Fluid dispensers are commonly used in restaurants, factories, hospitals, and public bathrooms. These dispensers may contain fluids such as soap, anti-bacterial cleansers, disinfectants, lotions and the like. Some dispensers utilize some type of manual pump actuation mechanism wherein the user pushes or pulls a lever to manually dispense a quantity of fluid into the user's hands. “Hands-free” dispensers may also be utilized wherein the user simply places their hand underneath or in front of a sensor and an electromechanical pump mechanism dispenses a metered quantity of fluid. Related types of dispensers may be used to dispense powder or aerosol materials.
In some embodiments, a dispenser includes a replaceable refill cartridge or container (e.g., a bag, pouch, or tank) that is installed within the dispenser housing or attached to the dispenser (e.g., below a countertop) and is connected to a pump mechanism and an outlet port for dispensing the contents of the container. When the fluid in the container is depleted, the container is detached from the pump mechanism and a new, filled container is installed and attached to the pump mechanism.
In other embodiments, a dispenser includes a more permanent container or reservoir into which additional fluid is poured from an external fluid source (e.g., an external bottle, bag, or other refill container). This arrangement may be preferred for dispensers for which access to the fluid source is inconvenient (e.g., countertop mounted dispensers that store fluid beneath the counter) or undesirable (e.g., dispensers for which user maintenance of the dispenser, such as disassembly and/or replacement of components, is preferably minimized), or to allow for refilling of the dispenser fluid container from a larger, more economical external refill container.
A variety of mechanical and electronic mechanisms have been utilized to prevent replacement of a depleted installed refill container with an unauthorized or incorrect refill container, for example, to ensure the correct type and quality fluid is being provided, or to limit the source of replacement fluid to approved manufacturers or distributors. Examples of such mechanisms include mechanically, magnetically, electromechanically, or electronically keyed arrangements that require the refill container to have a proper connector or identifier (e.g., magnetic, electromechanical, or electronic identifier) to assemble with and/or enable functioning of the dispenser. Despite these measures, tactics for improper or unauthorized refilling of a dispenser remain, including reuse of an authorized refill container by injection of refill fluid into the container (often referred to as “stuffing” or “drill and fill”). Dispenser systems that utilize an external refill container are generally even more vulnerable to refilling with unauthorized or incorrect fluids, as the fluid may be added through the external refill supply port or directly into the reservoir (e.g., “drill and fill”).
The present application contemplates inventive systems and methods for monitoring and/or controlling dispenser fluid refill operations, using either or both of a replaceable internal refill container and a connectable external refill container.
In an exemplary embodiment of the present application, a counter mountable fluid dispenser includes a below deck reservoir for storing a fluid comprising at least one of a soap, an anti-bacterial cleanser, a disinfectant, and a lotion, an above deck spout including an outlet port in fluid communication with the reservoir for dispensing fluid stored in the reservoir and an external supply port connected with the reservoir by a supply passage to supply fluid to the reservoir, a supply access valve connected with the supply passage and operable to block flow from the external supply port to the reservoir in a closed position and to permit flow from the external supply port to the reservoir in the open position, and a controller in communication with the supply access valve for controller operation of the supply access valve from a closed position to an open position in response to receipt of an authorized supply signal at the controller.
In another exemplary embodiment of the present application, a fluid dispensing system includes an external refill container and a fluid dispenser. The external refill container stores a refill fluid comprising at least one of a soap, an anti-bacterial cleanser, a disinfectant, and a lotion, and includes a first connector and a memory storage device storing identification data. The fluid dispenser includes a below deck reservoir for storing a fluid and an above deck spout including an outlet port in fluid communication with the reservoir for dispensing fluid stored in the reservoir and an external supply port connected with the reservoir by a supply passage to supply fluid to the reservoir. The external supply port includes a second connector connectable with the first connector to supply the refill fluid to the reservoir. The fluid dispenser further includes a controller in communication with the memory storage device at least when the second connector is connected with the first connector for transmitting the identification data to the controller.
In another exemplary embodiment of the present application, a refill container includes a container body storing a refill fluid comprising at least one of a soap, an anti-bacterial cleanser, a disinfectant, and a lotion, a self-sealing quick disconnect connector secured to the container body, and an RFID transponder disposed in or on the connector.
These and other features and advantages of the present invention will become better understood with regard to the following description and accompanying drawings in which:
The Detailed Description merely describes exemplary embodiments of the invention and is not intended to limit the scope of the claims in any way. Indeed, the invention is broader than and unlimited by the exemplary embodiments, and the terms used in the claims have their full ordinary meaning.
Also, while certain exemplary embodiments described in the specification and illustrated in the drawings relate to externally filled counter-mounted fluid dispensers and external refill containers for hand hygiene applications, and systems and methods for monitoring and controlling external refilling of hand hygiene dispenser devices, it should be understood that many of the inventive features described herein may be applied to other devices, systems, and methods. For example, the features described herein may be utilized in other dispensing arrangements (e.g., internal refill cartridge based dispensers, wall mounted dispensers, stand mounted dispensers, standalone dispensers, tabletop dispensers, portable dispensers), dispensers for other types of fluids (e.g., sunscreen, pharmaceuticals), dispensers of solid materials (e.g., powders, particulate), and other types of containment devices.
“Circuit communication” indicates a communicative relationship between devices. Direct electrical, electromagnetic and optical connections and indirect electrical, electromagnetic and optical connections are examples of circuit communication. Two devices are in circuit communication if a signal from one is received by the other, regardless of whether the signal is modified by some other device. For example, two devices separated by one or more of the following—amplifiers, filters, transformers, optoisolators, digital or analog buffers, analog integrators, other electronic circuitry, fiber optic transceivers or satellites—are in circuit communication if a signal from one is communicated to the other, even though the signal is modified by the intermediate device(s). As another example, an electromagnetic sensor is in circuit communication with a signal if it receives electromagnetic radiation from the signal. As a final example, two devices not directly connected to each other, but both capable of interfacing with a third device, such as, for example, a CPU, are in circuit communication.
“Logic,” as used herein, is synonymous with “circuit” or “circuitry” and includes, but is not limited to, hardware, firmware, software and/or combinations of each to perform a function(s) or an action(s). For example, based on a desired application or needs, logic may include a software controlled microprocessor or microcontroller, discrete logic, such as an application specific integrated circuit (ASIC) or other programmed logic device. Logic may also be fully embodied as software. The circuits identified and described herein may have many different configurations to perform the desired functions.
“Signal,” includes, but is not limited to one or more electrical signals, analog or digital signals, one or more computer instructions, a bit or bit stream, or the like.
Any values identified in the detailed description are exemplary and they are determined as needed for a particular dispenser and/or refill design. Accordingly, the inventive concepts disclosed and claimed herein are not limited to the particular values or ranges of values used to describe the embodiments disclosed herein.
An exemplary aspect of the present application involves systems and methods for monitoring and controlling the refilling of a fluid dispenser, for example, to prevent filling the dispenser with improper or incorrect fluids, or by unauthorized individuals. In one such embodiment, an externally filled hand cleaning fluid dispenser is configured to monitor and control refilling of the fluid dispenser from an external refill container by identifying and/or preventing unauthorized or improper refill attempts. As used herein, an “externally filled fluid dispenser” includes any dispenser for which an internal reservoir is refilled by supplying fluid (e.g., from an external refill container) to an external supply port that is connected with or in fluid communication with the reservoir, as compared to a fluid dispenser that houses a replaceable or removable internal fluid refill container or cartridge, for which the fluid dispenser housing must be opened or removed for removal and replacement or refilling of the internal refill container. An externally filled fluid dispenser arrangement may be desirable for counter mounted dispensers having a spout or nozzle portion and external supply port mounted above a counter (or “above deck”) and a fluid containing portion (e.g., reservoir) mounted below the counter (or “below deck”), for example, to eliminate the need for below-counter access to the dispenser for refilling.
While the external supply port may include an open port continuously accessible for refilling the reservoir (e.g., by pouring refill fluid directly into the external supply port from a bulk container), in some embodiments, it may be desirable to restrict access to the external supply port and/or the supply passage to prevent the supply of incorrect or unauthorized fluids to the reservoir. For example, in one embodiment, an access door (shown schematically at 72) may be provided over the external supply port 70. The access door 72 may include a locking or latching mechanism (e.g., mechanically, electromechanically, electronically), shown schematically at 73, to secure the access door 72 in a closed position covering the external supply port 70, for example, to prevent unauthorized access to the external supply port, and/or to prevent inadvertent or unintentional exposure of the supply port. In an exemplary embodiment (described in greater detail below), the spout portion of the dispenser may include an access door panel that is movable (e.g., slideable, pivotable) to expose an external supply port carried by the spout portion. The access door may be unlocked using a variety of arrangements, including, for example, a mechanical key or other insertable tool, a keypad entered combination code, or an RFID or other wireless unlocking code. In some embodiments, an unlocking element (e.g., code carrying RFID tag) may be carried by the external refill container, such that an authorized external refill container must be brought into proximity with the access door locking mechanism to open the access door. In other embodiments, the unlocking element may be a separate user-carried component (e.g., a mechanical key or electronic (e.g., RFID) key card.
In another embodiment, the external supply port 70 of the dispenser 20 may additionally or alternatively include a keyed, self-sealing connector (e.g., a keyed quick disconnect fitting member), shown schematically at 74, that connects with a corresponding keyed, self-sealing connector 94 on the external refill container 90, while preventing an open-flow connection with non-keyed or incorrectly keyed external containers. This arrangement would prevent a user from simply pouring refill fluid into the open or exposed external supply port 70 to refill the reservoir 30, or from supplying refill fluid from an unauthorized or incorrect (i.e., non-keyed or incorrectly keyed) container. The keying mechanism of the connectors may, for example, be mechanically, magnetically, or electromechanically operable.
In still another embodiment, an external refill container may include an electronic keying mechanism configured to transmit an authorized supply data signal to a controller in the dispenser, to initiate controller operation of a supply valve to permit the flow of refill fluid supplied to the external supply port to pass to the reservoir. In the schematically illustrated exemplary embodiment of
An external refill container may utilize many different electronic keying mechanisms for communicating an authorized supply signal to the controller of the dispenser. In an exemplary embodiment, an RFID transponder tag 95 is located in or on the connector 94 of the container 90, and is arranged to transmit an authorized supply signal to a receiver 65 housed in the above deck spout portion 60 of the dispenser 20, with the receiver 65 being in wired or wireless circuit communication with the controller 50 disposed in the below deck housing 41. The proximity of the transponder tag 95 to the receiver 65 allows for the use of a passive RFID transponder tag, and the use of short range, low power RFID communication (e.g., Near Field Communication, Bluetooth® LE communication) between the transponder tag and the receiver. Further, the receiver may remain inactive (e.g., disconnected from a power source) until it is activated by a switch mechanism 75 triggered by opening the access door 72 to the external supply port 70, and/or connecting the external refill container connector 94 to the external supply port connector 74. Upon activation, the receiver 65 transmits an interrogation signal to the RFID transponder tag 95, and the transponder tag responds with transmission of the authorized supply data signal to the receiver 65. The receiver 65 transmits the authorized supply data signal to the controller 50 for evaluation of the data signal, and the controller actuates the supply valve to open the supply valve. The switch mechanism 75 may additionally or alternatively function to temporarily disable the dispensing mechanism 40, such that a person refilling the reservoir 30 does not unintentionally actuate the dispensing mechanism (e.g., due to proximity to sensor(s) of the user interface 80).
The authorization data signal may include one or more codes or other information that may be relevant to whether fluid from the corresponding container should be permitted to be supplied to the dispenser reservoir. For example, a unique serial code may be used to identify a specific batch of refill fluid being supplied, a product code may be used to identify the type of fluid stored in the refill container, and a distributor or manufacturer code may be used to identify the source of the fluid (e.g., to identify the supplier as an authorized distributor or manufacturer). A date code may identify the age of the fluid (e.g., to prevent refilling the dispenser with an expired fluid).
According to another aspect of the present application, the electronic keying mechanism 95 of the external refill container 90 may include a writeable memory storage device 96, such that the controller 50 may transmit to the keying transceiver 95, for storage in the memory storage device 96, additional usage information that may be relevant to future usage of the external refill container. As one example, where an external refill container is intended for a single use, the dispensing system may be configured such that once the external refill container has been connected to the dispenser to supply refill fluid to the dispenser, with the keying transceiver 95 placed in circuit communication with the dispenser controller 50, the dispenser controller transmits an invalidating data signal to the keying transceiver to write an invalidating code to (or to erase an authorization code from) the memory storage device, to prevent unauthorized re-use of the refill container 90. The disabled refill container may be configured to be recycled and reset by an authorized user or administrator by erasing the invalidating code or writing a new authorization code to the memory storage device.
As another example, where unauthorized refilling of the external refill container 90 is prohibited, the dispensing system may be configured such that the dispenser controller 50, through data signals received from a fill level sensor 55, determines a fill level of the refill container, or an amount of fluid supplied from the refill container into the reservoir 30, and writes to the writeable memory storage device 96 data corresponding to a current fill level of the refill container. In a subsequent use of the external refill container 30, a dispenser controller measurement indicating an increased refill container fill level provides an indication that the external refill container 90 has been improperly refilled. In response to identifying an improper refilling of the container, the controller 50 may provide an alert, locally (e.g., audible alarm tone, display panel warning light on the user interface 80) and/or remotely (e.g., cell phone text alert, alert transmission to a central computer system). Additionally or alternatively, the controller may temporarily (e.g., until an administrator reset or override is performed) disable the pumping mechanism 40 to prevent use of the dispenser 20, and/or maintain the supply valve 36 in the closed position to prevent further refilling of the reservoir 30. Still further, the controller 50 may transmit an invalidating data signal to the container's keying transceiver 95 to write an invalidating code to (or to erase an authorization code from) the container's memory storage device 96, to prevent subsequent use of the refill container 90.
Many different arrangements may be used to measure a fill level of the external refill container 90. As one example, the fill level of the external refill container may be measured directly, for example, by measuring the weight of the external refill container (and subtracting the known weight of the container itself). The weight of the external refill container may be measured using, for example, a strain gauge, force sensitive resistor, potentiometer, optic sensor, or other weighing sensor technology disposed on the external refill container or in the portion of the dispenser supporting the connected refill container (e.g., within the spout portion). The weight sensor may be configured to continuously or periodically measure the weight of the external refill container, or to measure the weight of the external refill container in response to specific refilling operations (e.g., when the external refill container is initially connected to the dispenser's external supply port prior to supplying fluid, and/or when the external refill container is initially disconnected from the dispenser's external supply port after supplying fluid). In one such embodiment, when the connector of the external refill container is initially connected with the connector of the dispenser's external supply port, the dispenser controller measures a current weight of the external refill container (based on data signals from the weight sensor) and compares the current weight to stored weight data from the refill container's memory storage device, to identify an improper refilling of the container indicated by an increase in the refill container weight (and to initiate one or more of the notification or disabling operations described above). When the connector of the external refill container is disconnected from the connector of the dispenser's external supply port (e.g., by pressing a release button on the dispenser spout portion, as described in greater detail below), the dispenser controller measures a current weight of the external refill container (based on data signals from the weight sensor) and writes current weight data to the refill container's memory storage device, which may replace the previously stored weight data.
In another embodiment, the fill level of the external refill container may be determined based on a known initial or previously determined refill container fill level, and an increase in the fill level of the reservoir as the external refill container supplies fluid to the reservoir, as being equivalent to the corresponding decrease in the refill container fill level. The weight of the reservoir may be measured using, for example, a strain gauge, force sensitive resistor, potentiometer, optic sensor, or other weighing sensor 55 disposed on the reservoir or on the below deck portion of the dispenser that supports the reservoir. The weight sensor 55 may be configured to continuously or periodically measure the weight of the reservoir 30 (e.g., taking into account known weights of the other dispenser components exerting a load on the weight sensor), or to measure the weight of the reservoir in response to specific refilling operations (e.g., when the external refill container 90 is initially connected to the dispenser's external supply port 70 prior to supplying fluid, and/or when the external refill container is initially disconnected from the dispenser's external supply port after supplying fluid). In one such embodiment, when the connector 94 of the external refill container 90 is initially connected with the connector of the dispenser's external supply port, the dispenser controller 50 begins frequent (e.g., once per second) measurements of the current weight of the reservoir (based on data signals from the weight sensor 55). The controller compares the change in the reservoir weight (due to added refill fluid) to stored weight data from the refill container's memory storage device 96 to identify an improper refilling of the container indicated by a reservoir weight increase that exceeds the previous refill container weight (and to initiate one or more of the notification or disabling operations described above). When the connector 94 of the external refill container 90 is disconnected from the connector 74 of the dispenser's external supply port (e.g., by pressing a release button on the dispenser spout portion, as described in greater detail below), the dispenser controller 50 measures a current weight of the reservoir 30 (based on data signals from the weight sensor 55) and writes current weight data to the refill container's memory storage device 96 corresponding to the previous refill container weight less the measured increase in the reservoir weight, with the current weight data replacing the previously stored weight data.
Monitoring the weight of the reservoir 30 may be useful to identify additional conditions of interest in the dispenser 20. As one example, a measured reservoir weight below a predetermined threshold may be used to identify a low fluid condition, for example, to provide a local or remote alert that a refill of the fluid is needed. In an exemplary embodiment, a user interface actuation of the dispensing mechanism triggers a controller reading of the weight sensor data to check for a below-threshold reservoir weight indicating a low fluid condition. In response to detection of the low fluid condition, the controller 50 initiates an alert notification (e.g., powering an LED indicator light on the user interface 80). As another example, an increase in the measured reservoir weight while the supply passage 35 is closed (e.g., closed access door 72, closed supply valve 36) and/or while no authorized supply data signal has been received would indicate that the supply passage 35 is being bypassed or otherwise tampered with to improperly refill the reservoir 30, for example, by injecting refill fluid directly into the reservoir or into the below deck portion of the supply passage (e.g., tubing or hose), often referred to as a “drill and fill” procedure. Upon identifying a drill and fill event, the controller 50 may initiate one or more of the notification or disabling operations described above.
In the illustrated embodiment, an external supply port 170 (
The external supply port 170 includes a quick disconnect socket 174 connected with a supply passage 135 extending to the reservoir 130. The quick disconnect socket 174 is configured for interlocking connection with a corresponding quick disconnect plug 194 disposed on the external refill container 190 (e.g., threaded onto an end port of the refill container, see
To further safeguard against the supplying of incorrect or unauthorized refill fluid to the reservoir 130, the pump housing assembly 140 of the dispenser 120 includes a supply valve 136 disposed along, and defining a portion of, the supply passage 135. When the supply valve 136 is in the closed position, a refill fluid supplied to the external supply port 170 is blocked within the supply passage 135 by the closed supply valve, even when supplied by a refill container having the correct quick disconnect plug or other such keyed connector. To open the supply valve 136 and permit the supplying of refill fluid from the refill container 190 to the reservoir 130, the refill container is provided with an electronic keying mechanism that communicates authorization data to a dispenser controller 150 disposed in the pump housing 141 (formed by housing members 141a, 141b, 141c, as shown in
In the illustrated embodiment, a collar-shaped RFID transceiver 195 is assembled with the quick disconnect plug 194 of the refill container 190, and is positioned for short range, low power RFID communication (e.g., Near Field Communication) with a corresponding RFID transceiver 165 disposed in the external supply port 170. The supply port transceiver 165 receives refill container data (e.g., corresponding to supplier identifying distributor codes, fluid and/or container identifying serial numbers, and fluid fill level data) from the refill container transceiver 195, and transmits this data (e.g., by wired circuit communication) to the controller 150. Once the controller 150 verifies that the refill container 190 is from the correct supplier (e.g., by verifying the distributor code stored in the memory of the transceiver), contains the correct fluid (e.g., by verifying the serial number or product code stored in the memory of the transceiver), and/or contains sufficient fluid for refilling (e.g., by checking the fluid fill level data stored in the memory of the transceiver), the controller 150 initiates actuation of the supply valve 136 from a closed position blocking flow from the quick disconnect socket 174 to the reservoir 130 to an open position permitting flow from the quick disconnect socket 174 to the reservoir 130.
Many different types of electrically actuated supply valves may be utilized. In the illustrated embodiment, the supply valve 136 is a solenoid actuated two-way shutoff valve. One such example is a two-way diaphragm shutoff miniature “nano” valve actuated by a latching 6 VDC solenoid (manufactured by RPE Ltd. in Carbonate, Italy).
To trigger RFID communication when the access door 172 is opened (e.g., to prevent continuous power consuming RFID transmissions from the supply port transceiver when the supply port is not in use), the supply port transceiver 165 includes a reed switch 177 (see
The reed switch 177 may additionally or alternatively function to temporarily disable the dispensing mechanism 142, such that a person refilling the reservoir 130 does not unintentionally actuate the dispensing mechanism (e.g., due to proximity to sensor(s) of the user interface 180).
The refill container transceiver 195 includes a writeable memory storage device (not shown), such that the below deck controller 150 may transmit (through the supply port transceiver 165) to the refill container transceiver 195, for storage in the memory storage device, additional usage information that may be relevant to future usage of the external refill container 190. As discussed above, data transmitted to the refill container transceiver 195 for storage in the memory storage device may include, for example, fill level data based on the weight change of the dispenser reservoir 130 while the external refill container 190 is connected with the supply port 170 (e.g., as determined by wireless communication between the supply port transceiver 165 and the refill container transceiver 195), or an invalidating code in response to an indication that the external refill container has been improperly reused and/or refilled.
In the illustrated embodiment of
When the connector 194 of the external refill container 190 is initially connected with the connector of the dispenser's external supply port, the dispenser controller 150 begins frequent (e.g., once every second) measurements of the current weight of the reservoir (based on data signals from the strain gauge 155). The controller compares the change in the reservoir weight (due to added refill fluid) to stored weight data from the refill container's memory storage device to identify an improper refilling of the container indicated by a reservoir weight increase that exceeds the previous refill container weight (and to initiate one or more of the notification or disabling operations described above). After each weight sensor measurement (e.g., once every second) the controller 150 may transmit the weight data to the refill container's memory storage device for storage of refill container weight data corresponding to the previous refill container weight less the measured increase in the reservoir weight, with the current weight data replacing the previously stored weight data. Alternatively, the weight data may be transmitted to the refill container less frequently, such as, for example, only when the refill procedure has completed. For example, when the connector 194 of the external refill container 190 is disconnected from the connector 174 of the dispenser's external supply port 170, by pressing the release button 166 on the dispenser spout portion 160, the dispenser controller 150 may be triggered or activated to measure a current weight of the reservoir 130 (based on data signals from the strain gauge 155) and transmits current weight data to the refill container's memory storage device corresponding to the previous refill container weight less the measured increase in the reservoir weight, with the current weight data replacing the previously stored weight data.
The pump housing assembly 140 includes a pump mechanism 142 disposed in the pump housing 141. While many different types of pump mechanisms may be utilized, in the illustrated embodiment, the pump mechanism includes a piston displacement pump 143 (e.g., a piston displacement foaming pump) actuated by a gear motor 144 that drives a cam 145 to rotate an actuator arm member 146 which reciprocates to actuate a lift member 147 secured with an outlet member 148 of the pump 142. The motion is terminated by an end-of-stroke switch (not shown).
A touch free sensor-based user interface 180 is disposed on a front portion 161a the spout shell 161. The exemplary user interface 180 includes a touch free sensor arrangement 185, with an infrared light emitting diode 186 and light detecting photo diode 187 that senses changes in the reflected light resulting from positioning of a user's hand under the spout. A microcontroller 184 in the user interface transmits an actuation signal to the below deck controller 150 to initiate operation of a pump motor, described in greater detail below. The pump mechanism may be activated within a brief predetermined time period (e.g., about 200 ms) after the user's hand passes within a detection range (or activation zone) of the sensor arrangement 185, to dispense a predetermined dose of fluid in the user's hand. To prevent excess dispensing of fluid, the user interface microcontroller may be configured to require an empty activation zone for a predetermined time period (e.g., about 0.12 seconds) before transmitting a new actuation signal in response to a subsequent detection of a user's hand in the activation zone. The user interface may further include a maintenance indicator light 188 to provide an indication of a dispenser condition requiring attention (e.g., low fluid, low battery, tampering indication).
The below deck controller 150 is in circuit communication with the user interface 180 and the pump mechanism 142. When the controller 150 receives an actuation signal from the user interface 180 (e.g., corresponding to detection of a user's hand in proximity with the sensor arrangement 185), the controller initiates operation of the pump mechanism 142 to dispense fluid from the reservoir 130 through the dispense passage 133 to the outlet port 163. Actuation of the pump mechanism 142 may also trigger a strain gauge 155 measurement of the fluid fill level, to check for a below-threshold reservoir weight indicating a low fluid condition. In response to detection of the low fluid condition, the controller 150 initiates an alert notification (e.g., powering an LED indicator light on the user interface 180). The controller 150 may also compare the measured reservoir weight to a most recent measured reservoir weight. An increase in the measured reservoir weight while the supply passage 135 is closed (e.g., closed access door 172, closed supply valve 136) and/or while no authorized supply data signal has been received would indicate that the supply passage 135 is being bypassed or otherwise tampered with to improperly refill the reservoir 130. Upon identifying such an event, the controller 150 may initiate one or more of the notification or disabling operations described above.
While various inventive aspects, concepts and features of the inventions may be described and illustrated herein as embodied in combination in the exemplary embodiments, these various aspects, concepts and features may be used in many alternative embodiments, either individually or in various combinations and sub-combinations thereof. Unless expressly excluded herein all such combinations and sub-combinations are intended to be within the scope of the present inventions. Still further, while various alternative embodiments as to the various aspects, concepts and features of the inventions—such as alternative materials, structures, configurations, methods, circuits, devices and components, software, hardware, control logic, alternatives as to form, fit and function, and so on—may be described herein, such descriptions are not intended to be a complete or exhaustive list of available alternative embodiments, whether presently known or later developed. Those skilled in the art may readily adopt one or more of the inventive aspects, concepts or features into additional embodiments and uses within the scope of the present inventions even if such embodiments are not expressly disclosed herein. Additionally, even though some features, concepts or aspects of the inventions may be described herein as being a preferred arrangement or method, such description is not intended to suggest that such feature is required or necessary unless expressly so stated. Still further, exemplary or representative values and ranges may be included to assist in understanding the present disclosure; however, such values and ranges are not to be construed in a limiting sense and are intended to be critical values or ranges only if so expressly stated. Moreover, while various aspects, features and concepts may be expressly identified herein as being inventive or forming part of an invention, such identification is not intended to be exclusive, but rather there may be inventive aspects, concepts and features that are fully described herein without being expressly identified as such or as part of a specific invention. Descriptions of exemplary methods or processes are not limited to inclusion of all steps as being required in all cases, nor is the order that the steps are presented to be construed as required or necessary unless expressly so stated.
This application is a continuation of U.S. patent application Ser. No. 16/441,680, entitled “SYSTEMS AND METHODS FOR MONITORING AND CONTROLLING DISPENSER FLUID REFILL,” filed Jun. 14, 2019, which claims priority to and the benefit of U.S. patent application Ser. No. 15/426,447, entitled “SYSTEMS AND METHODS FOR MONITORING AND CONTROLLING DISPENSER FLUID REFILL,” filed Feb. 7, 2017, issued as U.S. Pat. No. 10,358,335, which claims priority to and the benefit of U.S. patent application Ser. No. 15/398,170, entitled “SYSTEMS AND METHODS FOR MONITORING AND CONTROLLING DISPENSER FLUID REFILL,” filed Jan. 4, 2017, issued as U.S. Pat. No. 10,189,698, which claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 62/274,982, entitled “SYSTEMS AND METHODS FOR MONITORING AND CONTROLLING DISPENSER FLUID REFILL,” filed Jan. 5, 2016, the entire disclosures of which are incorporated herein by reference.
Number | Date | Country | |
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62274982 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 16441680 | Jun 2019 | US |
Child | 17198637 | US | |
Parent | 15426447 | Feb 2017 | US |
Child | 16441680 | US | |
Parent | 15398170 | Jan 2017 | US |
Child | 15426447 | US |