The present invention relates to an ice dispenser, especially an ice dispenser of the type able to be used in a refrigerator to store pieces of ice made by an automatic ice maker of the refrigerator and dispense them as required by a user.
An ice dispenser known from U.S. Pat. No. 4,176,527 A comprises a storage container for pieces of ice, a stirrer able to rotate around an axis extending through the supply container, an output chamber which lengthens the supply container in the direction of the axis and a rotatable slide coupled to the supply container in the output chamber in the form of a number of blades attached in parallel to the axis which, as they rotate, convey the ice penetrating into the output chamber to a outlet opening. The stirrer is embodied over a part of its length as a spiral and over the other part of its length adjacent to the output chamber as a worm drive conveyor, so that pieces of ice are conveyed into the output chamber by the rotation of the stirrer. Were the stirrer to be rotated without ice being able to be dispensed from the output chamber, the ice would build up in the output chamber and block its rotation. A rotation of the stirrer without simultaneous output of ice is thus not possible. If no ice is removed for a long period there is the danger of the pieces of ice freezing solid to each other in the supply chamber and blocking the rotation, so that the ice dispenser must be taken out of the refrigerator and defrosted to allow it to be used again.
To counter this danger, a very powerful drive motor can be provided for the stirrer, and supply container and stirrer can be designed to withstand high mechanical stresses, in order to make it possible to break away the pieces of ice even after long periods without use. In this way, although the danger of blocking of the ice dispenser can be reduced or the period of non-use until a blockage occurs can be extended, this approach is associated with significant costs and there is the danger of pieces of ice being inadvertently crushed in the supply container. However the greater the proportion of small fragments of ice in the supply container, the greater is its tendency to freeze solid and the greater is also the force necessary to release the ice.
U.S. Pat. No. 4,846,381 proposes solving the problem of freezing up by having a separate stirrer and screw conveyor accommodated in the supply container of an ice dispenser and having them driven by a separate motor respectively. This means that the stirrer can be driven to release the pieces of ice from one another without ice being simultaneously output by the screw conveyor. A problem of this construction is the large amount of space required for the stirrer and the separate screw conveyor and its drive motor, which essentially makes this solution of interest for commercial devices used exclusively for ice making. The object of the present invention is to create an ice dispenser which reliably prevents the freezing solid of stored pieces of ice and which, in doing so, has a structure that can be implemented cost-effectively, which makes it especially suitable for use in a household refrigerator.
The object is achieved in that, with an ice dispenser with a supply container for pieces of ice, a stirrer able to be rotated around an axis extending through the supply container, an output chamber adjoining the supply container and a rotatable slide coupled in the output chamber to the stirrer, with on a wall of the output chamber in which the slide is moved along as it rotates, an outlet opening is formed for ice conveyed by the slide, a coupling is arranged between stirrer and slide in order to optionally transmit or not transmit a drive torque exerted on the slide. If the drive torque is transmitted, the slide rotates together with the stirrer, and pieces of ice which reach the output chamber by the movement of the stirrer or arrive in the output chamber in another way, are conveyed by the slide to the outlet opening. If the drive torque is not transmitted, the slide remains at rest, so that ice is not conveyed to the outlet opening. In this state it is possible to actuate the stirrer on its own in order to release pieces of ice that have frozen together in the supply container, without ice being output simultaneously.
On account of its simple construction, an ice dispenser is preferred in which the stirrer and the slide have the same axis of rotation.
The output chamber expediently has the shape of a cylinder concentric to the axis of rotation of the slide, where the outlet opening is formed in a drum surface of the cylinder.
According to a first embodiment one face side of the cylindrical output chamber is open to the supply container.
According to a second embodiment a dividing wall with a through-opening is arranged between the supply container and the output chamber. The size of the through-opening can be suitably selected to control the rate at which pieces of ice enter the output chamber from the supply container when the stirrer is moved.
The prevent pieces of ice entering the output chamber if the stirrer is just moved to keep the pieces of ice in motion, the slide can advantageously be fixed in a setting blocking the through-opening.
To promote the movement of the pieces of ice from the supply container into the output chamber, the supply chamber preferably has a floor sloping down towards the output chamber.
It is further preferable for the slide to have a first set of fingers and for a second set of fingers to be provided in the output chamber with at least one of the sets comprising at least two axially spaced fingers, and that, with a rotation of the slide, a finger of the other set fits into a space between the two fingers of the one set. Pieces of ice coming between the two sets of fingers are crushed between the fingers and thus reach the outlet opening in the form of small fragments. To improve the crushing effect, the fingers are expediently embodied as blades, with sharp cutting edges.
To safely exclude the output of pieces of ice during stirring when the coupling is open—especially with the above-mentioned first embodiment without dividing wall between supply container and output chamber—the second set of fingers is preferably able to be fixed in a setting bridging the outlet opening.
To prevent the output of the pieces of ice, it is not necessary for the second set of fingers to completely close off the output opening; it is sufficient for it to reduce the free cross section enough for no complete piece of ice to pass through.
If the second set of fingers, in the setting of the fingers bridging the outlet opening, only partly closes off this opening, it can be used in this setting to crush the pieces of ice, since the crushed pieces thus produced can continue to pass through the outlet opening.
In order to also be able to output intact pieces of ice, the second set of fingers is expediently able to be moved between the setting bridging the outlet opening and a setting releasing the outlet opening.
To make it possible for the second set of fingers to return to the bridging setting, without having to provide separate drive means for this purpose, it is advantageous for the bridging setting to be a stable equilibrium setting of the second set of the fingers.
The second set of fingers is preferably locked if required by a user in the output chamber or is able to be rotated jointly with the slide around its axis of rotation.
Such a rotation can be driven in a simple way, if the second set of fingers is positively coupled to the slide.
Further features and advantages of the invention emerge from the description of exemplary embodiments given below which refer to the enclosed figures. The figures are as follows:
The refrigerator shown in
Arranged below the ice maker 5 is a collection vessel 6 of an ice dispenser which receives the discharged pieces of ice. The collection vessel 6 extends over a large part of the depth of the inner chamber 3. Accommodated in a rear recess 7 of the collection vessel 6 is an electric motor for driving a stirrer 8 extending in a longitudinal direction of the collection vessel 6. At an end 7 of the stirrer 8 extending away from recess rotating blades 9 of a crusher are coupled in a way not described in any greater detail below. The blades 9 are accommodated in a cylindrical output chamber 10, which is open to the collection vessel 6 and lengthens this along the axis of rotation of the stirrer 8. Arranged on an end face of the output chamber 10 facing the door 2 is an electromagnet 11, the function of which is likewise explained further on in this document.
The stirrer 8 is a metal rod bent into a zigzag form in a plane parallel to the axis. Because of its planar shape, unlike a helix or a worm drive, it does not exert any conveying force in an axial direction on the pieces of ice contained in the collection vessel 6, but moves these in random directions and thus prevents them freezing solid to each other over a wide area. Thus the stirrer 8 can be turned from time to time by the motor, without thus pushing pieces of ice into the output chamber 10 and being able to block the latter.
As can especially be seen in the
A water tank 16 is embedded on the rear wall of the recess 14 in the insulating material of the door 2. The water tank 16 is connected on the one hand like the ice maker 5 via a supply line 17 and a cut-off valve 18 to the drinking water network and on the other hand to a dispensing nozzle 19 in the recess 14.
The structure and function of the crusher in accordance with a first embodiment are now described with reference to
The plates 26 are connected rigidly at their outer circumference by two transverse bars 25, 27. In the configuration shown in
The edge sections of the plates 26 adjoining the shaft 20 are respectively clamped via elastic buffer rings 29 between two slides 23, so that the plates 26 tend to follow a rotation of the blades 9 in the counterclockwise direction if they are not prevented from doing so, as shown in
It can again be seen with reference to
The ice dispenser functions as follows: While the shaft 20 and the sleeve 22 are not coupled to one another, as shown in
If the coupling element 31 is moved, to establish the positive connection between shaft 20 and sleeve 22 the blades 9 rotate jointly with the stirrer 8 in the counterclockwise direction. Pieces of ice which reach the output chamber 10 are pushed by the rotating blades 9 against the plate 26 and crushed between the rotating blades 9 and the plates 26 blocked by the stop 28. The fragments produced in such cases pass through the spaces between the plates 26 and reach the outlet opening 12. Crushed ice is thus dispensed.
To dispense ice in pieces it is sufficient to withdraw the stop 28 briefly while the stirrer 8 is rotating in the counterclockwise direction. Because of the clamping between the buffer rings 29 the plate 26 rotates together with the blades 9 and releases the outlet opening 12, so that the blades 9 push intact pieces of ice to the outlet opening 12 and these are output.
Basically it is possible to leave the stop 28 withdrawn while the pieces of ice are being output, so that the plates 26 perform the same rotation as the blades 9. In this case however it is difficult to measure out the pieces of ice since the dispensing mode for pieces of ice can only be ended if the plates 26 have reached the setting shown in
In this embodiment the shaft 20 extends through a partition wall 34 which separates the collection vessel 6 and the output chamber 10 from each other. A through-opening 35 (see
The blades 9 able to be coupled in the output chamber 10 with the aid of the electromagnet 11 to the rotation of the stirrer 8 have the same shape as shown in
In the configuration shown in
If intact pieces of ice are to be delivered it is sufficient to withdraw the stop 28, so that as a result of the clamping of the blades 36 between the buffer rings 29, the blades 36 are carried along with the rotation of blades 9. There can be provision for the stop 28 to be withdrawn precisely when a group of blades 9 passes the blades 36. In this way an even delivery of the pieces of ice can be achieved since the blades 36 do not prevent the pieces of ice getting through the through-opening 35 in one of the spaces between the four groups of blades 9.
If the coupling element 31 is disengaged to make it possible to rotate the stirrer 8 without simultaneously rotating the sleeve 22 and the blades 9, this expediently occurs if the blades 9 are in an orientation as shown in
Number | Date | Country | Kind |
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20 2006 013 709.2 | Sep 2006 | DE | national |
10 2006 061 094.6 | Dec 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/058723 | 8/22/2007 | WO | 00 | 9/28/2009 |