even load of the motor current of ice-making disc when reversing changes, can cause that the voltage that is sent to motor changes, leave surplus must for like this capacity of transformer, thereby power circuit is maximized, can produce problems such as caloric value increase thus.If adopt conversion electric power etc., then can produce the problem that cost increases.
So, The present invention be directed to the problems referred to above and propose, the object of the present invention is to provide a kind of automatic icing equipment, this automatic icing equipment can be surveyed the ice bit motion before falling to ice, also can after falling to ice, survey the ice bit motion, and, can realize these actions by 1 sensor.
The automatic icing equipment of the 1st scheme of the present invention comprises ice-making disc, for the water that makes preparation breaks away from, this ice-making disc from horizontal level along icing the direction rotation, and from horizontal level along with ice direction opposite to the rotation of instead ice direction; The storage refrigerator, this storage refrigerator is arranged at the below of above-mentioned ice-making disc; An ice position bar, this ice position bar in above-mentioned ice-making disc along instead icing direction when rotating, rotatable to contact with ice being stored in above-mentioned storage refrigerator from the top; Controlling organization, this controlling organization control is iced step and is surveyed ice position step, ice in the step above-mentioned ice-making disc from horizontal level along icing the direction rotation, thereby fall the ice action, survey in the step of ice position above-mentioned ice-making disc along instead icing the direction rotation, thereby detect whether filled with water of above-mentioned storage refrigerator by above-mentioned ice position bar.
The automatic icing equipment of the 2nd scheme of the present invention relates to the equipment of above-mentioned the 1st scheme, this equipment comprises 1 detecting sensor, output signal when this detecting sensor is iced direction rotation predetermined angular on above-mentioned ice-making disc edge, and in above-mentioned ice-making disc when instead icing the direction rotation, the signal of the rotation status of the above-mentioned ice of output expression position bar; Above-mentioned controlling organization is iced in the step above-mentioned, make above-mentioned ice-making disc from horizontal level along icing direction rotation, after detecting the signal that above-mentioned detecting sensor sends, make above-mentioned ice-making disc return to horizontal level; In the step of above-mentioned survey ice position, make above-mentioned ice-making disc along instead icing the direction rotation, by the signal that above-mentioned detecting sensor is sent, whether detect in the above-mentioned storage refrigerator filled with water.
The automatic icing equipment of the 3rd scheme of the present invention relates to the equipment of above-mentioned the 2nd scheme, and this equipment comprises makes above-mentioned ice-making disc along icing direction and instead icing the motor of direction rotation, reaches the current detecting mechanism that the electric current that is sent to said motor is detected; Above-mentioned detecting sensor is output signal when above-mentioned ice-making disc is positioned at horizontal level also; In the initialization process process of above-mentioned controlling organization when power connection etc., make above-mentioned ice-making disc return the horizontal recovering step of horizontal level; This horizontal recovering step comprises: the 1st horizontal recovering step, and this step makes above-mentioned ice-making disc along icing the direction rotation by said motor; When the 2nd horizontal recovering step, this step reach a reference value at the detected electric current of above-mentioned current detecting mechanism, make above-mentioned ice-making disc along instead icing the direction rotation; The 3rd horizontal recovering step, this step makes above-mentioned ice-making disc stop at horizontal level when detecting the signal that above-mentioned detecting sensor sends.
The automatic icing equipment of the 4th scheme of the present invention relates to above-mentioned the 2nd the described equipment of scheme, this equipment comprises temperature sensor, this temperature sensor is installed in the above-mentioned ice-making disc, and it is according to the temperature of above-mentioned ice-making disc, detects having or not of water in the above-mentioned ice-making disc; Above-mentioned controlling organization carries out following step: in the process of temperature detection step, this step initialization process when power connection etc., by the said temperature sensor, detect having or not of water in the above-mentioned ice-making disc; Horizontal recovering step, this step detect at said temperature to be judged in the step in the above-mentioned ice-making disc and to make above-mentioned ice-making disc return horizontal level when anhydrous.
The automatic icing equipment of the 5th scheme of the present invention relates to above-mentioned the 2nd the described equipment of scheme, this equipment comprises temperature sensor, this temperature sensor is installed in the above-mentioned ice-making disc, and it is according to the temperature of above-mentioned ice-making disc, detects having or not of water in the above-mentioned ice-making disc; Above-mentioned controlling organization carries out following step: in the process of temperature detection step, this step initialization process when power connection etc., by the said temperature sensor, detect having or not of water in the above-mentioned ice-making disc; Horizontal recovering step, this step is judged when in the above-mentioned ice-making disc water being arranged in said temperature detection step, after the ice making action finishes, is made above-mentioned ice-making disc return horizontal level.
Automatic icing equipment to above-mentioned the 1st scheme is described below.
Generating ice with ice-making disc, the occasion that the ice that falls afterwards moves, controlling organization carries out the following step of icing, and this step makes ice-making disc ice the direction rotation from the horizontal level edge, thereby falls the ice action.
In addition, detecting the occasion whether the storage refrigerator fills with ice, surveying ice position step, this step makes ice-making disc along instead icing the direction rotation, detects by pole pair ice position, ice position.
Automatic icing equipment to above-mentioned the 2nd scheme is described below.
Controlling organization in icing step, make ice-making disc from horizontal level along icing direction rotation, when detecting the signal that detecting sensor sends, determine ice-making disc and be positioned at the maximum twist position, make ice-making disc return to horizontal level.That is, make the ice-making disc rotation along instead icing direction.
On the other hand, in surveying ice position step, make ice-making disc, detect the storage refrigerator by ice position bar and whether fill with ice, judge according to the signal that detecting sensor is sent along instead icing the direction rotation.
Thus, can only pass through a detecting sensor, ice the detection in step and the inspection ice position step.
Below with regard to above-mentioned the 3rd automatic icing equipment, the occasion that the ice-making disc of initialization process process turns back to horizontal level when making power connection etc. is described.
Above-mentioned controlling organization carries out the 1st horizontal recovering step, this step drives ice-making disc along icing the direction rotation by motor, afterwards, when the detected electric current of current detecting mechanism reaches a reference value, carry out the 2nd horizontal recovering step, make this ice-making disc along instead icing the direction rotation, when detecting the signal that detecting sensor sends, carry out the 3rd horizontal recovering step, this step makes ice-making disc stop at horizontal level.So, when making the ice-making disc edge ice direction rotation arrival maximum twist position, motor is applied load, thereby electric current is increased.Thus, the increase of this electric current is detected, whether be positioned at the maximum twist position thereby detect ice-making disc by current detecting mechanism.
Automatic icing equipment to above-mentioned the 4th scheme is described below.
When having water in the ice-making disc,, then can produce the danger that water overflows if make the ice-making disc rotation.
For this reason, controlling organization is in the process of initialization process, carry out the temperature detection step, this step detects having or not of the water in the ice-making disc by temperature sensor, only when in this temperature detection step, judge when ice-making disc does not have water, just make ice-making disc return the horizontal recovering step of horizontal level.
Automatic icing equipment to above-mentioned the 5th scheme is described below.
As mentioned above, when having water in the ice-making disc, if make the ice-making disc rotation, then can produce the phenomenon that water overflows, if carry out rotation to a certain degree, then water can not overflow from ice-making disc.
For this reason, controlling organization is in the process of initialization process, carry out the temperature detection step, this step detects having or not of the water in the ice-making disc by temperature sensor, afterwards, when in this temperature detection step, judge when in the ice-making disc water being arranged, after the action of ice making finishes, make above-mentioned ice-making disc get back to the horizontal recovering step of horizontal level.
Fig. 1 is in the automatic icing equipment of expression one embodiment of the present of invention, the perspective view when ice-making disc is horizontal;
Front view when Fig. 2 is horizontal for above-mentioned ice-making disc;
Perspective view when Fig. 3 ices state for ice-making disc is in;
Front view when Fig. 4 ices state for ice-making disc is in;
Fig. 5 is in inspection ice state for ice-making disc, and ices the perspective view when not filling with;
Fig. 6 is in inspection ice state for above-mentioned ice-making disc, and ices the perspective view when filling with;
Fig. 7 is in the front view of the occasion of inspection ice state for ice-making disc;
Fig. 8 is the right hand view that concerns between expression the 1st action component and the 2nd action component;
Fig. 9 is the longitudinal sectional drawing of center section part of the freezer of present embodiment;
Figure 10 is the longitudinal sectional drawing of seeing from the right side of the main body of automatic icing equipment;
Figure 11 is the longitudinal sectional drawing of seeing from the back side of the main body of automatic icing equipment;
Figure 12 is the block diagram of automatic icing equipment;
Figure 13 is the key diagram of the operating state of automatic icing equipment;
Figure 14 represents the table of ice-making disc spinning movement.
(overall structure of automatic icing equipment 10)
Fig. 9 is the longitudinal sectional drawing in stage casing that the freezer 12 of automatic icing equipment 10 is installed.
In Fig. 9, freezer 12 down comprises refrigerating chamber 14, ice storing cabin 16 and refrigerating chamber 18 from epimere, and automatic icing equipment 10 is contained in the ice storing cabin 16.
This automatic icing equipment 10 is by the main body 22 of ice-making disc 20, rotatably mounted this ice-making disc, the ice position bar 24 that rotates freely of this main body 22 constitutes relatively.
In addition, in the bottom of refrigerating chamber 14 water tank 26 that supplies water to ice-making disc 20 is housed, the water that is provided by this water tank 26 passes through water inlet pipe 30, is sent to ice-making disc 20, and this water inlet pipe 30 is installed between the partition member 28 of refrigerating chamber 12 and ice storing cabin 16.
In addition, the storage refrigerator 32 that is used for storing the ice that falls from ice-making disc 20 is housed below ice making equipment 10.
(internal structure of automatic icing equipment 10)
Internal structure according to the main body 22 of Figure 10,11 pairs of automatic icing equipments 10 is described below.The longitudinal sectional drawing of Figure 10 for seeing from the right side of main body 22, the longitudinal sectional drawing of Figure 11 for seeing from the back side of main body 22.
As shown in figure 10, the back of main body 22 is passed in the rotating shaft 34 of spiraling of ice-making disc 20.
As shown in figure 11, on this spirals rotating shaft 34, plectane 36 and the 1st gear 38 are housed coaxially.The 2nd gear 40 and 38 engagements of the 1st gear, the 3rd gear 42 and 40 engagements of the 2nd gear.Between the back of plectane 36 and main body 22, motor 44 is housed, is contained in worm screw 46 and above-mentioned the 3rd gear 42 engagements on the rotating shaft of this motor 44.
Thus, when motor 44 drove, 38 rotations of worm screw the 46, the 3rd gear the 42, the 2nd gear the 40, the 1st gear drove plectane 36 also with its rotation, thereby ice-making disc 20 are rotated.
On the other hand, ice position bar 24 is hinged at the right flank and the bar rotating shaft 48 of main body 22.
(making the structure of ice-making disc 20 rotations)
Be described according to Fig. 1~8 pair a plectane 36 and an ice position bar 24 that ice-making disc 20 is rotated below.In addition, in Fig. 1~8, owing to be easy to the gear 38,40,42,46 and the motor 44 that make plectane 36 rotations are illustrated the Therefore, omited description of them.
At first, the direction of rotation to ice-making disc 20 describes.
As depicted in figs. 1 and 2, " level of ice-making disc 20 " refers to that ice making face is a horizontal state.
When ice-making disc was fallen the ice action, shown in Fig. 3 and 4, it rotated along direct rotational direction, and ice-making disc 20 is in twisting states, thereby realizes ice.Here, " positive rotation " refers to the A1 direction among Fig. 3 and Fig. 4.
Ice-making disc 20 shown in Fig. 5,6,7, is rotated along the rightabout despining direction A2 with direct rotational direction A1 when detecting storage ice amount according to mode described later.
The back of plectane 36 constitutes the 1st cam 50, and the front of plectane 36 constitutes the 2nd cam 52.
Structure and action to the 1st cam 50 is described below.
Shown in Fig. 2,4,7, have the 1st cam path 53 substantially in the form of a ring in the back of plectane 36.
The 1st action component 54 of long strip-board shape is housed in the place ahead of above-mentioned the 1st cam 50.56 rotations freely can be put around axle in the right part of the 1st action component 54, and its left part can be freely along moving up and down.In addition, position probing magnet 58 is housed on this left part.In addition, be provided with the 1st protuberance 60 with the 1st cam path 53 tablings in the central authorities of the 1st action component 54.
Thus, when plectane 36 (the 1st cam 50) rotated, along with the rotation of the 1st cam path 53, the 1st protuberance 60 was along moving up and down, and the position probing that is positioned at the left part of the 1st action component 54 moves up and down too with magnet 58.
Here, the 1st cam path 53 forms in the following manner, this mode is: only when ice-making disc 20 is positioned at the position of about ± 10 ° of relative horizontal level, for the position probing that makes the 1st action component 54 places the top position with magnet 58, and only in this position, the 1st cam path 53 is made towards the shape of top groove that enlarge, that diameter is bigger (below, the above-mentioned position of ice-making disc is called " horizontal field 62 ").
In addition, rotating along direct rotational direction on about 180 ° position, the 1st cam path 53 rises towards the top in order to make the 1st protuberance 60 once more, and it is made the shape (below, this position is called " the maximum twist zone 63 " of ice-making disc) of the bigger groove of diameter.
Also have,, be positioned at lower position in order to make position probing with magnet 58, and it is made the shape of the less groove of diameter in other the anglec of rotation.
Structure and action to the 2nd cam 52 is described below.
The 2nd cam 52 is to be formed by the 2nd cam path 64 in the ring-type of the front of plectane 36.
The 2nd protuberance 66 and the 2nd cam path 64 tablings, the 2nd protuberance 66 stretches out from the bar rotating shaft 48 of ice position bar 24.
When ice-making disc 20 was rotated about 45 ° along the despining direction, the 2nd cam path 64 can move towards other the below of position for making the 2nd protuberance 66, was the shape (below, this position is called ice-making disc " surveying zone, ice position 68 ") of the bigger groove of diameter.
Also have, the 2nd actuating strut 70 is housed at the middle part of bar rotating shaft 48, at the front end of the 2nd action component 70 storage ice is housed and detects with magnet 72.This detection magnet 72 is positioned at position probing with near the magnet 58.
Action to the 2nd cam 52 is described below, when ice-making disc 20 when the despining direction is rotated about 45 °, survey the 2nd protuberance 66 places that zone, ice position 68 is arranged in bar rotating shaft 48.Thereby, in this position, detect by 24 pairs of ice positions of ice position bar, if storage refrigerator 32 fills with ice, then this ice position bar 24 contacts with ice, and can not rotate, the 2nd protuberance 66 on the bar rotating shaft 48 can not drop into to be surveyed in the zone, ice position 68.Do not having ice on the other hand, or do not filling with the occasion of ice, ice position bar 24 can be because of gravity rotates towards the below, and the 2nd protuberance 66 drops into to be surveyed in the zone, ice position 68.At this moment, storage ice detects with magnet 72 also with 48 rotations of bar rotating shaft.
Hall integrated circuit 74 is equipped with in inboard at the right flank of main body 22.When these hall integrated circuit 74 position probing magnets 58 close described above, or store ice and detect when using magnet 72, become open mode from closed condition.
(circuit structure in the automatic ice-making plant 10)
Below according to the block diagram of Figure 12, the circuit structure of automatic icing equipment 10 is described.
Controlling organization that automatic icing equipment 10 is controlled 78 is made of microcomputer, and its drive circuit 80 with hall integrated circuit 74, temperature sensor 76 and motor 44 is connected.In addition, this mechanism also is connected with current detection circuit 82.82 pairs of this current detection circuits detect from the current value that drive circuit 80 is sent to motor 44.
(operating state of automatic icing equipment 10)
Below according to Fig. 1 to 8,13,14, the operating state of automatic icing equipment 10 recited above is described.
(1) occasion (with reference to Fig. 1,2,13,14) that is horizontal of ice-making disc 20
Be to generate in the ice-making disc 20 occasion or the anhydrous occasion of ice, ice-making disc 20 keeps static at horizontal level.
At this moment, as shown in Figure 1, in the 2nd cam 52,, surveys beyond the zone, ice position 68 the 2nd protuberance 66, so bar rotating shaft 48 remains on the state that ice position bar 24 is risen towards the top because being positioned at.On the other hand, because the 2nd action component 70 is positioned at the position of leaving hall integrated circuit 74,, storage ice can not impact hall integrated circuit 74 with magnet 72 so detecting.
As shown in Figure 2, in the 1st cam 50, because the 1st protuberance 60 in the 1st action component 54 is positioned at the horizontal zone 62 of the 1st cam path 53, therefore the position probing of the 1st action component 54 is positioned near the hall integrated circuit 74 with magnet 58, as shown in figure 13, make hall integrated circuit 74 be in open mode.
(2) ice-making disc 20 falls to ice the occasion (with reference to Fig. 3,4,13,14) of action
According to the temperature detection signal of temperature sensor 76, judge whether the ice making action finishes, if the ice making action finishes, the motor 44 that then is in down the ice action makes ice-making disc 20 rotate along direct rotational direction A1.
As shown in Figure 4, when plectane 36 (the 1st cam 50) rotates, because in rotation, the 1st protuberance 60 moves towards the position beyond the horizontal zone 62, the position probing of the 1st action component 54 is separated with magnet 58 and hall integrated circuit 74, as shown in figure 13, make this hall integrated circuit 74 be in closed condition.
As shown in Figure 4, motor 44 continues rotation, and when rotating to about 180 ° position, the 1st protuberance 60 moves to maximum twist zone 63.Thus, the storage ice detection in the 1st action component 54 is positioned near the hall integrated circuit 74 once more with magnet 72, as shown in figure 13, makes this hall integrated circuit 74 be in open mode.
Become the position of open mode at hall integrated circuit 74 once more from closed condition, as shown in figure 13, controlling organization 78 judges that ice-making disc 20 arrive maximum twist zones 63, returns to horizontal level for making it, and motor 44 is driven along the despining direction.
When ice-making disc 20 along despining direction rotation, thereby when leaving the position in maximum twist zone 63, above-mentioned hall integrated circuit 74 is in closed condition, temporary transient this state that keeps continuously.In addition, as shown in figure 13, in the time of in arriving horizontal zone 62, this hall integrated circuit 74 is in open mode once more, thereby after making controlling organization 78 judge that ice-making disc 20 returns to horizontal level, thereby motor 44 is stopped.
(3) ice position bar 24 is surveyed the occasion (with reference to Fig. 5,6,7,8,13,14) of ice bit motion
As shown in figure 13, by being contained in the timer of controlling organization 78 inside, t1 drives in required time, so that ice-making disc 20 is rotated about 45 ° along the despining direction.
As shown in Figure 7, in the 1st cam 50,, and the position probing of the 1st action component 54 is separated with magnet 58 and hall integrated circuit 74, made hall integrated circuit 74 be in closed condition because the 1st protuberance 60 arrives horizontal zone 62 position in addition.At this state, survey zone, ice position 68 and be positioned at the 2nd protuberance 66 positions.
As shown in Figure 6, when the ice in the storage refrigerator 32 filled with, ice position bar 24 contacted with water, can not rotate, and the 2nd protuberance 66a is in zone, relative survey ice position 68 states that float.Thus, also separate with magnet 72 because the storage of the 2nd action component 70 ice detects, and make this hall integrated circuit 74 be in closed condition with hall integrated circuit 74.
On the other hand, as shown in Figure 7, do not ice in storage refrigerator 32, when ice position bar 24 descended, the 2nd protuberance 66b also dropped into downwards to survey and ices in the zone, position 68.So the storage ice in the 2nd action component 70 detects with magnet 72 close hall integrated circuits 74, makes this hall integrated circuit 74 be in open mode.As shown in figure 13, owing to get back to above-mentioned open mode, controlling organization 78 is judged in the storage refrigerator 32 does not have ice.
As shown in figure 13, return to horizontal level for making ice-making disc 20, motor 44 makes ice-making disc 20 along the direct rotational direction rotation t1 time once more.At this moment, whether ice-making disc 20 recover to be to judge like this, when the 1st protuberance 60 arrives the position of horizontal zones 62, when hall integrated circuit 74 is in open mode, then arrives this recovery position.
(4) survey ice bit motion and the control of the order of ice action
Surveying the ice bit motion is arbitrarily with the order of falling to ice action.
Such as, can be after surveying the ice bit motion, the ice that falls moves.Ice bit motion by survey and judge that ice does not fill with, when the ice that also can fall moves, after the time, can fall to ice action continuously by horse back from position, survey ice position along direct rotational direction rotation t1.
In addition, filling with the occasion of ice, also can not make ice-making disc 20 turn back to horizontal level, making this ice-making disc 20 be in contrary 45 ° heeling condition, after wait ice uses, until bar 24 declines of ice position.In addition, in case after ice-making disc 20 turns back to horizontal level, also can be with the switching of door, or certain time interval is surveyed the ice bit motion once more as opportunity.
Formerly carry out falling to ice the occasion of action, before carrying out the water that next time, the supply ice making was used, surveyed the ice bit motion.When by surveying the ice bit motion, record the occasion that ice fills with, do not wait until when ice fills with always and just supply water.This wait method is identical with the above-mentioned occasion of surveying ice position earlier, also can make ice-making disc 20 be in heeling condition, etc. water to be used, descend until ice position bar 24, in addition, in case after ice-making disc 20 turns back to horizontal level, also can be with the switching of door, or certain time interval is surveyed the ice bit motion once more as opportunity.
(performance of motor 44)
Below, motor 44 is described.
When falling the ice action, determine that by hall integrated circuit 74 ice-making disc 20 is to be horizontal, still be in the maximum twist position, needn't adopt timer to carry out time control simultaneously.Thus, it doesn't matter to realize the action of ice and the voltage of motor 44 by motor 44.Such as, can make motor voltage be in the relative broad range of 7~13V.
Otherwise, surveying ice during bit motion, only need making the 2nd cam 52 rotate to an ice position bar 24, can to detect the ice bit position just passable.In other words, because in this occasion, do not apply load on the motor 44, substantially need not motor torque, can not cause so big influence to the change of supply voltage like this, the change of rated value has ± variable quantity of 2V such as relative 12V, can not have problems, maintain surplus can for the degree of stability of supply voltage.
In addition, when carrying out this survey ice bit motion,, the operation precision of ice position bar 24 can be improved like this, the lower power supply of price that in drive circuit 80, adopts the transformer mode can be adopted because motor voltage can be a certain lower voltage limit that can realize down the ice action.
(the horizontal recovery control method of ice-making disc 20)
(1) the 1st horizontal recovery control method
When carrying out initialization process during below to the power connection of freezer etc., the 1st horizontal recovery control method that makes ice-making disc 20 return to horizontal level is described.
When carrying out above-mentioned initialization process, make ice-making disc 20 along being rotated in the forward the t1 time above (such as, t1+1 second, below, be referred to as " t2 time ").
So ice-making disc 20 is in from horizontal level to the position the maximum twist position, afterwards, makes ice-making disc 20 along reverse rotation, above-mentioned hall integrated circuit 74 is got back to the position of open mode and is promptly got back to horizontal level.
Also have, during from horizontal level to the maximum twist position, when the edge is rotated in the forward the t2 of t1 more than the time during time, because ice-making disc 20 rotations surpass the maximum twist position, in order to make its rotation be no more than this maximum twist position retainer is installed, or the engagement between the gear 38~46 is thrown off, and do not limit the reversing of ice-making disc 20 to good.
(2) the 2nd horizontal recovery control method
The 2nd horizontal recovery control method to ice-making disc 20 is described below.
If adopt the 1st horizontal recovery control method, be no more than the maximum twist position in order to make ice-making disc 20, retainer must be set, this retainer can make gear 38~46 produce stress.In addition, when making gear 38~46 throw off engagement, can produce the noise when throwing off.
Therefore, in the 2nd horizontal recovery control method, control in the following manner, this mode is: control the electric current that is sent to motor 44 from drive circuit 80, do not make ice-making disc 20 rotations surpass the maximum twist position.
Specifically, when the maximum twist position, hall integrated circuit 74 is in the state of opening, and meanwhile, making to act on the motor 44 has this to reverse the torque that causes, and motor current increases.So, be in open mode at hall integrated circuit 74, and by current detection circuit 82, detecting motor current surpasses a reference value and judges that ice-making disc is in the maximum twist position, at this moment, even, still make it along reverse rotation along being rotated in the forward under the situation that does not reach the t2 time, in case hall integrated circuit 74 become close not busy state after, it is stopped when this ice-making disc rotates to when making this hall integrated circuit 74 be in the horizontal level of position of next open mode.
(3) the 3rd horizontal recovery control method
The 3rd horizontal recovery control method to ice-making disc 20 is described below.
In order to replace according to the 2nd horizontal recovery control method, by a reference value motor current is carried out judgment mode, in the 3rd horizontal recovery control method, difference between electric current when motor current during by common rotation and level are recovered being rotated in the forward of control, whether, judge whether to reach the maximum twist position greater than a reference value.Others in addition are identical with the 2nd horizontal recovery control method.By adopting this difference between current, can eliminate Yin Mada individual difference, last variation, temperature the influence that variation caused to coil impedance.
Specifically, the motor current when rotating usually is for formerly to carry out being rotated in the forward of t2 time, the current value when carrying out the reverse rotation in 1 second again, and fixed its be motor current when rotating usually.
This be because: even be positioned in ice-making disc under the situation of maximum twist position, when along reverse rotation, still can not act on moment of torsion on the ice-making disc 20.
In addition, at this moment,, must rotate a reverse rotation time along positive rotation in order before being rotated in the forward of t2 time, to detect common electric current.
(4) the 4th horizontal recovery control method
The 4th horizontal recovery control method to ice-making disc 20 is described below.
The 4th horizontal recovery control method detects by hall integrated circuit 74 and electric current to be increased and when reaching the maximum twist position, with irrelevant situation of t2 time under must make ice-making disc 20 along being rotated in the forward, to the maximum twist position, make it along reverse rotation afterwards, turn back to level.
(5) the 5th horizontal recovery control method
By above-mentioned method, can make ice-making disc 20 turn back to horizontal level certainly, still, the occasion of water inlet has the danger that water overflows in ice-making disc 20.For this reason, also must before recovering action, above-mentioned level carry out following control.
Temperature by 76 pairs of ice-making disc 20 of temperature sensor detects, and when judging that the preparation hydrodynamic(al) is done to finish, carries out above-mentioned level and recovers action.By adopting aforesaid way, can prevent the phenomenon that sealing overflows from ice-making disc 20.In addition, when connecting power supply, coil colder (such as, temperature sensor is below-9.5 ℃), can obviously judge the not occasion of water inlet, also can not wait under the situation that the ice making action finishes, carry out level and recover to move.
On the other hand, the occasion of water inlet in ice-making disc 20, ice-making disc 20 is horizontal, and at this moment, even under the situation that makes ± 10 ° of ice-making disc 20 rotations, water still can not overflow.Thus, if after initialization process, about 10 ° along reverse rotation of the positions that makes ice-making disc 20 make hall integrated circuit 74 be in closed condition, then since ice-making disc 20 be not horizontal, thereby the aforesaid level that turns back to horizontal level is recovered action.In addition,, owing to have water, and make ice-making disc 20 return the home position in occasion in addition, this equipment can with having or not of water irrelevant situation under finish the action of preparation ice, carry out level afterwards again and recover action.
In addition, also will draw first switch and magnet combination, or with cam and switch combination, so that the hall integrated circuit 74 in replacement the foregoing description.
If adopt automatic icing equipment of the present invention, can be individually fall ice action and survey the ice bit motion, can survey the ice bit motion after the ice action falling, in addition, otherwise also can, after surveying the ice bit motion, fall to ice and move.
If adopt the 2nd described automatic icing equipment of scheme of the present invention, can fall to ice action and survey the ice bit motion by 1 detecting sensor.
If adopt the 3rd described automatic icing equipment of scheme of the present invention, recover action step by after initialization process, carrying out level, can make ice-making disc return to horizontal level really.
If adopt the 4th described automatic icing equipment of scheme of the present invention, when anhydrous, owing to carry out horizontal recovering step, the situation that water overflows from ice-making disc can not take place like this in judging ice-making disc.
If adopt the 5th described automatic icing equipment of scheme of the present invention, when in determining ice-making disc, water being arranged,, can not produce the situation that water overflows like this owing to after the action of ice making, carry out horizontal recovering step.
Claims (5)
1. automatic icing equipment is characterized in that it comprises:
Ice-making disc, for the ice that makes preparation breaks away from, this ice-making disc can be from horizontal level along icing the direction rotation, and can from horizontal level along with ice direction opposite to the rotation of instead ice direction;
The storage refrigerator, this storage refrigerator is arranged at the below of above-mentioned ice-making disc;
With an ice position bar, this ice position bar in above-mentioned ice-making disc along instead icing direction when rotating, rotatable to contact with ice being stored in above-mentioned storage refrigerator from the top;
Controlling organization, this controlling organization control is iced step and is surveyed the ice step, this ice in the step above-mentioned ice-making disc from horizontal level along icing the direction rotation, thereby fall the ice action, survey whether above-mentioned ice-making disc fills with ice along instead icing the direction rotation thereby detect above-mentioned storage refrigerator by above-mentioned ice position bar in the step of ice position.
2. automatic icing equipment according to claim 1 is characterized in that:
This equipment comprises 1 detecting sensor, and this detecting sensor is in above-mentioned ice-making disc output signal when icing direction rotation predetermined angular, and in above-mentioned ice-making disc when instead icing the direction rotation, the signal of the rotation status of the above-mentioned ice of output expression position bar;
Above-mentioned controlling organization is iced in the step above-mentioned, make above-mentioned ice-making disc from horizontal level along icing direction rotation, after detecting the signal that above-mentioned detecting sensor sends, make above-mentioned ice-making disc return to horizontal level;
In the step of above-mentioned survey ice position, make above-mentioned ice-making disc along instead icing the direction rotation, by the signal that above-mentioned detecting sensor is sent, detect in the above-mentioned storage refrigerator whether fill with ice.
3. automatic icing equipment according to claim 2 is characterized in that:
This equipment comprises makes above-mentioned ice-making disc along icing direction and instead icing the motor of direction rotation; And
The current detecting mechanism that the electric current that is sent to said motor is detected;
Above-mentioned detecting sensor is output signal when above-mentioned ice-making disc is positioned at horizontal level also;
In the initialization process process of above-mentioned controlling organization when power connection etc., make above-mentioned ice-making disc return the horizontal recovering step of horizontal level;
This horizontal recovering step comprises:
The 1st horizontal recovering step, this step makes above-mentioned ice-making disc along icing the direction rotation by said motor;
When the 2nd horizontal recovering step, this step reach a reference value at the detected electric current of above-mentioned current detecting mechanism, make above-mentioned ice-making disc along instead icing the direction rotation;
The 3rd horizontal recovering step, this step makes above-mentioned ice-making disc stop at horizontal level when detecting the signal that above-mentioned detecting sensor sends.
4. automatic icing equipment according to claim 2 is characterized in that:
This equipment comprises temperature sensor, and this temperature sensor is installed in the above-mentioned ice-making disc, and it is according to the temperature of above-mentioned ice-making disc, detects having or not of water in the above-mentioned ice-making disc;
Above-mentioned controlling organization carries out following step:
In the process of temperature detection step, this step initialization process when power connection etc.,, detect having or not of water in the above-mentioned ice-making disc by the said temperature sensor;
Horizontal recovering step, this step detect at said temperature to be judged in the step in the above-mentioned ice-making disc and to make above-mentioned ice-making disc return horizontal level when anhydrous.
5. automatic icing equipment according to claim 2 is characterized in that:
This equipment comprises temperature sensor, and this temperature sensor is installed in the above-mentioned ice-making disc, and it is according to the temperature of above-mentioned ice-making disc, detects having or not of water in the above-mentioned ice-making disc;
Above-mentioned controlling organization carries out following step:
In the process of temperature detection step, this step initialization process when power connection etc.,, detect having or not of water in the above-mentioned ice-making disc by the said temperature sensor;
Horizontal recovering step, this step is judged when in the above-mentioned ice-making disc water being arranged in said temperature detection step, after the ice making action finishes, is made above-mentioned ice-making disc return horizontal level.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP24872497A JP3572175B2 (en) | 1997-09-12 | 1997-09-12 | Automatic ice making equipment |
JP248724/97 | 1997-09-12 |
Publications (2)
Publication Number | Publication Date |
---|---|
CN1211713A true CN1211713A (en) | 1999-03-24 |
CN1080406C CN1080406C (en) | 2002-03-06 |
Family
ID=17182412
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN98119179A Expired - Lifetime CN1080406C (en) | 1997-09-12 | 1998-09-11 | Automatic icing equipment |
Country Status (3)
Country | Link |
---|---|
JP (1) | JP3572175B2 (en) |
KR (1) | KR100273051B1 (en) |
CN (1) | CN1080406C (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103307828A (en) * | 2012-03-09 | 2013-09-18 | 株式会社Scd | Driving device for automatic ice-making machine |
CN111336729A (en) * | 2018-12-19 | 2020-06-26 | 青岛海尔股份有限公司 | Ice maker and refrigerator with same |
Families Citing this family (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6571567B2 (en) * | 2001-09-07 | 2003-06-03 | Lg Electronics Inc. | Ice-making apparatus in refrigerator |
KR100671567B1 (en) | 2004-05-18 | 2007-01-18 | 엘지전자 주식회사 | Sense apparatus for full ice of ice maker in refrigerator |
JP5414755B2 (en) * | 2011-08-31 | 2014-02-12 | 日立アプライアンス株式会社 | refrigerator |
KR101331104B1 (en) * | 2011-10-28 | 2013-11-20 | 주식회사 에스 씨디 | Driving device for automatic ice-making machine |
JP5675935B2 (en) * | 2013-11-07 | 2015-02-25 | 日立アプライアンス株式会社 | Automatic ice machine and refrigerator |
CN106524617B (en) * | 2016-10-27 | 2018-12-25 | 上海浪拓制冷设备有限公司 | A kind of ice machine making ice and deice efficiency with raising |
KR102446548B1 (en) * | 2017-12-13 | 2022-09-26 | 주식회사 대창 | Ice maker and refrigerator including the same |
KR102417855B1 (en) | 2020-09-14 | 2022-07-07 | 엘지전자 주식회사 | Ice making assembly and controlling method thereof |
-
1997
- 1997-09-12 JP JP24872497A patent/JP3572175B2/en not_active Expired - Lifetime
-
1998
- 1998-09-11 KR KR1019980037887A patent/KR100273051B1/en not_active IP Right Cessation
- 1998-09-11 CN CN98119179A patent/CN1080406C/en not_active Expired - Lifetime
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103307828A (en) * | 2012-03-09 | 2013-09-18 | 株式会社Scd | Driving device for automatic ice-making machine |
CN103307828B (en) * | 2012-03-09 | 2015-10-28 | 株式会社Scd | For the drive unit of the ice maker of refrigerator |
US9784491B2 (en) | 2012-03-09 | 2017-10-10 | Scd Co., Ltd. | Driving device for automatic ice-making machine |
CN111336729A (en) * | 2018-12-19 | 2020-06-26 | 青岛海尔股份有限公司 | Ice maker and refrigerator with same |
Also Published As
Publication number | Publication date |
---|---|
JP3572175B2 (en) | 2004-09-29 |
JPH1183260A (en) | 1999-03-26 |
KR19990029776A (en) | 1999-04-26 |
CN1080406C (en) | 2002-03-06 |
KR100273051B1 (en) | 2000-12-01 |
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Address after: Tokyo, Japan Patentee after: Toshiba Corp. Address before: Kanagawa Patentee before: Toshiba Corp. |
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Effective date of registration: 20160919 Address after: Tokyo, Japan Patentee after: TOSHIBA LIFESTYLE PRODUCTS & SERVICES Corp. Address before: Tokyo, Japan Patentee before: Toshiba Corp. |
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