CN1141417A - Water feeding apparatus for automatic ice making device - Google Patents

Water feeding apparatus for automatic ice making device Download PDF

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Publication number
CN1141417A
CN1141417A CN96104214A CN96104214A CN1141417A CN 1141417 A CN1141417 A CN 1141417A CN 96104214 A CN96104214 A CN 96104214A CN 96104214 A CN96104214 A CN 96104214A CN 1141417 A CN1141417 A CN 1141417A
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China
Prior art keywords
feedwater
valve
ice
water
action
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Granted
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CN96104214A
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CN1122801C (en
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上野俊司
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Toshiba Corp
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Toshiba Corp
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25CPRODUCING, WORKING OR HANDLING ICE
    • F25C1/00Producing ice
    • F25C1/22Construction of moulds; Filling devices for moulds
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25CPRODUCING, WORKING OR HANDLING ICE
    • F25C2400/00Auxiliary features or devices for producing, working or handling ice
    • F25C2400/14Water supply

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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

The invention provides a water supplying device for an automatic ice maker, comprising a water outlet valve mechanism to open and close the water outlet of a quantitative cistern and a groove valve mechanism to open and close the water inlet of a water storage tank. The invention is provided with a valve operation mechanism which repeatedly conducts the following movements: fill a certain quantity of water in the water storage tank into the quantitative cistern in the first state from the opening of the water outlet valve mechanism to the closing of the groove valve mechanism and in the second state from the closing of the water outlet valve mechanism to the opening of the groove valve mechanism; then close the groove valve, return to the first state and supply the water in the quantitative cistern to the ice maker. The invention is also provided with an original place detection mechanism to detect whether the valve operation mechanism is at the first state, namely the original place.

Description

The waterworks that automatic ice-making plant is used
The present invention relates to the waterworks that automatic ice-making plant is used, this device is used for the ice maker container of the automatic ice-making plant in refrigerator and supplies with certain water gaging.
In the prior art, the waterworks that this automatic ice-making plant is used are the water of storing in the water receiving ware that is located in the refrigerator, by the ice maker container in the feed pump the supply system icehouse (being ice making tray).Its structure is, hopper releasably be arranged on the water receiving ware above, by being located at the groove valve of this hopper bottom, the water level in the water receiving ware is kept certain water level with respect to the water receiving ware.That is, supply with a certain amount of water from hopper.
But, in the waterworks of above-mentioned prior art,, can adhere to incrustation scale or mouldy etc. at water receiving ware inner surface owing to often storing water in the water receiving ware, very unhygienic.In addition, when ice making tray supplies water, feed pump sends harsh noise.
To this,, the applicant has invented the waterworks that address the above problem, and patent applied for (for example Japanese patent gazette is special is willing to flat 6-205332 number).Have quantitative cistern, hopper, outlet valve mechanism, groove valve system in these waterworks, give aquaporin and valve operating gear.Quantitative cistern is located at the ice maker container top and delivery port is arranged at the bottom; Hopper is located at this quantitative cistern top, and has admission port from certain water gaging to quantitative cistern that supply with; Outlet valve mechanism is used to open and close the delivery port of quantitative cistern; The groove valve system is used to open and close the admission port of hopper; Supply with ice maker container to the water that aquaporin is used for flowing out from quantitative cistern; Valve operating gear carries out following feedwater action periodically: from outlet valve mechanism and the buttoned-up state of groove valve system, open the groove valve system, from hopper, a certain amount of water is injected quantitative cistern, close the locked groove valve system then, open outlet valve mechanism, water in the quantitative cistern is supplied with ice maker container, close outlet valve mechanism again, get back to original state.
In said structure, close the delivery port of quantitative cistern earlier with outlet valve mechanism, under this state, open the groove valve system, from hopper, a certain amount of water is injected quantitative cistern.Close the locked groove valve system then and open outlet valve mechanism simultaneously, will exist a certain amount of water in the quantitative cistern to pass through to aquaporin the supply system ice container.In this case, when ice maker container feeds water, because the groove valve system closing, so to the precision height of ice maker container quantitative water supply.And not when ice maker container feeds water, quantitatively cistern is empty, so be difficult for producing incrustation scale, mouldy etc.
But in said structure, when the feedwater holding state that waterworks are failure to actuate, outlet valve mechanism and groove valve system are all being closed.Here, the valve body of outlet valve mechanism is to constitute like this, promptly contacts or leave by the rubber gasket on making above-mentioned valve body and being installed in quantitative cistern delivery port peristome to open and close delivery port.Therefore, under the delivery port closing state, valve body is pressed on the rubber gasket tightly.Valve body is normally made with hard resin, and this hard resin is pressed on the rubber for a long time, and both meetings closely contact and are difficult for throwing off.In addition, the valve operating gear operating physical force that is used for opening the valve body of outlet valve mechanism can not be set very greatly.Therefore, close outlet valve mechanism for a long time after, make waterworks when action, the delivery port of not opening sometimes, and cause feedwater bad.In addition, after the compression for a long time of rubber gasket, can not get back to original form, so if close outlet valve mechanism for a long time, then the sealing property of rubber gasket and outlet valve mechanism will worsen.
The present invention makes in view of the above problems, the waterworks that provide a kind of automatic ice-making plant to use are provided its purpose, this device can improve the precision to the ice maker container quantitative water supply, be difficult for to produce incrustation scale, mouldy etc. in the quantitative water supply container, and, even the feedwater holding state for a long time, can prevent that also the action of outlet valve mechanism is malfunctioning.
To achieve these goals, the waterworks used of automatic ice-making plant of the present invention are characterised in that and have quantitative cistern, hopper, outlet valve mechanism, groove valve system, valve operating gear and initial point testing agency.Quantitatively cistern is located at the ice maker container top of automatic ice-making plant, and the bottom has the delivery port that flows out water to this ice maker container; Hopper is located at the top of quantitative cistern, has the admission port of supplying water to this quantitative cistern; Outlet valve mechanism is used to open and close the delivery port of quantitative cistern; The groove valve system is used to open and close the admission port of hopper; Valve operating gear carries out following feedwater action repeatedly: promptly, from opening above-mentioned outlet valve mechanism and closing the 1st state of above-mentioned groove valve system, through the state of closing outlet valve mechanism, to the 2nd state of opening the groove valve system, inject a certain amount of water from hopper to quantitative cistern, then, through closing locked groove valve system state, get back to the 1st state of opening outlet valve mechanism, the water in the quantitative cistern is supplied with the feedwater action of ice maker container; Initial point testing agency is used to detect the initial point whether valve operating gear is positioned at the 1st state.
In the above-mentioned structure, preferably have the drive motors of driver's valve operating mechanism, initial point testing agency is made of magnet and Hall unit, and the moment close and output detection signal that detects magnet from Hall unit is counted, in the moment of having passed through setting-up time, make drive motors outage and stop.Also can make such structure: carry out in the feedwater course of action at valve operating gear, with the closed condition maintenance certain hour of above-mentioned 2 valve systems.
Be preferably made such structure: carry out in the feedwater course of action at valve operating gear, when loading onto again after hopper is removed, during the feedwater after this feedwater action is over is judged, even predicate not feedwater, it is bad also not report feedwater, and makes valve operating gear do the feedwater action again.In this case, preferably except do not report feedwater bad, preferably also do not carry out and unload ice action, make valve operating gear do the feedwater action more again.
In addition, also can make when surpass setting-up time the conduction time of drive motors, make the structure of drive motors outage.Be preferably made such structure: after connecting power supply, when detecting valve operating gear and not being positioned at initial point, be under the condition of level, drive above-mentioned drive motors, make valve operating gear get back to initial point at ice maker container.
According to said mechanism, when ice maker container fed water, the valve operating gear action was the 1st state from initial point, and when process was closed state to the 2 states of outlet valve mechanism, after outlet valve mechanism closed the delivery port of quantitative cistern, the groove valve system was opened.So, inject a certain amount of water to quantitative cistern from hopper.Then, through closing the state of locked groove valve system, when returning the 1st state, after the groove valve system is closed the admission port of hopper, become the state of the quantitative cistern delivery port of outlet valve mechanism opening from the 2nd state.So a certain amount of water that is stored in the quantitative cistern is supplied with ice maker container by delivery port.Therefore,, the groove valve system is being closed when ice maker container feeds water, so, can only the water in the quantitative cistern be supplied with ice maker container, improve precision to the ice maker container quantitative water supply.In addition, not when ice maker container feeds water, quantitatively cistern is empty, so be difficult for producing incrustation scale, mouldy etc.
The valve operating gear of waterworks is positioned at i.e. the 1st state standby of initial point feedwater.Under the 1st state, the groove valve system is being closed, and outlet valve mechanism is opening.Therefore, even the feedwater holding state for a long time, because outlet valve mechanism is opening, so the valve body of outlet valve mechanism and sealing gasket do not connect airtight, the performance of sealing gasket can not worsen, and discharge mechanism can not move malfunctioning.
In said structure, have the drive motors of driver's valve operating mechanism, simultaneously, initial point testing agency is made of magnet and Hall unit, the moment close and output detection signal that detects magnet from Hall unit is counted, passing through preset time constantly after, make the drive motors outage and stop, simple in structure.And, when motor begins to switch on, even motor has reverse slightly, the detection signal that Hall unit also can continue and output expression valve operating gear is positioned at initial point reliably.Like this, according to above-mentioned detection signal, can confirm that valve operating gear is positioned at initial point, so can prevent the misoperation of valve operating gear.
In addition, when adopting closed condition with 2 valve systems to keep the structure of the scheduled time, when checking the sealing property of 2 valve systems, can easily set the closed condition of 2 valve systems, institute is so that carry out above-mentioned inspection.
Carry out in the feedwater course of action at valve operating gear, hopper is loaded onto again after being taken off by the user sometimes.In this case, even the feedwater release is not fed water to ice maker container probably yet.Therefore, in the feedwater of feedwater after the release judged, predicate and do not feed water and to report feedwater bad.Specifically, expression is lighted to the feedwater signal lamp of hopper moisturizing.But, at this moment, owing to the user has loaded onto hopper again, so the user can suspect whether fault has taken place waterworks sometimes.
To this, adopt such structure to solve, promptly, carry out in the feedwater course of action at valve operating gear, when being loaded onto again after hopper is removed, during the feedwater after the feedwater release is judged, even predicate not feedwater, it is bad also not report feedwater, but makes valve operating gear do the feedwater action again.Like this, because it is bad not report feedwater, the user can not suspect that waterworks are out of order.And, owing to re-execute the feedwater action, so can feed water to ice maker container effectively.
Under the situation of said structure, except do not report feedwater bad, preferably also do not carry out and unload ice action, make valve operating gear do the feedwater action more again.Like this, do not unload the ice action owing to do not carry out, that is, ice maker container is counter-rotating up and down not, thus can prevent the generation of noise, and prolong the life-span of product.
Drive motors energising to the driver's valve operating mechanism, after beginning the feedwater action, when surpass the scheduled time conduction time of drive motors, owing to adopt the structure that makes the drive motors outage, so, drive motors can cut off the power supply drive motors when stopping the rotation because of certain reason, can prevent to burn out drive motors.
After connecting power supply, when valve operating gear is not positioned at initial point, thereafter, send the feedwater action command, when beginning the feedwater action, from the feedwater course of action, that is, from the on-off action process of 2 valve systems, the feedwater action is performed.At this moment, in ice maker container feedwater or only give the bad feedwater situation of low amounts of water can take place fully not.To this, adopt such structure to solve, that is, after connecting power supply, when detecting valve operating gear and be not positioned at initial point, be under the condition of level at ice maker container, drive above-mentioned drive motors, make valve operating gear get back to initial point.So when the feedwater action command sends (before the feedwater action beginning), valve operating gear is positioned at initial point effectively.Like this, can prevent the generation of bad feedwater.
Fig. 1 represents the 1st embodiment of the present invention, is the time diagram that concerns between the switching of expression operating axis position, outlet valve mechanism and groove valve system and the detection signal that Hall unit sends.
Fig. 2 is the skiagraph of refrigerator ice-making device.
Fig. 3 is the skiagraph of waterworks.
Fig. 4 is the figure that is equivalent to Fig. 3, and the state of outlet valve mechanism and groove valve system is closed in expression.
Fig. 5 is the figure that is equivalent to Fig. 3, represents the 2nd state.
Fig. 6 is the vertical view of valve drive.
Fig. 7 is the side view of valve drive.
Fig. 8 is the exploded perspective view of valve drive.
Fig. 9 is the oblique view of cam.
Figure 10 is a block diagram.
Figure 11 is the time diagram of expression automatic ice-making plant action.
Figure 12 be flow chart (one of).
Figure 13 is flow chart (two).
Figure 14 is the figure that is equivalent to Fig. 1, represents the 2nd embodiment of the present invention.
Figure 15 is the figure that is equivalent to Fig. 1, represents the 3rd embodiment of the present invention.
Among the figure, 1-refrigerator body, 2-refrigerating chamber, 3-ice-making compartment, 5-ice making tray (ice maker container), 6-driving mechanism, 8-ice making temperature sensor, 10-waterworks, 12-water receiving container, the quantitative cistern of 13-, 13a-delivery port, 13b-supporting arm, 14-outlet valve mechanism, 15-valve rod, 16-valve body, 17-top valve rod, 18-bottom valve rod, 20-compression helical spring, 21-compression helical spring, 22-rubber gasket, 26-hopper, 27-lid, the 27a-admission port, 28-groove valve system, 29-support, the 30-valve rod, 31-valve body, 32-compression helical spring, 33-groove switch, 35-valve drive, 36-shell, the 37-operating axis, 38-electrohydraulic valve actuator machine, 38a-rotating shaft, the 39-cam mechanism, 40-reduction gear, 41-cam, the 41a-cam surface, 41c-upper face, 41d-descends plane most, the 42-valve operating gear, 43-sealing gasket, 44-initial point testing agency, 45-magnet, 46-is ear IC suddenly, the 47-microcomputer.
Below, just be applicable to that with reference to accompanying drawing 1 to accompanying drawing 13 the 1st embodiment of band automatic ice-making plant refrigerator illustrates the present invention.Fig. 2 represents the schematic configuration of the automatic ice-making plant periphery of refrigerator body.Among Fig. 2, in refrigerator body 1, on space bar 4, have refrigerating chamber 2 and ice-making compartment 3.In refrigerator body 1, except refrigerating chamber 2 and ice-making compartment 3, also be provided with not shown refrigerating chamber and vegetable compartment etc.
In ice-making compartment 3, disposing ice maker container, for example plastic ice making tray 5.This ice making tray 5 can be rotated by driving mechanism 6 and support (spinning upside down).This driving mechanism 6 has ware and drives with motor 7 (see figure 10)s and deceleration device (not shown).Be stored in the cold air that water in the ice making tray 5 are supplied to ice-making compartment 3 and be cooled to ice.
In the exterior bottom of ice making tray 5, the temperature sensor that detects ice making tray 5 temperature is installed, i.e. ice making temperature sensor 8 (see figure 10)s.According to this ice making temperature detection signal with temperature sensor 8, detect water in the ice making tray 5 when having made ice, ice making tray 5 driven-mechanisms 6 spin upside down and reverse from level, unload the ice action after, return level.Below ice making tray 5, disposing storage ice container (not shown), be used to store the ice that falls when unloading ice.In this storage ice container, disposing storage ice test rod 9, whether be used to detect the ice of storing in the ice container full.
In the refrigerating chamber 2 above ice-making compartment 3, disposing waterworks 10 to ice making tray 5 feedwater.These waterworks 10 are described in detail in detail below.Bottom in refrigerating chamber 2 is provided with plastic mounting table 11, and water receiving container 12 forms as one with this mounting table 11.In the inside of this water receiving container 12, as shown in Figure 3, quantitatively cistern 13 is installed removably, this quantitative cistern 13 is as measuring container, for example is made of plastics and rounded.In this quantitative cistern 13, can store water a certain amount of, for example 105cc, the water yield of this 105cc is to supply with the most suitable water yield of ice making tray 5.Bottom center at quantitative cistern 13 forms mouth of a river 13a, and this delivery port 13a is opened and closed by outlet valve mechanism 14.
As shown in Figure 3, above-mentioned outlet valve mechanism 14 is made of valve rod 15 and valve body 16.Valve rod 15 can be bearing on the supporting arm 13b movingly up and down, and this supporting arm 13b inserts delivery port 13a and vertically is arranged at the inside bottom surface of quantitative cistern 13; Valve body 16 can be bearing on the valve rod 15 movingly up and down and open and close delivery port 13a from the outside of quantitative cistern 13.Valve rod 15 is to contact by barrier film 19 with bottom valve rod 18 on being located at valve body 16 and constitute by being located at top valve rod 17 on the quantitative cistern 13.Top valve rod 17 is arranged on the flange 17a of himself bottom and the compression helical spring between the supporting arm 13b 20 toward the belows pushing.The compression helical spring 21 that valve body 16 and bottom valve rod 18 are arranged between this valve body 16 and the bottom valve rod 18 lower end flange 18a promptly pushes toward the top toward closing direction.Edge of opening at delivery port 13a is installed with seal member, the sealing gasket 22 of for example annular soft rubber system.
As described later, be stored in the water in the quantitative cistern 13, when delivery port 3a opens, flow in the water receiving container 12.In the bottom of this water receiving container 12, form flow export 12a.This flow export 12a is connecting the upper end of feed pipe 23, and the bottom of this feed pipe 23 is facing to (see figure 2) in the ice making tray 5.Water receiving container 12 and feed pipe 23 have the function of giving aquaporin 24 of the water that flows out from quantitative cistern 13 being supplied with ice making tray 5.The flow export 12a of water receiving container 12 is by spherical float 25 (see figure 2) obturations.At this moment, in a single day water enter in the water receiving container 12, and float 25 floats, and water just can pass through flow export 12a.When not had water in the water receiving container 12, float 25 clogs flow export 12a, stops the cold air from ice-making compartment 3 to enter in the water receiving container 12.
On quantitative cistern 13, but be arranged on hopper 26 on the mounting table 11 with disposing clutch.As shown in Figure 3, below this hopper 26, the 26a of tube portion is being set highlightedly, on the 26a of this, but the lid 27 of the clutch that is being threaded.At about central part of this lid 27, form admission port 27a.This admission port 27a is opened and closed by groove valve system 28.This groove valve system 28 is made of valve rod 30 and valve body 31.Valve rod 30 can be bearing on the support 29 movingly up and down, and this support 29 is located at and covers 27 inner face (above among Fig. 3); Valve body 31 is installed in the bottom of valve rod 30, can open and close admission port 27a.Top and the compression helical spring between the support 29 32 that valve rod 30 is arranged on valve body 31 push valve body 31 frequent inaccessible admission port 27a toward the below.Hopper 26 except by admission port 27a be airtight the outside links to each other.
The diameter of the lid 27 of hopper 26 is greater than the quantitative top opening of cistern 13, relative with quantitative cistern 13 and and its between very little gap is arranged.Therefore, in order to reduce number of parts, lid 27 also is also used as the lid of quantitative cistern 13, and quantitatively the top opening tegmentum 27 of cistern 13 is firmly inaccessible.In lid 27 lower surface one side, form the 27b of tube portion that is slightly smaller than quantitative cistern 13 internal diameters, the 27b of this insert in the quantitative cistern 13 and and the inner peripheral surface of quantitative cistern 13 between the very little gap of formation.The valve rod 30 of groove valve system 28 is configured on the valve rod 15 same axis with outlet valve mechanism 14.
As shown in Figure 2, the right-hand position of the hopper 26 in refrigerating chamber 2 is provided with groove testing agency, for example the groove switch 33 that is made of microswitch.This groove switch 33 detects hopper 26 when being loaded on the mounting table 11 by bar 34, output detection signal.
As shown in Figure 2, in exterior bottom one side of water receiving container 12, disposing and driving the valve drive 35 that outlet valve mechanism 14 and groove valve system 28 open and close.This valve drive 35 is housed in the recess 4a chimericly, and this recess 4a is formed on the space bar 4 of refrigerating chamber 2 bottoms.This valve drive 35 also is fixed on by for example being threaded on the outstanding installation protuberance 11a that is arranged at below the mounting table 11.
To shown in Figure 8, valve drive 35 has operating axis 37, electrohydraulic valve actuator machine 38 and cam mechanism 39 as Fig. 6.Operating axis 37 can support on shell 36 as functional unit movingly up and down; Electrohydraulic valve actuator machine 38 for example is made of the AC synchronous motor as drive source; Cam mechanism 39 is converted to moving up and down of operating axis 37 as rotation-reciprocating motion switching mechanism with rotatablely moving of electrohydraulic valve actuator machine 38.Above-mentioned electrohydraulic valve actuator machine 38 is the general motor that uses as the timing motor for example for 100V exchanges electrically driven (operated) synchronous motor.Can only unidirectional rotation drive.
As Fig. 6 and shown in Figure 8, cam mechanism 39 is made of reduction gear 40 and cam 41.Reduction gear 40 slows down the rotation of the rotating shaft 38a of electrohydraulic valve actuator machine 38; Cam 41 drives rotation by reduction gear 40, and integral body roughly is circular plate type.As shown in Figure 9, on the upper surface peripheral part of this cam 41, form concavo-convex cam surface 41a, in the lower end of peripheral part, the gear part 41b of the gears engaged of formation and reduction gear 40.The lower end of operating axis 37 contacts with the cam surface 41a of cam 41, and cam 41 revolves and turns around, this operating axis 37 (see figure 7) that makes a round trip along the vertical direction.
In this structure, when the lower end of operating axis 37 contacted with the upper face 41c of cam surface 41a, operating axis 37 was positioned at upper limit position; When the lower end of operating axis 37 and cam surface 41a descend plane 41d to contact most the time, operating axis 37 is positioned at the lower position.At this moment, operating axis 37 and cam mechanism 39 constitute valve operating gear 42.As shown in Figure 3, operating axis 37 pierces into portion's 36a interior support and and stretch out upward, and the 36a of tube portion gives prominence to the upper surface that is arranged on shell 36.
As shown in Figure 3, operating axis 37 passes the hole 12b of water receiving container 12 bottoms and stretches out upward.This hole 12b is by preventing that water from flowing out sealing gasket 43 lockings of usefulness, and operating axis 37 is along with sealing gasket 43 is flexible and moving up and down.The bottom valve rod 18 of the valve rod 15 of outlet valve mechanism 14 contacts by the upper end of sealing gasket 43 with operating axis 37.Before feedwater action beginning, operating axis 37 is in the 1st state, promptly stops at the lower position of knee-action scope, just is positioned at initial point (being described in more detail in the back).At this moment, the elastic force that the valve body 16 of outlet valve mechanism 14 is compressed helical spring 20 is down passed and is opened delivery port 13a, simultaneously, the valve body 31 of groove valve system 28 under the elastic force effect of compression helical spring 32, the admission port 27a of inaccessible hopper 26.
Action to ice making tray 5 feedwater is whenever to turn around by above-mentioned cam 41 to carry out once.This cam 41 turns around, and operating axis 37 is done a reciprocating motion, and outlet valve mechanism 14 and groove valve system 28 open and close a circulation.At this moment, as mentioned above, the 1st state (valve original state) before the feedwater action is because operating axis 37 stops at the lower position of knee-action scope, so of this operating axis 37 back and forth is from its lower position.Along with the rotation of cam 41, operating axis 37 rises to upper limit position from the lower position through the centre position earlier, drops to the lower position through the centre position and stops from upper limit position again.
Therefore, when operating axis 37 returns lower position (initial point), for the electrohydraulic valve actuator machine 38 of switching on to ice making tray 5 feedwater must be de-energized.For control valve drive motors 38 in this wise, as shown in Figure 6, be provided with and be used to detect the initial point testing agency 44 that cam 41 is positioned at initial point (initial position).This initial point testing agency 44 is made of magnet 45 that is installed in the cam peripheral part and the IC46 of ear suddenly that is located on the shell 36.This suddenly ear IC46 have not shown Hall unit.Shown in Fig. 1 (b), when cam 41 was positioned at about origin position, magnet 45 was close, and ear IC46 exports for example low level detection signal suddenly, time output high level detection signal in addition.
In Figure 10 of expression electrical structure, as for example microcomputer 47 of control device, have the function of ice making, feedwater running and the refrigerator running of control automatic ice-making plant, storing these control programs.This microcomputer 47 also has the function as valve control device.This microcomputer 47 receive from the sense switch signal of storage ice sense switch 48, from the sense switch signal of ware transversal switch 49, from ice making with the sense switch signal of temperature sensor 8, from the sense switch signal of door switch 50, from the sense switch signal of groove switch 33 with from the detection signal of the IC46 of ear suddenly of initial point testing agency 44.Above-mentioned storage ice switch 48 is to ice in the storage ice container by detecting whether full storage ice test rod 9 moves; Ware transversal switch 49 is used to detect whether ice making tray 5 is level; Door switch 50 is used to detect the open and-shut mode of the door of ice-making compartment 3; Groove switch 33 is used to detect having or not of hopper 26.
The ware of the drive circuit 51 pair driving mechanisms 6 of microcomputer 47 by having switch element such as transistor drives with motor 7 and carries out power on/off control (just change, reverse and stop to control), the feedwater signal lamp 52 that for example is made of light emitting diode of reporting feedwater unusual (needing reporting to hopper 26 feedwater) usefulness is lighted control, electrohydraulic valve actuator machine 38 is carried out power on/off control by drive circuit 53.In this case, drive circuit 53 has relay, three terminal bidirectional switch etc.100V alternating voltage supply valve drive motors 38 from AC power 54.From dc source (not shown) for example+the 12V DC voltage supplies with ware and drives with motor 7.
Microcomputer 47 receives from the freezer temperature sensor that detects freezer temperature and detects the temperature detection signal of the refrigerator temperature sensor of refrigerating chamber 2 temperature, and the compressor of the part that constitutes the refrigerating chamber freeze cycle is carried out power on/off control; Also the fan electromotor to fan assembly carries out power on/off control, and this fan assembly is used for the cold air that cooler takes place is fed to each chamber (ice-making compartment 3, refrigerating chamber 2, refrigerating chamber, vegetable compartment etc.).
Below, the action of said structure is described with reference to Fig. 1, Figure 11, Figure 12 and Figure 13.
Earlier illustrate that with reference to Fig. 1 each on-off action of outlet valve mechanism 14 and groove valve system 28 and the above-below direction of the operating axis 37 of valve drive 35 move the relation of (being that cam 41 rotates).Among Fig. 1, represent the lower position of operating axis 37 to represent the centre position, represent upper limit position with PU with PC with PL.When cam 41 was positioned at the 1st (standby) state of initial point, operating axis 37 was positioned at lower position PL.As shown in Figure 3, the valve body 16 of outlet valve mechanism 14 is opened delivery port 13a, and simultaneously, the valve body 31 of groove valve system 28 is closed admission port 27a.At this moment, shown in Fig. 1 (b), be low level from the detection signal voltage level of the IC46 of ear suddenly of initial point testing agency 44 output.
Then, in case 38 energisings of electrohydraulic valve actuator machine, cam 41 begins rotation, and operating axis 37 just begins to rise from lower position PL.So the valve rod 15 of outlet valve mechanism 14 is operated axle 37 and up pushes away.At this moment, while valve rod 15 pushes compression helical spring 20 is up pushed away.Behind operating axis 37 and the valve rod 15 rising scheduled volumes, because compression helical spring 21 is compressed, its elastic force presses against the bottom of quantitative cistern 13 with valve body 16, closes its delivery port 13a.This position of closing delivery port 13a is at the position PC1 of centre position PC below slightly.At this moment, shown in Fig. 1 (b), be high level from the voltage level of the detection signal of the output of ear IC46 suddenly.
Cam 41 rotates again, operating axis 37 rises to centre position PC slightly during the position PC2 of top, and the valve rod 15 of outlet valve mechanism 14 contacts with the valve rod 30 of groove valve system 28, revolts the elastic force of compression helical spring 32, valve rod 30 is pushed to, and the valve body 31 of groove valve system 28 is opened admission port 27a.Afterwards, operating axis 37 arrives upper limit position PU, and during being positioned at this upper limit position PU, admission port 27a is opening.Here, while since the valve rod 15 of outlet valve mechanism 14 push compression helical spring 20,21 and be brought to, so the valve body 16 of outlet valve mechanism 14 is keeping closing the state of delivery port 13a.Therefore, valve rod 15 rises with respect to valve body 16 slips of halted state.That is, operating axis 37 is positioned at the state of upper limit position PU, and the 2nd state that has only groove valve system 28 to be to open.
Then, rotation corresponding to cam 41, to the stroke that lower position PL descends, the elastic force that the valve rod 15,30 of outlet valve mechanism 14 and groove valve system 28 is compressed helical spring 20,21,32 down pushes away operating axis 37 from upper limit position PU, and the valve body 31 of groove valve system 28 is closed admission port 27a earlier.This position of closing admission port 27a is an operating axis 37 at the position PC2 of centre position PC above slightly.At this moment,,, the valve body 16 of outlet valve mechanism 14 pushes away toward the top because being compressed helical spring 21 although valve rod 15 descends, so, be urged in the bottom of quantitative cistern 13, keeping closing the state of delivery port 13a.
Then, the valve rod 15 of outlet valve mechanism 14 leaves the valve rod 30 of groove valve system 28, this valve rod 15 further descends, compression helical spring 21 stretches, lost the elastic force that valve body 16 is pushed away upward, so valve body 16 moves toward the below integratedly with valve rod 15, leave the bottom of quantitative cistern 13 and open its delivery port mouth 13a.Opening the position of this delivery port 13a, is the PC1 of lower position slightly of centre position PC.Afterwards, operating axis 37 arrives original lower position PL, and during being positioned at this lower position, delivery port 13a is opening.When getting back to initial point (original state) when operating axis 37 is got back to original lower position PL (getting back to the 1st state), cam 41 turns around, shown in Fig. 1 (b), the detection signal voltage level of ear IC46 output is a low level suddenly.Thereby, detect and return initial point, it (specifically, is to become low level from detection signal to count constantly that electrohydraulic valve actuator machine 38 stops with regard to being de-energized, pass through scheduled time t, for example after 1.5 seconds, cut off the power supply), the knee-action of the rotation of cam 41 and operating axis 37 is stopped.
In this case, carry out the above-mentioned feedwater action required time of a circulation, promptly, when the frequency of AC power is 50Hz, be set at about 75.9 seconds, when the frequency of AC power is 60Hz, be set at about 63.3 seconds to the time ta0 of electrohydraulic valve actuator machine 38 energisings.Shown in Fig. 1 (a), in the feedwater action of an above-mentioned circulation, operating axis 37 is positioned at the time ta1 of lower position PL, when the frequency of AC power is 50Hz, is about 25.7 seconds, when the frequency of AC power is 60Hz, is about 21.4 seconds.Operating axis 37 rises to upper limit position PU required time ta2 from lower position PL, when the frequency of AC power is 50Hz, is about 23.4 seconds, when the frequency of AC power is 60Hz, is about 19.5 seconds.Operating axis 37 is positioned at the time ta3 of upper limit position PU, when the frequency of AC power is 50Hz, is about 10.4 seconds, when the frequency of AC power is 60Hz, is about 8.7 seconds.The upper limit position PU of operating axis 37 is set in the position than the high approximately 13.3mm of lower position PL.
Figure 12 and flow chart shown in Figure 13, the control content of ice making action of the automatic ice-making plant in the control program that expression microcomputer 47 is stored (unloading the ice action) and feedwater action.Below, according to above-mentioned each action of this flowchart text.At first, the user places refrigerator and connect power line, connects power supply (energising) (referring to the step S1 among Figure 12).So microcomputer 47 is to the compressor energising (step S2) of refrigerator, the refrigeration in each chamber of refrigerator (refrigerating chamber 2, refrigerating chamber, ice-making compartment 3 etc.) begins.
Then, microcomputer 47 judges according to the detection signal of the ware transversal switch 49 of automatic ice-making plant whether ice making tray 5 is level (step S3).If ice making tray 5 is not a level, then enter " NO " at step S3, energising also drives the ware driving with motor 7, makes ice making tray 5 rotations and gets back to level (step S4).Thereby, in step S3, enter " YES ".Then, judge that whether the cam 41 of waterworks 10 and operating axis 37 are at origin position (step S5).At this moment, judge whether the detection signal of ear IC46 is low level suddenly.If cam 41 and operating axis 37 then enter " NO " at step S5 not at origin position, make cam 41 and operating axis 37 return the processing (step S6) of initial point.
In this case, specifically, be exactly energising and driver's valve drive motors 38, make cam 41 rotations.Detection signal up to ear IC46 output suddenly is a low level.When the signal of the output of ear IC46 suddenly is low level, from this moment,, makes 38 outages of electrohydraulic valve actuator machine and stop through about 1.5 seconds (surpassing the scheduled time).Initial actuating control when in this case, the processing of above-mentioned steps S1~S6 is power connection.Even before power connection cam 41 and operating axis 37 because of certain reason not at origin position, because the control of this initial actuating can make cam and operating axis 37 be positioned at initial point effectively.
Then, judge whether the ice making in the ice making tray 5 finishes (step S7).At this moment, whether the ice making of the temperature of judgement detection ice making tray 5 reaches the finishing ice-making temperature (specifically with the detected temperatures of temperature sensor 8, judge whether above-mentioned detected temperatures is below-12.5 ℃, judge perhaps whether above-mentioned detected temperatures continues maintenances in 2 hours state below-9.5 ℃).Shown in Figure 11 (a), water in the ice making tray 5 is finishing ice-making, ice making is (or being state continuance below-9.5 2 hours) below-12.5 ℃ with the detected temperatures of temperature sensor 8, at this moment t0, in step S7, enter " YES ", move to next step, judge whether to carry out to unload and ice action (step S8).
At this step S8, judge whether to ice fullly in the storage ice container, if ice is full, in step S8, enter " YES ", do not unload the ice action and standby.If in the storage ice container ice less than, then in step S8, enter " NO ", begin to unload ice action (step S9).Specifically, shown in Figure 11 (b), use motor 7 positive veers energisings to drive, ice making tray 5 is spun upside down and reverses, ice is drawn off from ice making tray 5 to the ware driving of driving mechanism 6.After ice making tray 5 arrives upturned position, drive with the energising of motor reverse directions, make ice making tray 5 return original horizontal level toward the rightabout rotation to ware.
Then, detection signal according to ware transversal switch 49, whether unload the ice action finishes (promptly, whether ice making tray 5 has got back to level) (step S10), as Figure 11 (b) and (c), unload ice action when having finished (having got back to horizontal level) at moment t1, at this constantly, in step S10, enter " YES ", ware is driven with motor 7 outages stop, stopping to unload ice action (step S11).Then, carry out the action of feedwater in ice making tray 5 by waterworks 10.
Specifically, at first, microcomputer 47 judges that whether cam 41 and operating axis 37 (valve operating gear 42) are at origin position (the step S12 among Figure 13).If at origin position, then in step 12, enter " YES ", make the timers of installing in the microcomputer 47 action (step S13) that picks up counting, begin simultaneously electrohydraulic valve actuator machine 38 switch on (step S14).Above-mentioned timer is to begin the timer that counting electrohydraulic valve actuator machine is used for 38 conduction times from feedwater action, and when picking up counting action, elder generation is timing time zero setting, and action again picks up counting.
Then, judge whether hopper 26 installs (step S15).Suppose that hopper 26 installed, then in step S15, enter " YES ", judge that whether cam 41 and operating axis 37 are at origin position (step S16).At this moment, because the energising of electrohydraulic valve actuator machine 38, cam 41 begins rotation, so the no longer close ear IC46 (no longer at initial point) suddenly of magnet, the voltage level of the detection signal of ear IC46 output is a high level suddenly, enters in step S16 " NO ".Whether the timing time of judging timer again is for example (step S17) more than 80 seconds, if this timing time less than 80 seconds, then enters in step S17 " NO ".That is, under the state that hopper 26 is installed with, cam 41 turns around up to getting back to initial point, perhaps, in step S15, enter " YES ", in step S16, enter " NO ", in step S17, enter " NO ", carry out circular treatment repeatedly, till the timing time of timer arrives 80 seconds.
Electrohydraulic valve actuator machine 38 begins energising, and when cam 41 began to rotate, operating axis 37 rose to upper limit position PU from lower position PL through centre position PC earlier.So as shown in Figure 4, after the valve body 16 of outlet valve mechanism 14 was closed the delivery port 13a of quantitative cistern 13, as shown in Figure 5, under these outlet valve mechanism 14 closing state, groove valve system 28 was opened the admission port 27a of hopper 26.Thereby the water in the hopper 26 flows in the quantitative cistern 13 by admission port 27a, and a certain amount of water (for example 105cc) is stored in this quantitative cistern 13.Specifically, along with water flows out from admission port 27a, quantitatively the water levels in the cistern 13 rise, and when promptly the lower ending opening of the 27b of tube portion is blocked by the water surface in the quantitative cistern 13 in the bottom of admission port 27a, no longer flow out water from admission port 27a.At this moment, because the 27b of tube portion often is bearing in the certain altitude position, so, in quantitative cistern 13, always keep certain water level, in other words, always storing a certain amount of water.
As mentioned above, quantitatively always storing a certain amount of water in the cistern 13, simultaneously, after water was full of in the admission port 27a downside of hopper 26, operating axis 37 moved to lower position PL through centre position PC from upper limit position PU.At this moment, valve drives with 41 rotations of motor 38 driving cams, makes the time of the admission port 27a that opens hopper 26, can satisfy certain water gaging and deposit the required time of quantitative cistern 13 in.Along with the decline of operating axis 37, the valve body 31 of groove valve system 28 is closed the feedwater 27a of hopper 26, and then, the valve body 16 of outlet valve mechanism 14 leaves the bottom of quantitative cistern 13, opens its delivery port 13a.So as shown in Figure 3, the water that is stored in the quantitative cistern 13 flows to water receiving container 12 with the interior water of the admission port 27a downside that is present in hopper 26 from delivery port 13a, supplies with in the ice making trays 5 by feed pipe 23 from flow export 12a again.At this moment, as shown in Figure 1, when operating axis 37 dropped to lower position PL, outlet valve mechanism 14 opened delivery port 13a fully.
Cam 41 rotates again, when cam 41 is got back to initial point (turning around), and magnet 45 close ear IC46 suddenly.Thereby the voltage level of the detection signal of ear IC46 output is a low level suddenly, and (that is, being positioned at initial point) enters in step S16 " YES ".Therefore, as long as motor 38 and cam 41 regular events just do not enter in step S17 " YES ".
After in step S16, entering " YES ", then, shown in Fig. 1 (b), be that low level is counted constantly, during through setting-up time t, valve driven with motor 38 cut off the power supply and stop (step S18, S19) from the detection signal of ear IC46 output suddenly.This setting-up time t surpasses the scheduled time, in the present embodiment, for example is set at 1.5 seconds.Above-mentioned surpass the scheduled time and handle (step S18), is the processing that the mid portion for the low level interval that initial point is placed on detection signal carries out.Because above-mentioned valve drives the outage with motor 38, cam 41 and operating axis 37 are got back to initial point and are stopped, and above-mentioned delivery port 13a becomes closed condition.Then, wait is judged the time (for example 5.5 minutes) (step S20) of using through predetermined feedwater.Feed ice making tray 5 interior water the temperature of ice making tray 5 is risen, this feedwater judges with the time to be exactly the time of temperature (the ice making detected temperatures of the temperature sensor 8) rising of wait ice making tray 5.
Then, passed through the above-mentioned time (5.5 minutes) after, judge whether given water (step S21) in the ice making tray 5.Specifically, microcomputer 47 judges whether ice making is more than-9,5 ℃ with the detected temperatures of temperature sensor 8.If feedwater in ice making tray 5, ice making is more than-9.5 ℃ with the detected temperatures of temperature sensor 8, then enters in step S21 " YES ", finishes the feedwater action.Then, the water that supplies in the ice making tray 5 is cooled off by the cold air in the ice-making compartment 3, carries out the ice making action.
According to the detected temperatures of ice making, judge whether to reach the finishing ice-making temperature again with temperature sensor 8.Specifically, judge whether above-mentioned detected temperatures is (or whether the state below-9.5 ℃ has kept 2 hours) (step S22) below-12.5 ℃.If finishing ice-making then enters in step S22 " YES ", return step S8, with similarly aforementioned, judge whether that the ice that unloads that will carry out ice making tray 5 moves.Unload the ice action if carry out, unload ice action and feedwater action more repeatedly.
In above-mentioned steps S21, if ice making is not more than-9.5 ℃ with the detected temperatures of temperature sensor 8, then do not predicate feedwater in ice making tray 5, then in step S21, enter " NO ", make feedwater signal lamp (feedwater light emitting diode) 52 light (step S23).By lighting of this feedwater signal lamp 52, the user just knows that this is to hopper 26 feedwater.
So the user takes off hopper 26 and the water of packing into, after again the hopper 26 of adorning water being installed, then in step S24, enter " YES ", the feedwater signal lamp extinguishes back (step S25), gets back to abovementioned steps S13, carries out the feedwater action again.
In the feedwater action of waterworks 10, be in the rotation of cam 41, when taking place, electrohydraulic valve actuator machine 38 is lockable, cam 41 can not rotate or ear IC46 malfunctioning (or magnet 45 comes off) and can not detect faults such as initial point time the suddenly, because the gate time of the timer of microcomputer 47 surpasses 80 seconds, then enters in step S17 " YES ".With electrohydraulic valve actuator machine 38 outage (step S26), simultaneously, the alarm or make of ringing is reported light emitting diode that fault uses and is lighted and report fault (step S27), stops the feedwater action.When reporting fault, should ask the repairman to repair.
Below, illustrate in the feedwater action, be in the energising driving of electrohydraulic valve actuator machine 38, the action (control) after hopper 26 is removed.At this moment, in step S15, enter " NO ", judge whether cam 41 gets back to initial point (whether making a circle) (step S28).When cam 41 is not got back to initial point, if the timing time of timer that predicates microcomputer 47 in step S28 less than 80 seconds then in step S29 was " NO ".That is, get back to step S28.
At this moment, when 38 energisings of electrohydraulic valve actuator machine, when cam 41 turned around, correspondingly, operating axis 37 moved along the vertical direction, and outlet valve mechanism 14 makes on-off action (if hopper 26 is loaded onto again, the groove valve system is also made on-off action).When cam 41 was got back to initial point, magnet 45 was near ear IC46 suddenly, became low level from the voltage level of the detection signal of ear IC46 output suddenly, entered in step S28 " YES ".Then, shown in Fig. 1 (b), become low level from the detection signal of the output of ear IC46 suddenly and count constantly,, valve is driven with motor 38 cut off the power supply and stop (step S30, S31) through setting-up time t (surpass the scheduled time handle).Wait for again through predetermined feedwater and judging,, judge whether in ice making tray 5, to supply water (step S33) according to the detected temperatures of ice making with temperature sensor 8 with time (for example 5.5 minutes) back (step S32).
If ice making is more than-9.5 ℃ with the detected temperatures of temperature sensor 8, then predicating feedwater finishes, in step S33, enter " YES ", finish the feedwater action, if hopper 26 is removed, there is not water in the ice making tray 5, ice making can not be more than-9.5 ℃ with the detected temperatures of temperature sensor 8, so, in step S33, predicate " NO ", return step S12, carry out the feedwater action again.After in step S15, predicating " YES ", in the feedwater course of action, under the situation that hopper 26 has been removed, when not feeding water in the ice making tray 5,, conclude that feedwater does not finish at step S21.Feedwater signal lamp 52 is lighted, and as described later, when hopper 26 was loaded onto again again, feedwater signal lamp 52 extinguished.
In feedwater action, be in the rotary course of cam 41, when taking place that electrohydraulic valve actuator machine 38 is lockable, cam 41 can not rotate or ear IC46 malfunctioning (or magnet 45 comes off) and can not detect fault such as initial point time the suddenly, because the timing time of the timer of microcomputer 47 has surpassed 80 seconds, enters in step S29 " YES ".When making electrohydraulic valve actuator machine 38 outage (step S34), the alarm or make of ringing is reported the light emitting diode that fault uses and is lighted, and reports the generation (step S35) of fault, stops the feedwater action.
In above-mentioned waterworks 10, in the zero hour of feedwater action, cam 41 and operating axis 37 because of certain reason not when the origin position, in step S12, enter " NO ", make cam 41 and operating axis 37 be positioned at the processing of initial point.Specifically, microcomputer 47 makes the timer action (step S36) that picks up counting, and simultaneously, beginning is to 38 energisings (step S37) of electrohydraulic valve actuator machine.Judge then whether cam 41 and operating axis 37 have got back to initial point (whether making a circle) (step S28).If cam 41 is not got back to initial point, then in step 28, enter " NO ".If the timing time of the timer of microcomputer 47 was less than 80 seconds, then step S29 enters " NO ".Promptly, cam 41 almost revolve turn around get back to initial point before, or before the timing time of timer reached 80 seconds, carry out step S28 repeatedly and enter " NO ", step S29 enters the circular treatment of " NO ", revolve to turn around up to cam 41 and get back to initial point, or till the timing time of timer reached 80 seconds.Similarly carry out in this later processing and aforementioned processing.
If adopt the present embodiment that constitutes like this, then because only a certain amount of water (105cc) that is stored in the quantitative cistern 13 that comprises the water in the 27a downside of admission port is supplied with ice making tray 5, simultaneously, to ice making tray 5 feedwater the time, close locked groove valve system 28, so, to ice making tray 5 feedwater the time, the water in quantitative cistern 13, other water can not flow into, always a certain amount of water ice making tray 5 can be supplied with, high-precision quantitative water supply can be carried out.And quantitatively cistern 13 interior water fall in the feed pipe 24 naturally, supply with ice making tray 5, thus different with the way of supplying water of feed pump, big noise does not take place in feedwater, can realize quiet feedwater.At this moment,, compare as the structure of the drive source of valve drive 35, can accomplish quiet feedwater more with adopting solenoid because the drive source of valve drive 35 is to adopt motor (electrohydraulic valve actuator machine 38).
In the foregoing description, quantitatively cistern 13 is often empty, only in just water storage in the short time of ice making tray 5 feedwater, so, with often the situation of water storage is different in the quantitative cistern 13.Like this, quantitatively be not easy scaling and mouldy in the cistern 13.And the smell of the food in the refrigerating chamber 2 can not absorbed by the water in the quantitative cistern 13.Because in ice making tray 5, finishing ice-making needs 2~5 hours, so under the situation of quantitatively cistern 13 frequent water storages, the smell of the food in the refrigerating chamber 2 can be absorbed by water.In addition, in the foregoing description, because quantitatively cistern 13 is removably, because of long-term use when dirty, can take off from water receiving container 12, method such as wash with water is simply cleaned.
In the foregoing description, the valve operating gear 42 of waterworks 10 is to be positioned at i.e. the 1st state standby of initial point feedwater.In the 1st state, be lower position PL because cam 41 and operating axis 37 are positioned at initial point, so groove valve system 28 is being closed, outlet valve mechanism 14 is opening.Therefore, even standby feedwater state continuance is long-time, because outlet valve mechanism 14 is opening, the valve body 16 and the rubber gasket 22 of outlet valve mechanism 14 do not connect airtight, the sealing property of sealing gasket 22 can not worsen, and can prevent conscientiously that the action of outlet valve mechanism 14 is malfunctioning.
In the groove valve system 28 of the valve operating gear 42 of the foregoing description, the power of opening this valve body 31 is that the last thrust of operating axis 37 produces, so be sizable power.Therefore, even the closed condition of groove valve system 28 for a long time, can open valve body 31, valve body 31 can not cling with delivery port 27a yet.
In the above-described embodiments, by the cam 41 and the operating axis 37 of electrohydraulic valve actuator machine 38 driver's valve operating mechanisms 42; The initial point testing agency 44 of detecting cam 41 and operating axis 37 initial points is made of the magnet 45 and the Huo Er IC46 that are installed on the cam; Suddenly ear IC46 detect magnet 45 near and output detection signal (low level signal), count when having passed through the scheduled time (1.5 seconds) from this output time, make electrohydraulic valve actuator machine 38 outage and stop.Therefore, the simple structure of waterworks 10.In addition, when electrohydraulic valve actuator machine 38 began to switch on, even this motor 38 has reverse slightly, ear IC46 also can continue the detection signal (low level signal) that output expression cam 41 and operating axis 37 (valve operating gear 42) are positioned at initial point suddenly.Like this, according to the detection signal of ear IC46 suddenly, can confirm that cam 41 and operating axis 37 (valve operating gear 42) are positioned at initial point, therefore, can prevent the misoperation of valve operating system 42 and waterworks 10.
Carry out (that is, during the energising of electrohydraulic valve actuator machine 38 drives) in the feedwater action at valve operating gear 42, hopper 26 is loaded onto after being taken off by the user again sometimes, at this moment, valve drive 35 actions, the feedwater action looks it is to be through with, but in fact probably not to ice making tray 5 feedwater.Therefore, in the feedwater of feedwater after the release judged, predicate and do not feed water and to report feedwater bad.Specifically, feedwater signal lamp 52 is lighted, and indication should be to hopper 26 moisturizings (step S23).But, in the foregoing description, carry out in the feedwater action (promptly at valve operating gear 42, during the energising of electrohydraulic valve actuator machine 38 drives), when loading onto again after hopper 26 is removed, during the feedwater after the feedwater release is judged (step S21), even predicate not feedwater, according to the judgement of step S24, it is bad also not report feedwater.Like this, because it is bad not report feedwater, the user just can not think it is that fault has taken place waterworks by mistake.Under the state that hopper 26 has been loaded onto again, carry out the feedwater action again, can confirm to ice making tray 5 feedwater, and, through after the judgement of finishing ice-making, unload to ice and move.
Therefore, in the above-described embodiments, when wrong report feedwater is bad or ice making when not finishing, what ice making tray 5 is done spin upside down unloads the ice action.Can prevent the generation of noise, and prolong the life-span of product.
In the above-described embodiments, after 38 energisings of electrohydraulic valve actuator machine and the action that begins to feed water to driver's valve operating mechanism 42, the conduction time of electrohydraulic valve actuator machine 38 is when surpassing the scheduled time (for example 80 seconds), owing to can make 38 outages of electrohydraulic valve actuator machine, so, the electrohydraulic valve actuator machine is during because of certain reason stall, can make the electrohydraulic valve actuator tester in power-down state and prevents that electrohydraulic valve actuator machine 38 from burning out.
When power connection, if valve operating gear 38 is not positioned at initial point, after, when sending the feedwater instruction and beginning the feedwater action, in the feedwater course of action, that is, from the on-off action process of 2 valve systems 14,28, carry out the feedwater action.At this moment, can produce fully not in ice making tray 5 feedwater or only give feedwater unfavorable condition such as a spot of water.To this, when power connection, when detecting valve operating gear 42 not at initial point, at ice making tray 5 is under the condition of level, energising driver's valve drive motors 38 makes valve operating gear 42 get back to initial point, so, when the feedwater action command sends (before the feedwater action beginning), valve operating gear 42 is positioned at initial point effectively.Like this, can prevent the feedwater condition of poor.
Figure 14 represents the 2nd embodiment of the present invention.The difference of it and the 1st embodiment only is described here.In the 2nd embodiment, between lower position PL and upper limit position PU, do in the knee-action of a circulation at the operating axis 37 that makes valve operating gear 42, as shown in figure 14, when upper limit position PU drops to lower position PL, make it only be arranged in the centre position PC on its way at operating axis 37 at preset time ta5.When operating axis was positioned at the centre position, 2 valve systems 14,28 all were closed conditions.Above-mentioned time ta5 when ac power frequency is 50Hz, for example is set at 7.1 seconds, when ac power frequency is 60Hz, for example is set at 5.9 seconds.
In the 2nd embodiment, as mentioned above, for make operating axis 37 at the fixed time ta5 be positioned at centre position PC, on the cam surface 41a of cam 41, form smooth median surface (not shown).On the middle part, inclined-plane (slope) of descending most plane 41d to descend, its length is corresponding with above-mentioned scheduled time ta5 at upper face 41a for this median surface.
At this moment, as shown in figure 14, valve operating gear 42 is carried out the feedwater action required time ta0 of a circulation, when the frequency of AC power is 50Hz, for example is set at 75.9 seconds, when ac power frequency is 60Hz, for example is set at 63.3 seconds.Time ta1 when operating axis 37 is positioned at lower position PL when the frequency of AC power is 50Hz, is about 18.6 seconds, when ac power frequency is 60Hz, is about 15.5 seconds.Operating axis 37 rises to upper limit position PU required time ta2 from lower position PL, when the frequency of AC power is 50Hz, is about 23.4 seconds, when ac power frequency is 60Hz, is about 19.5 seconds.Operating axis 37 is positioned at the time ta3 of upper limit position PU, when the frequency of AC power is 50Hz, is about 10.4 seconds, when ac power frequency is 60Hz, is about 8.7 seconds.
Operating axis 37 drops to centre position PC required time ta4 from upper limit position PU, when the frequency of AC power is 50Hz, is about 8.4 seconds, when ac power frequency is 60Hz, is about 7.0 seconds.Operating axis 37 drops to lower position PL required time ta6 from middle position PC, when the frequency of AC power is 50Hz, is about 8.0 seconds, when ac power frequency is 60Hz, is about 6.7 seconds.In addition, the upper limit position PU of operating axis 37 is than the high approximately 13.3mm of lower position PL.The centre position PC of operating axis 37 is than the high approximately 6.5mm of lower position PL.Part except that above-mentioned is all identical with the 1st embodiment.
Therefore, above-mentioned the 2nd embodiment also can obtain the effect same with the 1st embodiment.Particularly in the 2nd embodiment, carry out in the feedwater course of action at valve operating gear 42, the closed condition of 2 valve systems 14,28 is only kept scheduled time ta5, so, in the inspection line of making factory etc. during the sealing property of 2 valve systems 14,28 of inspection, with before the median surface (centre position PC) of the cam surface 41a of cam 41 contacts, cam 41 rotations are got final product in the lower end of operating axis 37.At this moment, the time ta5 that is positioned at centre position PC is about 7.1 seconds or 5.9 seconds, so, even the detection performance of ear IC46 has dispersiveness (the most about 4 seconds of error) suddenly, also can make operating axis 37 be positioned at the centre position conscientiously simply.Therefore, can easily all be set in closed condition to 2 valve operating gears 14,28, be convenient to above-mentioned inspection.
Figure 15 represents the 3rd embodiment of the present invention, and the difference of it and the 2nd embodiment only is described here.In the 3rd embodiment, as shown in figure 15, operating axis 37 from lower position PL when upper limit position PU rises, make its only preset time ta7 be arranged in its way centre position PC.This scheduled time ta7 when the frequency of AC power is 50Hz, for example is set at 7.1 seconds, when ac power frequency is 60Hz, for example is set at 5.9 seconds.In addition, in the 3rd embodiment, as mentioned above, for make operating axis 37 at the fixed time ta7 be positioned at centre position PC, on the cam surface 41a of cam 41, form smooth median surface (not shown).This median surface is descending plane 41d to the middle part, inclined-plane (slope) that upper face 41c rises most, and its length is corresponding with above-mentioned scheduled time ta7.
Operating axis 37 rises to centre position PC required time ta8 from lower position PL, when the frequency of AC power is 50Hz, is about 11.4 seconds, when ac power frequency is 60Hz, is about 9.5 seconds.Operating axis 37 rises to upper limit position PU required time ta9 from middle position PC, when the frequency of AC power is 50Hz, is about 12.0 seconds, when ac power frequency is 60Hz, is about 10.0 seconds.Except above-mentioned part, all the other structures are identical with the 2nd embodiment.Therefore, the 3rd embodiment also can get the effect identical with the 2nd embodiment.
In the various embodiments described above, be to adopt cam mechanism 39 that rotatablely moving of electrohydraulic valve actuator machine 38 is converted to the straight-line of operating axis 37, but be not limited to this, also can adopt rotatablely moving-linear motion conversion mechanism of other, for example spring is to mechanism, crank mechanism etc.
As mentioned above, owing to have the valve operating gear of the action of feeding water repeatedly among the present invention, this feedwater action is: from the 1st state of opening outlet valve mechanism and closing the locked groove valve system, through the state of closing outlet valve mechanism, the 2nd state to opening the groove valve system injects quantitative cistern with a certain amount of water from hopper, then, through closing the state of locked groove valve, get back to the 1st state of opening outlet valve mechanism, the water in the quantitative cistern is supplied with ice maker container.So, the precision height of waterworks quantitative water supply in ice maker container, and, in the utensil of quantitative water supply, be difficult for to produce incrustation scale, mouldy etc., give water state even continue to be in standby for a long time, outlet valve mechanism can not move malfunctioning yet, can prevent the deterioration of sealing property conscientiously.
In said structure, have the drive motors of driver's valve operating mechanism, and, initial point testing agency is made of magnet and Hall unit, from Hall unit detect magnet near and output detection signal count constantly, passed through the scheduled time after, make drive motors outage and stop, institute seemingly, and is simple in structure.When motor begins to switch on, even motor reverses slightly, Hall unit also can be exported the detection signal that the expression valve operating gear is positioned at initial point unceasingly.Therefore, according to above-mentioned detection signal, can confirm that valve operating gear is positioned at initial point, thereby can prevent the misoperation of valve operating system.
In addition, carry out in the process of feedwater action at valve operating gear, owing to make the closed condition of 2 valve systems keep the stipulated time, so, when checking the sealing property of 2 valve systems, can easily 2 valve systems be set in closed condition, be convenient to above-mentioned inspection.
Carry out in the process of feedwater action at valve operating gear, hopper is loaded onto after being taken off by the user again sometimes.In this case, even the feedwater release, in ice maker container, do not feed water probably yet.Therefore, in the feedwater of feedwater after the release judged, predicate and do not feed water and to report feedwater bad, still, when after detecting hopper and being removed, being loaded onto again, bad and make valve operating gear do the feedwater action again with regard to not reporting feedwater.So the user can not think it is that waterworks are out of order by mistake.
Under the unclosed state of ice making, do not unload ice action owing to do not carry out, ice maker container is not spun upside down, the noise that produces so can prevent therefore, and can prolong life of product.
After to the drive motors energising of driver's valve operating mechanism, the action that begins to feed water, when surpass the scheduled time conduction time of drive motors, make the drive motors outage, so, drive motors can make the drive motors outage, thereby prevent that drive motors from being burnt out during because of certain reason stall.
When connecting power supply, if valve operating gear is not positioned at initial point, thereafter, sends the feedwater action command and begin to feed water when moving, in the feedwater course of action, promptly in the on-off action process of 2 valve systems, carry out feedwater and move.At this moment, in ice maker container feedwater or only give the feedwater unfavorable condition of low amounts of water can take place fully not.To this, behind power connection, when detecting valve operating gear and be not positioned at initial point, be under the condition of level at ice maker container, drive motors is driven, make valve operating gear get back to initial point.So when sending the feedwater action command (before the feedwater action beginning), valve operating gear is positioned at initial point effectively.Therefore, can prevent the feedwater condition of poor.

Claims (7)

1. the waterworks that automatic ice-making plant is used is characterized in that, have quantitative cistern, hopper, outlet valve mechanism, groove valve system, valve operating gear and initial point testing agency; Described quantitative cistern is located at the top of the ice maker container of automatic ice-making plant, and its bottom has the delivery port that flows out water to ice maker container; Described hopper is located at the top of quantitative cistern, and has admission port from water to this quantitative cistern that supply with; Described outlet valve mechanism is used to open and close the delivery port of quantitative cistern; Described groove valve system is used to open and close the admission port of hopper; Described valve operating gear is used for carrying out repeatedly following feedwater action, promptly, from opening outlet valve mechanism and closing the 1st state of locked groove valve system, through the state of closing outlet valve mechanism, the 2nd state to opening the groove valve system injects quantitative cistern with a certain amount of water from hopper, then, through closing the state of locked groove valve, get back to the 1st state of opening outlet valve mechanism, the water in the quantitative cistern is supplied with the feedwater action of ice maker container; Described initial point testing agency is used to detect the initial point whether valve operating gear is positioned at the 1st state.
2. waterworks of using by the described automatic ice-making plant of claim 1, it is characterized in that, have the drive motors that drives above-mentioned valve operating gear, above-mentioned initial point testing agency is made of Hall unit and magnet, the moment close and output detection signal that detects magnet from Hall unit is counted, when having passed through the scheduled time, make drive motors outage and stop.
3. the waterworks of using by the described automatic ice-making plant of claim 1 is characterized in that, carry out in the feedwater course of action at valve operating gear, with the closed condition maintenance stipulated time of 2 valve systems.
4. the waterworks of using by profit requirement 1 described automatic ice-making plant is characterized in that, have hopper and refill decision mechanism and feedwater decision mechanism; This hopper refills decision mechanism and is used for judging that the hopper that is removed is loaded onto again again at valve operating gear execution feedwater course of action; This feedwater decision mechanism is used to judge the water state of giving after the feedwater release, even the feedwater decision mechanism is judged as feedwater, because hopper refills the judgement of decision mechanism, and it is bad not report feedwater, and makes valve operating gear do the feedwater action again.
5. waterworks of using by the described automatic ice-making plant of claim 4, it is characterized in that carry out in the feedwater course of action at valve operating gear, hopper is removed when being loaded onto again, even above-mentioned feedwater decision mechanism predicates not feedwater, do not carry out yet and unload the ice action.
6. the waterworks of using by the described automatic ice-making plant of claim 2 is characterized in that, when surpass setting-up time the conduction time of drive motors, make the drive motors outage.
7. the waterworks of using by claim 2 or 6 described automatic ice-making plants is characterized in that, behind the power connection, when detecting valve operating gear and not being positioned at initial point, at ice maker container is under the condition of level, drives above-mentioned drive motors, makes valve operating gear get back to initial point.
CN96104214A 1995-03-03 1996-03-01 Water feeding apparatus for automatic ice making device Expired - Fee Related CN1122801C (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
JP07043799A JP3130755B2 (en) 1995-03-03 1995-03-03 Water supply for automatic ice making equipment
JP043799/95 1995-03-03
JP043799/1995 1995-03-03

Publications (2)

Publication Number Publication Date
CN1141417A true CN1141417A (en) 1997-01-29
CN1122801C CN1122801C (en) 2003-10-01

Family

ID=12673803

Family Applications (1)

Application Number Title Priority Date Filing Date
CN96104214A Expired - Fee Related CN1122801C (en) 1995-03-03 1996-03-01 Water feeding apparatus for automatic ice making device

Country Status (4)

Country Link
JP (1) JP3130755B2 (en)
KR (1) KR100191301B1 (en)
CN (1) CN1122801C (en)
TW (1) TW289081B (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114812030A (en) * 2022-05-07 2022-07-29 青岛彭美创新科技有限公司 Ice making module and ice maker and refrigerator with same

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP4364916B2 (en) 2007-03-28 2009-11-18 日本電産サーボ株式会社 Automatic ice making machine
KR102023412B1 (en) * 2012-06-12 2019-09-20 엘지전자 주식회사 Refrigerator

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114812030A (en) * 2022-05-07 2022-07-29 青岛彭美创新科技有限公司 Ice making module and ice maker and refrigerator with same
WO2023087736A1 (en) * 2022-05-07 2023-05-25 李兆阳 Ice making module, and ice maker and refrigerator having same

Also Published As

Publication number Publication date
TW289081B (en) 1996-10-21
KR100191301B1 (en) 1999-06-15
CN1122801C (en) 2003-10-01
JP3130755B2 (en) 2001-01-31
KR960034938A (en) 1996-10-24
JPH08240366A (en) 1996-09-17

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