PERFORMANCE

This invention relates to hands-free dispensers for absorbent sheet products (preferably paper towels), and provides dispensers having improved hand sensor performance in hands-free mode. The present inventors have recognized that the presence of metal objects or surfaces in hands-free dispensers, in the vicinity of the hand sensor, sometimes adversely affects the hand sensor performance. United States Published Patent Application No. 2007/0234868, the entirety of which is hereby expressly incorporated by reference herein, describes a hands-free dispenser in which a capacitive hand (proximity) sensor projects through an opening in the front cover of the dispenser, which permits the dispenser cover to have a metallic outer surface.

When developing dispensers as described in United States Published Patent Application No. 2007/0234868, it has been found that when the cover has a nickel-plated outer surface, the performance of the capacitive hand sensor can be adversely affected, resulting, for example, in decreased sensitivity of the hand sensor, hypersensitivity of the hand sensor, and/or spontaneous shutting down of the hand sensor. Additional problems can arise due to accumulation of static electricity on the metallic dispenser parts and/or surfaces, which can result in problems such as double feeding of the absorbent sheet through the internal rollers of the dispenser, spontaneous shutting down of the hand sensor, and uncontrolled dispensing of paper. The present inventors have discovered that one or more of these problems can be mitigated by providing a conductive path from one or more of the metal surfaces that interferes with the intended operation of the dispenser, to a charge receiver that is positioned more remote from the hand sensor than the interfering metal surfaces .

The invention is preferably applied to hands- free dispensers utilizing capacitive proximity sensors for hand detection, as described for example in United States Published Patent Application No. 2007/0234868, but may also be applied to dispensers utilizing hand sensors that operate on different detection principles, such as active or passive infrared hand sensors.

The invention preferably draws charge away from a metallized front cover and/or a metal dispensing roller mounted within the dispenser housing, but it will be appreciated that the invention may draw charge away from any metal surface or component of the dispenser, or away from any metal article proximate the dispenser, that interferes with the intended manner of dispenser operation .

In a preferred embodiment, a conductive wire is mounted inside the dispenser housing, and is electrically connected at one end to both a metallized dispenser cover and a rotating aluminum pinch roll mounted within the dispenser. The wire is preferably encased in plastic or other insulating material intermediate its exposed ends. The wire is preferably connected at its other exposed end to a negative terminal of the battery compartment that holds the batteries powering the dispenser. This embodiment provides a self-contained conductive path that does not complicate the installation of the dispenser; and although the wire does not serve to ground the metal surfaces to any object outside the dispenser, it nevertheless provides improved hand sensor performance by providing a conductive path between the interfering metal surfaces and the more rearwardly-positioned battery compartment .

When the conductive element is connected at its proximate end to a moving member such as an aluminum pinch roll, the electrical contact will be established by suitable means such as a metallic brush element. When the conductive element is connected at its proximate end to the dispenser cover, it is preferred that the electrical contact occur through the intermediary of a conductive element such as a metallic spring that is mounted on the dispenser body, and which is in electrical contact with the dispenser cover only when the cover is closed. It will be appreciated that the interfering metal surfaces and components will typically not be connected to the charge receiver other than by the conductive element according to the invention. For example, a wire supplying driving current to an electric motor would not be a conductive element according to the invention, because such a wire is attendant to the normal operation of the motor. The interfering metal surfaces according to the invention are therefore those that are not necessarily connected to the charge receiver, be it the battery compartment or another charge receiver, for their conventional operation.

It will be appreciated that the conductive path can take forms other than that of a wire, for example, a metallic element mounted to an interior surface of the dispenser body. Such a metallic element, whether in the form of a wire or flexible plate, may be encased in insulating material intermediate the connections to the interfering surfaces and the charge receiver, or may be exposed in these intermediate regions. In another embodiment, interior brackets are formed in the dispenser body at the time of injection molding of the same, and the conductive element is positioned in these brackets . The brackets may hold a conductive element that has already been provided with an insulating covering, or the brackets may themselves provide an insulating covering that partially or completely covers an otherwise exposed conductive element.

As noted above, the charge receiver is the negative terminal of the battery compartment in one embodiment of the invention, which utilizes the batteries as a charge sink when the dispenser is in operation. However, the charge receiver may take the form of other metallic elements either inside or outside the dispenser housing, provided that such charge receiver is positioned at a greater distance from the hand sensor than the interfering metallic surfaces to which the conductive element is connected at its other end. It is nevertheless preferred that the charge receiver be a metallic component inside the dispenser housing, in light of the benefits described above. The invention is applicable not only to battery-powered dispensers but also to hard-wired dispensers that draw their current supply from the mains of the facility in which they are installed. In that case, the distal end of the conductive element would be connected to a suitable charge receiver inside or outside of the dispenser.

The accompanying figures illustrate a preferred embodiment of the invention. In Fig. 1, a cassette of a hands-free dispenser is shown, that incorporates the one version of the improvement of the present invention. That cassette corresponds to the cassette shown in the figures of United States Published Patent Application No. 2007/0234868. As shown in Fig. 1, a conductive wire encased in red plastic is connected at one end to both an aluminum pinch roll (corresponding to the roll 16 shown in Fig. 5 of United States Published Patent Application No. 2007/0234868) via a metallic bracket and a metallic brush, and (via the same metallic bracket) to a metallic spring that is in electrical contact with the dispenser cover when this latter is closed. The particulars of this proximate end connection are shown at greater magnification in Fig. 2. At its distal end, the wire is connected to the negative terminal of the battery compartment, and hence to the negative side of the batteries when the dispenser is in use, as shown in greater detail in Fig. 3.

The following claims reflect various aspects of the inventors' current contemplation of the present invention, and are presented without prejudice to the possible claiming of the invention differently and/or more broadly in a subsequent PCT application or application filed under 35 USC §111 (a), and these claims should not impair the ability of any such subsequent application to claim the priority of the present application under 35 USC §119 (e) or any other applicable statute or rule.