1. Field of the Invention
The present invention relates generally to an ice-making assembly for installation in a domestic refrigerator or freezer.
2. Description of the Prior Art
In higher-quality refrigerators or freezers in particular, it is increasingly the practice to equip these appliances with an ice maker, with which pieces of ice, e.g. in cube form, can be produced. On the one hand, a high production capacity (i.e. a large quantity of ice that can be produced per unit of time) is aspired to in the case of such ice makers, on the other hand a high production capacity of the ice maker is often accompanied by a correspondingly enlarged size of the ice maker, for which adequate space is not available inside the appliance in common household refrigerators or/and freezers
JP 09-310946 A shows in its figures an ice maker with two ice cube trays, which are each longer than they are wide and are arranged adjacent to one another transversely to their longitudinal extension. The two ice cube trays are each rotatable about their own axis of rotation in order to rotate the trays into a discharge position, in which the ice cubes produced in them can fall out of the trays.
Embodiments of the present invention provide an ice-making assembly for installation in a domestic refrigerator or freezer, the ice-making assembly comprising: a frame structure; first and second ice-making trays supported for rotation about a rotational axis with respect to the frame structure between an ice production position and an ice discharge position, wherein the first and second ice-making trays are disposed behind one another in a direction of the rotational axis and each have a tray longitudinal dimension in the direction of the rotational axis that is larger than a tray width direction in a direction transverse to the rotational axis. By arranging the ice-making trays with their long side behind one another, instead of longitudinally adjacent to one another, they do not take up any more construction space in width than an ice-making assembly with a single ice-making tray of the same tray size. In the longitudinal tray direction, however, the adequate interior depth often present in domestic refrigerators or freezers can be used, which can facilitate the installation of two ice-making trays arranged behind one another in a longitudinal direction. This applies in particular (but not only) if the ice-making trays are operated according to the twist-tray principle, i.e. the trays are not only rotatable into their discharge position, but are additionally twistable to cause or to assist the ice produced in the trays to break loose. In ice makers that operate according to the twist tray principle, the ice-making trays often do not exceed a set length, because as the tray length increases, the angle by which the tray is to twist so that the ice located therein can be broken loose reliably from the tray gets bigger. The construction space available inside household refrigerators or freezers is often considerably deeper than the normal length of a single ice-making tray. This available construction space can be used efficiently if two ice-making trays are arranged behind one another in the longitudinal direction of the tray. This does not increase the construction size of the ice-making assembly in a plane transverse to the longitudinal direction of the tray (or at any rate not substantially), but offers an increased ice production capacity compared with a single ice-making tray.
In this disclosure, an ice-making assembly means a preassemblable construction unit, which can be installed as such in a refrigerator or freezer.
In certain embodiments, the ice-making assembly further includes a rotary drive device supported on the frame structure for causing rotation of the first and second ice-making trays about the rotational axis. The rotary drive device includes a drive motor disposed adjacent to a first longitudinal end of one of the first and second ice-making trays where the other of the first and second ice-making trays is disposed adjacent to a second longitudinal end of the one of the first and second ice-making trays opposite the first longitudinal end. The drive motor is an electric motor, for example, and sits—seen in the tray longitudinal direction—beyond both ice-making trays, thus either in front of or behind the two trays. In other embodiments, the drive motor sits between the first and second ice-making trays.
To freeze water poured into the ice-making trays, a cold air flow is used in certain embodiments of the present invention, which sweeps past the ice-making trays on the underside of the tray bottom. So that both ice-making trays are covered by the cold air flow substantially along their overall length, the ice-making assembly may include a wall structure delimiting a cold air duct extending on the underside of the first and second trays from one to the other of the first and second ice-making trays. Cold air can flow in the cold air duct. The wall structure keeps the flowing cold air in contact with the ice-making trays, so to speak, and prevents it from being diverted prematurely, i.e. before it reaches the rear end of the rear ice-making tray (seen in the tray longitudinal direction). So that the wall structure arrangement does not stand in the fall path of the ice falling out upon emptying of the ice-making trays, thus when the ice produced therein is discharged from the trays, and obstruct the emptying process, the wall structure in certain embodiments includes a separate first wall member in relation to each of the first and second ice-making trays, each first wall member being arranged for movement relative to the frame structure. Each first wall member can be arranged, for example, for joint rotation with the respectively associated ice-making tray. Other movement patterns are naturally conceivable for the first wall members, for example a lateral (horizontal) movement out of the fall path of the ice produced.
So that the cold air duct can extend without interruption if possible from one ice-making tray to the other, the wall structure in certain embodiments further includes a second wall member interposed between the first wall members and arranged fixedly relative to the frame structure. The second wall member facilitates a seamless transition of the cold air duct to the adjacent first wall members.
In certain embodiments, the ice-making assembly comprises a tray-and-duct sub-assembly supported on the frame structure for rotation with respect to the frame structure about the rotational axis, the tray-and-duct sub-assembly including a channel member having the wall structure, the channel member defining a channel, wherein the first and second ice-making trays are accommodated in the channel and are supported on the channel member.
The channel member may include opposite channel end walls and an intermediate support wall, the first ice-making tray being arranged between, and supported on, a first of the channel end walls and the intermediate support wall, the second ice-making tray being arranged between, and supported on, the intermediate support wall and a second of the channel end walls.
Each of the first and second ice-making trays may be arranged for joint rotation with the channel member about the rotational axis and for twisting relative to the channel member about a twist axis extending parallel to the rotational axis.
According to another aspect, the invention provides a domestic refrigerator or freezer that includes an ice-making assembly and a container. The ice-making assembly includes a frame structure and first and second ice-making trays supported for rotation about a rotational axis with respect to the frame structure between an ice production position and an ice discharge position. The the first and second ice-making trays are disposed behind one another in a direction of the rotational axis and each have a tray longitudinal dimension in the direction of the rotational axis that is larger than a tray width direction in a direction transverse to the rotational axis. The container is arranged under the first and second ice-making trays to collect ice discharged from the first and second ice-making trays.
Embodiments of the present invention will be explained in more detail hereinafter with reference to the enclosed drawings.
Reference is made first to
Both ice-making trays 14, 16 are rotatable relative to the main frame 12 about a common axis of rotation 20 running in a tray longitudinal direction. A rotary drive device generally designated 22 is used for the rotary drive of the ice-making trays 14, 16 relative to the main frame 12. The rotary drive device in the embodiment in
In the example shown, the drive unit 24 and the first transmission unit 26 are located beyond the two trays 14, 16 when seen in the longitudinal direction of the two trays 14, 16, while the transmission unit 34 sits between the two trays 14, 16. Specifically, the drive unit 24 and the first transmission unit 26 are installed in the main frame 12 in the example shown on the side of that longitudinal end of the ice-making tray 14 that is remote from the ice-making tray 16.
A lever 36 fitted pivotably on the main frame 12 is used to detect the filling level in a collection container (not shown in greater detail in
In
The embodiment in
The wall structure 38a is composed in the example shown of several separately produced wall members comprising first wall members 48a and 50a and a fixed second wall member 52a. Located beneath the ice-making tray 14a is the movable first wall member 48a, which is arranged for joint rotation with the ice-making tray 14a so that it is not in the fall path of the pieces of ice falling out in the ice discharge position of the tray 14a. Located beneath the ice-making tray 16a is the movable first wall member 50a, which is arranged analogously to the wall member 48a for joint rotation with the ice-making tray 16a. The main frame 12a provides corresponding recesses in which the ice-making tray 14a, 16a and the movable first wall members 48a, 50a can rotate about the axis of rotation 20a. The space between the two movable first wall members 48a, 50a is bridged by the fixed second wall member 52a, which is arranged fixedly relative to the main frame 12a. A certain axial overlap can exist here between the fixed second wall member 52a and one or both of the movable first wall members 48a, 50a.
The movable first wall members 48a, 50a and the fixed second wall member 52a can be formed in cross section roughly in the shape of a channel or trough, for example. The movable first wall members 48a, 50a can be drawn up on both sides of the longitudinal edges of the respective ice-making tray 14a, 16a, so that the trays 14a, 16a—figuratively speaking—are sunk in the channels formed by the first wall members 48a, 50a or immersed in these. For a particularly efficient use of the cold air conveyed in the cold air duct 40a it can be advantageous if the first wall members 48a, 50a together with the ice-making trays 14a, 16a form a duct space that is closed all around in cross section. To do this, the wall surface sections 48a, 50a can contact the trays 14a, 16a laterally or be connected to these.
To achieve a continuously good cooling effect over the entire extent of the cold air duct 40a, the cross section size of the cold air duct 40a may decrease on the section from the outlet opening 44a to the exit opening 46a (leaving the inconsistencies on the underside of the trays 14a, 16a caused by the bulges 18a out of consideration). See the taper (bevel) of the fixed second wall member 52a indicated at 54a in this regard and the taper (bevel) of the movable first wall member 50a indicated at 56a.
In
Reference is now made to
The ice-making assembly 10c according to the embodiment shown in
The rotary drive device 22c, which is supported by the main frame 12c, comprises the transmission unit 26c to transmit a drive torque from the drive unit 24c to the tray-and-duct sub-assembly 64c.
The channel member 66c includes opposite channel end walls and an intermediate support wall. A first channel end wall 68c of the channel member 66c is formed at a first end of the channel member 66c which is coupled to the drive transmission unit 26c. A second channel end wall 72c of the channel member 66c is formed at the opposite second end of the channel member 66c. An intermediate support wall 70c of the channel member 66c is located between the first and second channel end walls 68c, 72c. The first ice-making tray 14c is arranged between the first channel end wall 68c and the intermediate support wall 70c, the second ice-making tray 16c is arranged between the intermediate support wall 70c and the second channel end wall 72c. The first ice-making tray 14c is supported in the region of one of its longitudinal ends on the first channel end wall 68c in a rotationally fixed manner and in the region of its opposite longitudinal end on the intermediate support wall 70c in a manner permitting a twisting rotational movement with respect to the channel member 66c. The second ice-making tray 146c is supported in the region of one of its longitudinal ends on the intermediate support wall 70c in a rotationally fixed manner and in the region of its opposite longitudinal end on the second channel end wall 72c in a manner permitting a twisting rotational movement with respect to the channel member 66c.
A synchronous drive of the first and second ice-making trays 14c, 16c is enabled via the channel member 66c. By actuating the drive unit 24c, therefore, the first and second ice-making trays 14c, 16c can both be rotated from an ice production position (similar to the situation shown in
Although the preferred embodiments of the present invention have been described herein, the above description is merely illustrative. Further modification of the invention herein disclosed will occur to those skilled in the respective arts and all such modifications are deemed to be within the scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
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10 2015 002 424.8 | Feb 2015 | DE | national |