Shelving systems are commonly used for the efficient display or storage of consumer goods and other items. In their most basic form, shelving systems use fixed (non-adjustable) shelves. Such systems necessarily are designed with sufficient spacing between shelves to accommodate the largest or tallest object expected to be stored therein. A considerable storage volume can be wasted if such a system is used to store items smaller than those considered in establishing the design. Such wasted storage volume could be reduced by reducing the spacing between shelves, but only at the expense of no longer providing capacity to store larger items.
Manually adjustable shelving systems can decrease these inefficiencies by allowing the user to set shelf spacing as necessary for a particular application and to adjust the shelf spacing as needs change. However, manually adjustable systems typically require that items borne on a shelf be removed from the shelf before adjustments can be made. Power operated shelving systems can overcome this problem by allowing the user to adjust shelf spacing on demand, without first clearing a shelf of its contents. However, power operated shelving systems using conventional mechanical switch control interfaces also have limitations. For instance, mechanical switches typically include internal moving parts which are at least somewhat exposed to the environment. As such, contaminants, such as dirt or moisture, can enter the switch mechanism and increase the risk of malfunction or the severity of mechanical wear. Also, the discontinuities and crevices associated with mechanical switches can make such switches and the areas around them difficult to clean.
Further, mechanical switches typically have large profiles, often making it difficult to integrate them into a shelving system where space is limited. For example, mechanical switches typically require a dedicated switch panel which might not easily be integrated into a shelving unit and might even need to be mounted remotely from the shelving unit. Moreover, because mechanical switches generally can control only a single function, a system wherein many functions need to be controlled requires the use of a like number of such switches. Thus, the use of mechanical switches is disadvantageous in shelving systems wherein space conservation is an important consideration.
Conventional shelving systems include numerous other disadvantages. For example, the depth of the shelves in conventional refrigerators and the disparate sizes of products stored thereon can make it cumbersome to take inventory of items in a refrigerator. This task is further complicated by the fact that conventional refrigerators typically use opaque doors, making it impossible to see the contents of the refrigerator without opening the door. As such, taking inventory requires opening the door, a practice that is not only inconvenient, but energy inefficient as well.
Another shortcoming involves illumination of shelving used in, for example, refrigerators. Conventional refrigerators typically include a convenience light somewhere in the interior cavity. Light can propagate from the light fixture, through the wire or glass shelves inside the compartment, to other shelves above or below. Light, however cannot propagate through opaque items placed on such shelves. As such, attempts to illuminate a refrigerator compartment using a single convenience light often achieve very limited success. One proposal to overcome this problem involves the installation of a convenience light under each such shelf for illuminating the space below. Although this solution helps put light where it is needed, a conventional light fixture mounted underneath a refrigerator shelf in a conventional manner is highly susceptible to failure due to infiltration by spilled liquids.
The present invention overcomes the foregoing limitations and provides an intelligent shelving system that permits efficient use of space by integrating touch sensor technology into power-operated shelving system design. A shelving system according to the present invention can include power-operated shelf adjustment and can incorporate spill detection, adaptive and intelligent operator/equipment interfacing, encapsulated lighting and other features as further described and claimed below.
Although many types of switching devices can be used as control inputs in accordance with the invention, preferred embodiments of the invention use touch input devices that respond to a user's touch or proximity for control input. Such touch input devices can include, for example, capacitive switches, infra-red touch sensors, and field effect sensors. Touch input devices can minimize many of the problems associated with mechanical switches and generally are more reliable, ergonomic and aesthetic. Also, a single touch input device can be more easily configured to selectively control several different functions.
While the drawings generally depict capacitive and electric field (or field effect) touch switches (or touch sensors) for the purpose of illustration, the principles of the present invention can be seen by those skilled in the art as appropriate for any manner of touch switch device, including, but not limited to, capacitive touch switches, infrared touch switches, electric field touch switches, acoustic touch switches and electromagnetic touch switches. Specific examples include the touch switches described in U.S. Pat. No. 5,594,222, No. 5,856,646, No. 6,310,611 and No. 6,320,282, each naming David W. Caldwell as inventor. The disclosures of the foregoing U.S. patents are hereby incorporated herein by reference. The disclosures of U.S. patent application Ser. No. 10/272,219, entitled Molded/Integrated Touch Switch/Control Panel Assembly and Method for Making Same (now U.S. Pat. No. 6,897,390), No. 10/272,377, entitled Touch Switch with Integrated Control Circuit, No. 10/272,047, entitled Touch Sensor with Integrated Decoration, and No. 10/271,438, entitled Integrated Touch Sensor and Light Apparatus, all filed on Oct. 15, 2002 and all naming David W. Caldwell as an inventor, also are hereby incorporated herein by reference.
Preferred embodiments of the present invention use touch sensors as control input devices. Touch sensors are solid state devices that respond to a user's touch or proximity. Touch sensors commonly include electrodes and electronic components mounted on a substrate. This substrate might have a user-accessible operative touch surface. Preferably, this touch surface is on the side of the substrate opposite the side that bears the touch sensor's electrodes and electronic components. In alternate embodiments, the operative touch surface can be on another substrate that is attached to or otherwise associated with the substrate bearing the touch sensor components. In either embodiment, a signal is supplied to the electrode(s), thus generating an electric field about the operative touch surface. When the electric field is disturbed by a user's touch or proximity, the touch sensor circuitry generates a control signal that can be used to control the operation of a light, motor or other end device.
Touch sensors overcome many disadvantages inherent to mechanical switches. For example, because a touch sensor's operative touch surface can be a non-perforated substrate, the touch sensor is much less susceptible to damage due to liquids and other foreign matter. Because a touch sensor has no moving parts, it is much less prone to wearing out. Because a touch sensor and its substrate can be (but need not be) substantially planar, problems related to the large profile of mechanical switches can be avoided, thus removing the design limitations that relatively large profile mechanical switches impart on the design of shelving systems and the like.
Many of the problems associated with mechanical switches, including the effects of contamination and space considerations, are particularly troublesome in shelving environments where relatively high levels of moisture or contaminants exist and where space is preferably conserved. This situation exists, for instance, in refrigerators, where moisture can condense on surfaces, where spills are likely, where food particles can be deposited on surfaces, where realizing maximum shelving space is a design goal and where the size of the overall shelving system is limited.
Use of power-operated shelves for a refrigerator is advantageous because the shelves of a refrigerator can bear numerous, disparately-sized and often unwieldy items. Shelf adjustment is therefore sometimes necessary, but difficult to achieve manually without removal of all or most of the items borne on the shelf. Use of touch switch controlled, power-operated shelves is particularly advantageous because touch switch assemblies have a low profile and, as discussed above, can prevent malfunctions owing to moisture and contaminants associated with mechanical switches that might otherwise be used in this application. The potential for malfunction of a mechanical switch due to contamination is heightened in this application because refrigerator shelves often bear liquids and foodstuffs that are prone to being spilled onto shelves and that can then drip through or around such shelves. Mechanical switches are particularly susceptible to short circuit failure under these conditions. Such malfunctions can be prevented by using touch sensors having a non-perforated touch surface substrate that can prevent liquids from reaching the touch sensor's electronic components.
According to the present invention, shelves can be movably mounted in any number of configurations as required by the particular application. Expected shelf load and dimensions and cost considerations, as well as the configuration of refrigerator 100 itself, dictate which mounting configuration or drive mechanism would be most advantageous. Shelving systems according to the present invention can include conventional fixed or manually adjustable shelves in addition to one or more power operated shelves, as depicted in
In the illustrated embodiments, shelves 10, 11, 12 each include two “hard keys” 30. In other embodiments, more or fewer hard keys can be used. Preferably, each hard key 30 includes an operative touch surface which can be touched by a user to actuate an underlying touch sensor. The touch sensor underlying a hard key 30, when triggered by user input, generates a control signal that controls a specific device in a predetermined manner. For example, a hard key 30 might be used to turn on a light on and off. Alternatively, a first hard key 30 might be used to cause a shelf to be raised, while another might be used to cause raise a shelf to be lowered.
In the illustrated embodiment, shelf 11 also includes “soft key” 31, each of which also includes an operative touch surface having an underlying touch sensor. Unlike a hard key 30, a soft key 31 does not necessarily control a specific device in a predetermined manner. Instead, a soft key 31 can be used to execute various control functions, for example, a function identified by a message prompt on an input/output display 233. Display 233 can display any variety of message prompts corresponding to functions that might be applicable to a particular system. A user desiring to execute the function corresponding to the message displayed on display 233 can do so by simply touching the appropriate soft key 31.
For instance, soft key 31 could serve as a confirmation key which could be used to execute a function corresponding to the message prompt when validation of a previously selected input might be required. For example, if a user tries to adjust a shelf outside predetermined limits, such as above a maximum height or to less than a minimum distance relative to another shelf, a safety mechanism might interrupt the execution of the input. In these situations input/output display 233 might prompt “Continue to raise this shelf” or simply “Continue.” The user would touch soft key 31 to continue to raise the shelf. Thus, soft keys are reconfigurable and can control functions that are dependent on the state of the system and the corresponding prompt of input/output display 233.
In
User input to the hard keys of
FIGS. 2B and 3A-3C depict shelf 11 of
Other kinds of information, status, or output devices could also be mounted on control panel 21 of shelves according to the present invention, and could be used in connection with the operation of the touch switch assemblies. For instance, lights mounted either beside or beneath operative touch surfaces could indicate either the presence of an operative touch surface or could signal to the user that an input has registered in the circuit to which the touch sensor is connected. Lights can be either LEDs, OLEDs, LEPs, light pipes, electroluminescent back-lighting, standard incandescent bulbs or any other suitable lighting, and can be configured, for example, according to the disclosure of U.S. Provisional Patent Application Ser. No. 60/341,551. Input/output display 233 can also be configured to present device information to a user, either simply as information, such as temperature or humidity levels, or as part of a message prompt soliciting a response.
An embodiment of input/output display 233 and its subcomponents is shown in detail in FIGS. 3A-B. Display board 133 is mounted on display board substrate 132 which, in turn, is affixed to control panel 21 using adhesive layer 134. Display board 133 displays messages and other information to the user. Display board 133 can be of any suitable construction depending on the requirements of the application. For instance, display board 133 could be a vacuum fluorescent display, liquid crystal display, electroluminescent display, electrophoretic display, polymer display, light emitting diode, or any other type display.
The touch switch electrical components are disposed on touch sensor substrate 36, which also defines operative touch surfaces 38. Substrate 36 is sufficiently transparent to allow a user to view messages on display board 133. In this embodiment, the touch switch electrical components include electrode 31, integrated control circuit 32 and circuit trace 39. Electrode 31 preferably is transparent to allow the message prompts of display board 133 to reach the user. Other touch sensor configurations and types are also suitable for use in connection with the present invention. For instance, control circuit 32 could be located remote from transparent electrode 31. Other types of touch sensors appropriate for use in connection with the present invention include, but are not limited to, electric field, capacitive, infra-red, differential touch sensors, or touch sensors and touch switch assemblies according to the disclosure of U.S. Provisional Patent Application Ser. No. 60/334,040.
Touch sensor substrate 36 can be decorated with decoration 136. Decoration 136 can be applied using, for example, the disclosure of U.S. Provisional Patent Application Ser. No. 60/341,551 and can be transparent and made of glass, plastic or other suitable material. In
Any of the touch switches corresponding to operative touch surfaces 38 can be configured as either a hard or a soft key. For instance, the touch sensors and operative touch surfaces labeled “1”-“3” could be configured as soft keys which could be used to effect control of whatever function the soft key represents at any given time. This function typically would be represented on the portion of display board 133 underlying a particular soft key. For example, portions of display board 133 underlying the touch surfaces 38 labeled as “1”-“3” in
Input/output display 233 can also include hard key touch sensors that can be configured to induce the vertical movement of shelf 12, or any other desired response, according to the particular design or application requirements. As shown in
In other embodiments, touch sensors and display panels could be located in places other than a shelving system's shelves. However, locating sensors and panels on the shelves themselves can advantageously prevent the confusion that might accompany a remote control panel and might obviate the otherwise needless labeling of particular touch surfaces as pertaining to particular shelves, while at the same time affording the user the flexibility of being able to control the movement or status of each shelf independently of others within the system.
As shown in
Other uses of touch sensors are also advantageous in shelving systems. For instance, touch or proximity sensors can be useful in configuring a shelving system that minimizes the risk of two power operated shelves coming too close together or of items on a lower shelf hitting the bottom side of a higher shelf within the system as the lower shelf is raised. To prevent this, a shelf could be equipped with touch sensors disposed on its underside. Such touch sensors could detect the encroachment of another shelf or of items borne by another shelf and signal to the shelf in motion to stop and/or reverse direction. These touch sensors could be of similar construction to those shown underlying hard keys. Such touch sensors could advantageously be designed for longer range stimulation than typical touch sensors or else could be stimulated by probes (not shown) attached to power operated shelves so as to stimulate the touch sensors before the shelf itself encroaches too close.
Other embodiments of the present invention include the power-operated touch switch controlled shelving system of an office workspace as shown in
The problems associated with mechanical switches are particularly troublesome in power-operated adjustable shelving systems where switches are subject to repeated and often careless or aggressive use, as, for instance, where a store's display indiscriminately tempts numerous consumers, and perhaps their curious children, to activate the switches that control the movement of shelves and the items they bear. In such situations, mechanical wear owing to repeated use of the switch is a problem, unless touch switch assemblies, which can minimize mechanical wear, are used. Thus, the use of touch switch assemblies in these, and other, shelving systems can alleviate the problems of the prior art.
Sometimes the items a shelving system must display are such as to require that direct access to the shelf is not feasible. This is the case, for instance, where the display items must be environmentally controlled, or where the items are especially valuable or fragile. The embodiment of the present invention depicted in
Display 233 depicted in
Various other features can be incorporated with shelving systems according to the present invention. For instance, the display can be used to provide information relating to one or more characteristics of items stored on the shelf, such as a description of the items, their size and price, the quantity of items stored on the shelf, and so on. In one embodiment, this information can be derived from data transmitted from devices such as RF ID tags (not shown) associated with the stored items to a receiver associated with the shelving system, as would be known to one skilled in the art. To conserve energy, the display could be activated by proximity sensors (not shown) responsive to a consumer's approach or according to some other input. For example, these sensors could cause the display to be activated or cause to be displayed thereon certain information when a potential consumer approaches the shelving system or otherwise provides an input to one or more touch sensors associated with the shelving system. This feature, i.e., the selective activation of displays, can also prove advantageous in other embodiments of the present invention. For instance, individual shelves or their displays could be proximity activated, or could include an activation key to turn on the display when touched. In all embodiments, information to be displayed can come from a location remote from the system or can be provided by sensors or other devices proximate or integral to the system.
The preceding drawings and descriptions serve to illustrate, but neither limit nor exhaust, the principles of the present invention. Various alterations to the embodiments described above are in keeping with the spirit of the invention and will be understood by those skilled in the art to be a part of the present invention as claimed below.
This application is filed as a continuation-in-part of, claims priority from, and incorporates by reference the disclosure of, U.S. patent application Ser. No. 10/271,933, filed on Oct. 15, 2002, which claims priority from, and incorporates by reference the disclosures of, U.S. Provisional Patent Application Ser. Nos. 60/334,040, filed on Nov. 20, 2001; 60/341,350, 60/341,550, and 60/341,551, all filed on Dec. 18, 2001; and 60/388,245, filed on Jun. 13, 2002. This application also claims priority from, and incorporates by reference the disclosure of, U.S. Provisional Patent Application 60/724,089, filed on Oct. 6, 2005.
Number | Date | Country | |
---|---|---|---|
60334040 | Nov 2001 | US | |
60341350 | Dec 2001 | US | |
60341550 | Dec 2001 | US | |
60341551 | Dec 2001 | US | |
60388245 | Jun 2002 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10271933 | Oct 2002 | US |
Child | 11544323 | Oct 2006 | US |