The present invention relates to an ice flap device for a refrigerator, comprising
Refrigerators are known that have a built-in ice dispenser for dispensing ice cubes and/or crushed ice. A compartment is normally located on the front of a door of the refrigerator for introducing a glass or other receptacle, which is to be filled with ice. Located above the glass introduced into the compartment is the end of a dispenser shaft, through which the ice falls into the glass. Depending on its position, a movable ice flap opens or closes a dispenser aperture of the dispenser shaft. The invention is concerned in particular with the operation of such an ice flap and proposes an advantageous motorized type of operation.
The object of the invention is to provide an ice flap device of the type described at the beginning, which can be manufactured cheaply with a simple design configurtion and at the same time generates little noise in operation.
To achieve this object, the invention proposes according to one aspect that in the case of a generic ice flap device, the drive mechanism comprises an a.c. motor and a first electrical switch, which lies in the supply circuit of the a.c. motor and switches depending on a user action such as the placing of a receptacle into an ice dispenser compartment of the refrigerator, for example, and by means of which the a.c. motor can be turned on when the receptacle is placed into the ice dispenser compartment to move the flap unit from the closed position in the direction of the open position.
Advantageous developments of the invention result from the dependent sub-claims.
What is advantageous about the solution according to the invention according to the above aspect is that the a.c. motor can be operated directly using the mains operating voltage of the refrigerator. A power unit for rectifying and transforming down the mains voltage, such as would be necessary in the case of a d.c. motor or a stepper motor, can be dispensed with in this respect. Motorized drive solutions are also distinguished by a lower noise level than magnetically actuated solutions, for example; they can be kept largely free of disturbing humming and clicking noises. By controlling the a.c. motor by electrical switches, which lie in the supply circuit of the motor and switch depending on the proper introduction of a receptacle into the ice dispenser compartment and/or depending on the position of the flap unit, it is also possible to dispense with complex processor-based control logic for the motor.
The user action by means of which the first switch is switched can also include, alternatively or in addition to introducing a glass into the ice dispenser compartment, pressing a button for example, by means of which the user can initiate ice dispensing and if applicable terminate it (by releasing the button or pressing it again).
According to a further aspect of the invention, furthermore, instead of an a.c. motor a d.c. motor can also be used, which can likewise be controlled by means of one or more mechanically actuatable electrical switches lying in the supply circuit of the motor. Even such a switch-controlled d.c. motor solution can manage without central control intelligence in the form of a processor for controlling the motor.
The invention is explained further below with reference to the enclosed figures. The figures show:
To explain the ice flap device according to the first embodiment, reference is made first to
The flap unit 14 is pretensioned by spring pretensioning means, in the case of the example by a torsion spring 30 (see
Protruding into said dispenser compartment of the refrigerator is an operating rocker 16, which is supported swivellably about an axis of rotation 17 and is pushed backwards (relative to the dispenser compartment) against the resetting effect of an elastic pretensioning element (not shown in greater detail) by the receptacle when this is placed in the dispenser compartment. The operating rocker 16 tilting backwards thereupon mechanically actuates a first electrical switch 26, the switching of which turns on the motor 12. If the receptacle is removed from the dispenser compartment again, the operating rocker 16 swivels back, at which the switch 26 switches back to its original position. The switch 26 thus switches depending on the placing of the receptacle into the dispenser compartment. It goes without saying that solutions other than an operating rocker are possible to actuate an electrical switch depending on the placing of a receptacle into the ice dispenser compartment of the refrigerator. For example, a pressure switch, which is actuated directly by the receptacle, could be provided at the rear end of the dispenser compartment.
Connected to the motor shaft of the motor 12 is a cam disc 18, which rotates about the axis designated A of the motor 12 when the motor 12 is driven. The external circumferential face of the cam disc 18 serves as a control face for controlling two further mechanically actuated electrical switches 22, 24. Furthermore, protruding axially from the cam disc 18 is an eccentric lug or cam 20 circulating with the disc around the axis A, which cam interacts with the flap unit 14 to drive it. Specifically the eccentric lug 20 interacts in the example shown with a radial finger 28 of the flap unit 14, which finger is formed in an axially lateral area of the flap carrier and preferably in one piece with this.
The motor axis A and the flap swivel axis 15 lie substantially parallel to one another but at a radial distance from one another. The circulatory path of the eccentric lug 20 runs partly through the swivel space of the flap unit 14 and partly outside this. Accordingly no permanent coupling exists between the motor 12 and the flap unit 14. Instead of this, when the motor 12 is driven, the eccentric lug 20 moves from outside the swivel space of the flap unit 14 towards it until it abuts against the finger 28. When the motor 12 rotates further in the same direction of rotation, the eccentric lug 20 then presses the flap unit 14 open or closed against the effect of the torsion spring 30 depending on whether the flap unit is pretensioned in its closed position or its open position. As the motor 12 rotates still further in the same direction of rotation, the eccentric lug 20 then moves through a dead centre of maximum opening or maximum closing of the flap unit 14 and again approaches the limit at which it exits the swivel space of the flap unit 14. In this phase, the flap unit 14 closes or opens again under the pretensioning effect of the torsion spring 30, until it finally comes to rest in its closed position or open position by stopping at an abutment that is stationary relative to the dispenser housing and the eccentric lug 20 exits the swivel space of the flap unit 14.
A complete revolution of the eccentric lug 20 thus corresponds to an opening and subsequent closing of the flap unit 14. The motor 12 can always be operated in the same direction of rotation in this case.
To close the flap unit 14, the motor 12 is rotated further in the direction of the arrow 32. The eccentric cam 20 then rotates out of the rotary position according to
It can be seen that the angle of rotation of the eccentric cam 20 from the closed position of the flap unit 14 according to
The two further switches 22, 24 likewise lie in the supply circuit of the motor 12. They each have one actuating finger in permanent spring-loaded engagement with the control face formed on the outer circumference of the cam disc 18, so that the actuating fingers follow the radial contour of the control face. The switching state of the switches 22, 24 depends in this manner on the rotary position of the cam disc 18 and accordingly on the rotary position of the motor shaft.
To explain in greater detail the electrical interconnection of the switches 22, 24, 26 and the motor 12 and the control of the ice flap device 10 depending on the switching states of the switches, reference is now made to
The switch 26 is a two-way switch, which depending on the switching state applies an a.c. mains voltage 40 (e.g. 110 V or 220/240 V) serving as a supply voltage to one of two parallel circuit branches 39, 41, which both run electrically parallel to one another and lead to a common first voltage connection 43a of the motor 12. The circuit branch 39 runs via the further switch 22, while the circuit branch 41 runs via the further switch 24.
The switch 22 is likewise formed as a two-way switch. Depending on the switching state, it either closes the circuit branch 39 (as e.g. in
The switch 24 is formed as a simple on/off switch, which opens the circuit branch 41 (as e.g. in
A second voltage connection 43b of the motor 12 is connected directly to the supply voltage 40. The same applies to the other operating voltage connection of the drive unit 42.
In the starting state of the ice flap device 10 according to
As a result of the rotation of the cam disc 18, both switches 22, 24 are actuated. The situation according to
In
When the flap unit 14 opens (phase between
When the flap unit 14 closes (phase between
The time profile indicated for the switching processes of the switches 22, 24 can be set without difficulty via the opposite angular position of the notches 36, 38 and their angular extension as well as via the opposite angular position of the switches 22, 24. In the example shown, the notches 36, 38 are arranged for this purpose approximately at a distance of 180 degrees from one another, whereas the switches 22, 24 are arranged at a somewhat smaller effective angular distance from one another.
To explain the second embodiment, reference is made below to
The ice flap device 10 according to the second embodiment differs from the previous embodiment essentially in that the a.c. motor 12 is a polyphase motor operable in both directions of rotation and in particular a capacitor motor, which has a permanent rotary drive connection to the flap unit 14, preferably on the same axis, and in that in addition to the first switch 26 only one further switch 27 lies in the supply circuit of the motor 12. The switching state of this switch 27 is also dependent directly on the rotary position of the flap unit 14 due to the fixed drive coupling between motor 12 and flap unit 14.
In
The motor 12 operates with at least two phase voltages, the relative phase position of which determines the direction of rotation of the motor 12. In particular, the motor 12 produces by means of a capacitor arrangement an auxiliary phase voltage from an available single-phase mains voltage, wherein the switching states of the two switches 26, 29 determine the relative phase position (leading, lagging) of the auxiliary phase voltage thus generated compared with the mains voltage serving as an operating phase voltage. The capacitor arrangement, which can consist for example of a single capacitor, is designated 45 in
If the operating rocker 16 is actuated by introducing a receptacle into the dispenser compartment (
In the situation according to
In
Number | Date | Country | Kind |
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10 2008 013 750 | Mar 2008 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
3211388 | Gartner | Oct 1965 | A |
3406871 | Hoenisch | Oct 1968 | A |
3548444 | Callahan et al. | Dec 1970 | A |
3640088 | Jacobus et al. | Feb 1972 | A |
3789620 | Benasutti et al. | Feb 1974 | A |
3942334 | Pink | Mar 1976 | A |
4069545 | Holet et al. | Jan 1978 | A |
4090641 | Lindenschmidt | May 1978 | A |
4441337 | Kantor | Apr 1984 | A |
4462437 | Prada | Jul 1984 | A |
4679715 | Hovinga | Jul 1987 | A |
4901396 | Tatematsu et al. | Feb 1990 | A |
5077985 | Buchser et al. | Jan 1992 | A |
5139183 | Buchser et al. | Aug 1992 | A |
6135173 | Lee et al. | Oct 2000 | A |
6533003 | Jacobus et al. | Mar 2003 | B1 |
7302809 | Park | Dec 2007 | B2 |
7316121 | Lee et al. | Jan 2008 | B2 |
7340914 | Bowen et al. | Mar 2008 | B2 |
7383689 | Lee et al. | Jun 2008 | B2 |
7418830 | Bowen et al. | Sep 2008 | B2 |
7418831 | Bowen et al. | Sep 2008 | B2 |
7445137 | Noh et al. | Nov 2008 | B2 |
7587910 | Bowen et al. | Sep 2009 | B2 |
7617698 | Bowen et al. | Nov 2009 | B2 |
7628032 | Lee et al. | Dec 2009 | B2 |
7703297 | Bowen et al. | Apr 2010 | B2 |
20070256442 | Lyvers et al. | Nov 2007 | A1 |
Number | Date | Country | |
---|---|---|---|
20100089492 A1 | Apr 2010 | US |