This disclosure is directed to food waste disposers, and more specifically to means to operate food waste disposers in a batch feed mode.
As opposed to continuous feed waste disposers, batch feed waste disposers operate by filling the disposer with waste food, then substantially blocking the drain opening prior to operating the disposer, thereby disposing of food waste in batches. A batch feed disposer uses an interlock device positioned in the drain opening to activate the disposer. The interlock device also prevents foreign objects, such as silverware, from entering the disposer during operation, but will typically allow water to flow into the disposer. Batch feed waste disposers are also used in kitchens that do not have an electrically wired switch above the sink area, in which case the interlock device acts as the switch for the batch feed waste disposer.
One common means for activating the disposer is through mechanical contact of the interlock device with a switch in the throat of the disposer. However, such mechanical means of activating the disposer have been unreliable and subject to premature failure.
Newer methods for activating a batch feed waste disposer have included non-contact approaches, such as activation of a magnetic switch for example. In this approach, the interlock device contains a magnet which, when properly aligned within the drain opening, closes a magnetic switch that activates the disposer. The interlock device must be positioned such that its magnet is in the correct vertical and radial position within the drain opening to align with the magnetic switch.
In batch feed waste disposers using magnetic switch assemblies, such as those marketed by Viking Range Corporation of Greenwood, Miss., a magnet connected to a switch, typically a snap action switch or microswitch, is used to activate the disposer. Additionally, a reed switch or Hall-Effect sensor can also be used. The assembly is typically mounted onto an exterior surface of the disposer body using a special connection assembly. What is needed is a simple magnetic switch assembly that can be easily installed on an existing food waste disposer by a homeowner without the use of tools. It is also desirable to have a magnetic switch assembly that can be easily installed onto an existing continuous feed waste disposer in order to convert the continuous feed waste disposer into a batch feed waste disposer. Moreover, it would also be desirable for a homeowner to easily convert a batch feed disposer to a continuous feed dispose.
Still further, with some existing batch feed disposers, it may be possible to inadvertently actuate the disposer with a strong magnet such as the telescoping type used to retrieve metal objects, or magnetic bracelet jewelry. A strong vibration outside the disposer could also inadvertently actuate the disposer. It is desirable to include features in the design of the switching mechanism that minimize the possibility of inadvertent actuation, and at the same time provide a reasonable level of assurance that the disposer will not be actuated by outside vibration. Inadvertent actuation of a disposer, of course, is very undesirable.
The present application addresses shortcomings associated with the prior art.
In accordance with certain teachings of the present disclosure, a switching assembly for a food waste disposer includes a housing containing a switch and first and second magnets. An interlock device has third and fourth magnets. The magnets are arranged so that the switch is actuated when the first and third magnets align and the second and fourth magnets align. In certain exemplary embodiments, a lockout member is connected to the first magnet and is biased to prevent actuation of the switch device when the first and third magnets are not aligned. An activation member is connected to the second magnet, and activates the switch when the second and fourth magnets are aligned. The lockout member interacts with the activation member to lock the activation member in the off position when the activation member is in the lockout position.
In some embodiments, the third and fourth magnets are placed at specific locations in the interlock device, defining a predetermined angle between them so that the interlock device must be precisely positioned to align the magnets and actuate the disposer. For example, the third and fourth magnets may define an angle of less than 90 degrees therebetween.
To convert the disposer to a continuous feed disposer, an override device is receivable by the housing to lock the switch in an on position. The disposer can the be operated independently of the switching assembly. A cable is attached to the switch. The cable can be secured, for example, by attaching it to the disposer's dishwasher inlet tube. A stress relief device receives the cable and has a first end being pivotally connected to the tube. A fastener connects a second end of the stress relief device to the tube.
Other objects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which:
While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and are herein described in detail. It should be understood, however, that the description herein of specific embodiments is not intended to limit the invention to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
Illustrative embodiments of the invention are described below. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time-consuming, but would nevertheless be a routine undertaking for those of ordinary skill in the art having the benefit of this disclosure.
Referring to
It is a preferred aspect of the present disclosure that housing 12 is attached to the sink flange 20 by “snapping” housing 12 around at least a portion of the exterior periphery of sink flange 20. It is also envisioned that housing 12 may be snapped onto any exterior surface 15 of the food waste disposer circumscribing the drain opening. As best shown in
Housing 12 also preferably contains a locking groove 28 that is designed to engage at least one of the flange screws. Thus, magnetic switching assembly 10 can be securely installed by first snapping housing 12 around sink flange 20 (
One of skill in the art will realize that the proper position of housing 12 on sink flange 20 (i.e. the relative vertical distance below sink 22) is dependent upon the expected location of the activating magnet when the interlock device is positioned in the drain opening. Such a person skilled in the art will be able to adjust the position of the housing accordingly.
Housing 12 is designed to hold magnet 14, switch 16, and any other coupling devices 26 necessary to operatively couple magnet 14 to switch 16. Although
As noted, switch 16 is designed to enable the operation of the food waste disposer upon sensing the presence of an interlock device having a magnet within the drain opening. Switch 16 is preferably a snap action switch coupled to a magnet 14, although it is envisioned that other types of receivers may be utilize for sensing the presence of the interlock device and its magnet. One skilled in the art should appreciate that the need for a separate magnet 14 within the switching assembly 10 is dependent upon the type of switch used. In the embodiments shown in
A snap action switch is preferred because it can handle the high running currents of a food waste disposer, which other types of switches may not be able to handle. Examples of snap action switches commonly found today on the market include the Cherry KWSA-0001 snap action switch and the Saia-Burgess snap action switch. Other switches, such as the reed switch or the Hall-Effect switch, may need to be used in combination with a relay or triac to allow high current operation. When the disposer is not in operation, switch 16 will be in the normally open configuration, meaning that the switch contacts are in the open-circuit position (i.e. the disposer is not activated).
There are two acceptable design alternatives for closing switch 16, both of which may be used to activate the food waste disposer. First, switch 16 may be closed when magnet 14 is “attracted” by another magnet located inside the sink flange 20. Second, switch 16 may be closed when magnet 14 is “repelled” by another magnet located inside the sink flange 20. As is known, the disclosed snap action switches contains buttons which when pressed will cause the switch to be closed. It may be necessary (depending on the type of snap action switch used) to couple the movement of magnet 14 in the housing to the button on the switch 16. Accordingly, a coupling means 26, which is specially fitted to receive magnet 14 and to interface with the switch's 16 button, is designed to move as the magnet 14 moves, and accordingly to close the switch. Coupling means 26 is in one embodiment a specially formed and shaped piece of hard plastic, but could be made from several different materials and in several different configurations to effectuate proper transfer of the magnet force to the switch 16. However, depending on the orientation of the magnet and the switch, a coupling means 26 may not be necessary, so long as the magnet's force can be imparted directly to the switch. Moreover, a combined magnet/switch assembly can be used in lieu of components 14, 16, and 26, in which case the magnet on the assembly operates as the switch and directly controls the switching function.
Magnet 14 is preferably a rare earth magnet, and more preferably a magnet comprised of neodymium, and even more preferably a magnet comprised of neodymium iron boron. Rare earth magnets are preferred because of their strength, small size, reliability, and cost. Testing also reveals that rare earth magnets provide a more robust and accurate switching location, which is important for ease of use by homeowners.
Cables, such as the cable 18 connected to the housing 12, must be secured firmly enough to pass agency pull tests. The plastic or rubber cord insulation must not be damaged. Further, the ornamental cover of the disposer must not be subjected to any undue strain. To secure the cable or other cords associated with the disposer, a cord strain relief device is disclosed.
Referring to
As noted above, the switch 16 is activated via interaction of the magnet 14 with another magnet situated inside the sink flange 20. Typically, this magnet would be part of an interlock device that is inserted into the sink flange by a user to operate the disposer. However, in some instances, it is possible for a batch feed disposer to be inadvertently actuated with a strong magnet not associated with an interlock device, such as the telescoping type used to retrieve metal objects, or magnetic bracelet jewelry.
For the interlock device 300 to actuate the switching assembly 100, two magnets 310, 311 in the interlock device 100 must be aligned with two magnets 110, 111 in the switching assembly 100. In the illustrated system, the magnets 310, 311 are received in lobes 312, 313 extending from the interlock device 300. The illustrated embodiments include a second set of magnets 310a,311a and associated lobes 312a,313a, though these are provided as a convenience to a user and not required for operation of the system .
The interlock device 300 essentially operates as a precise magnetic “key” to unlock the switching mechanism 116 contained in the switching assembly 100. One of the magnets 310 attracts a corresponding magnet 110 attached to a lockout member 150, drawing it toward the interlock device 300 and thereby unlocking the mechanism. The second magnet 311 in the interlock 300 attracts the magnet 111 that actuates the switch 116 via an activation member or arm 152. The angle between the magnets is important. When the interlock device 300 is rotated to the right or left so that the magnets are unaligned, springs in the switching mechanism 116 turn it off. A spring 154 in the lock member 150 assists in returning the switch arm 116 to the off position. The lock member 150 moves into place, preventing the switch arm 116 from moving. As the interlock device is rotated further, the attraction between magnets serves as an “off” detent in either direction. This makes the system less likely to actuate when subjected to outside vibration. Since the angle between the magnets is less than 90 degrees, the second set of magnets 310a,311a on the other side of the interlock device 100 are not close enough to actuate the system. The second set of magnets 310a,311a are not needed for the system to function, but can be added for consumer convenience.
In alternative embodiments, polarities of the various magnets are arranged to attract or repel the locking member 150 and activation arm 152 as required to either actuate the switch 116 or lock it in an off mode. In still further embodiments, different combinations of weaker and stronger magnets are used to effect movement of the locking member 150 and activation arm 152 as desired.
As shown in
In some instances, a consumer may prefer to actuate the disposer via a wall switch instead of using the magnetic interlock device 300. In other words, convert the disposer so that it no longer functions as a batch feed device.
An override device 400 works in concert with the magnetically actuated switching assembly 100 for a batch feed disposer. As shown in
While the invention has been described with reference to specific embodiments, it is not limited to these embodiments. The invention may be modified or varied in many ways and such modifications and variations are within the scope and spirit of the invention and are included within the scope of the following claims.
This application claims priority to Indian Patent Application No. 1400/MUM/2005, filed on Nov. 9, 2005, and is also a continuation-in-part of U.S. patent application Ser. No. 10/389,160, filed on Mar. 14, 2003, both of which are incorporated by reference.
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Number | Date | Country | |
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20060144975 A1 | Jul 2006 | US |
Number | Date | Country | |
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Parent | 10389160 | Mar 2003 | US |
Child | 11319355 | US |