The present invention relates to ice dispensing, and in particular to an improved apparatus for and method of dispensing selected quantities of ice.
It is known to provide ice dispensers that dispense selected quantities of ice. One such ice dispenser forms the subject matter of U.S. Pat. No. 4,921,149, which is assigned to IMI Cornelius, Inc., the assignee of the present application and the teachings of which patent are specifically incorporated herein by reference. Said patent teaches an ice portion control for an ice dispenser in which a chute has an upper end into which ice is introduced and a lower end from which ice is dispensed. A dispensing gate normally closes the lower end of the chute, and with the chute filled with ice, to vend a desired quantity of ice, the dispensing gate is opened for a selected one of a plurality of timed periods of durations selected to dispense from the chute associated predetermined quantities of ice. Adjusting the durations of the timed periods varies the quantities of ice vended.
In a commercial embodiment of an ice portion control for an ice dispenser embodying the teachings of said U.S. Pat. No. 4,921,149, an ice chute receives ice from a storage bin through a permanently open ice outlet passage in the bin. An agitator in the bin pushes ice from the bin through the passage and into the upper end of the chute to fill the chute with ice, which ice is then dispensed from the chute by controlling an ice outlet opening at a lower end of the chute. When the chute is filled with ice, vending is achieved by opening a gate at the chute lower end for durations of time selected to flow predetermined quantities of ice out of the chute lower opening. The quantity of ice dispensed is determined by the time the gate is maintained open, and the agitator in the bin is operated for a time selected to refill the chute with a quantity of ice generally equal to that dispensed. Programming implemented through electronics with set protocols and values is employed in determining both the time durations of opening of the gate at the lower end of the ice chute for ice dispense and the time durations of operation of the agitator in response to ice dispensing to push ice in the bin through the bin passage and into the upper end of the chute to refill the chute. The ice portion control system employs pneumatics to open the gate at the lower end of the ice chute, while the top of the chute is permanently open and always in communication through the passageway with ice in the bin.
While the concept works well in the commercial embodiment, the ice chute is attached to the dispenser and needs to be removed periodically to provide for cleaning and sanitation. The manner in which the ice chute is attached makes it somewhat difficult to remove and reinstall, as parts of the attachment mechanism are not easily visible and require a service technician to work somewhat blindly. Further, the amount of ice in the chute is not easily viewed by a user, with the result that the user can not determine, before dispensing ice, whether a sufficient amount of ice is available in the chute to satisfy the dispense.
Additionally, as customers often wish to put a lid on a cup into which a drink has been dispensed, cup lid holders were secured to the front of the ice and beverage dispenser. Often attachment of the cup lid holders to the ice and beverage dispenser front face further limited access to and visibility of the ice dispenser, making it more difficult to service the dispenser and view the ice and beverage dispensing operations and limiting customer ability to see what is occurring. While not every ice and beverage dispense was affected, occasionally beverages and/or ice were overflowed or spilled. The result was that the dispenser required more maintenance in order for it and the surrounding area to be keep clean, and also beverages and ice were wasted, which increased costs and reduced profits.
Further, in the commercial version, ice dispense is controlled by a gate that is moved to a closed position and held closed by a spring in an air cylinder, and then opened by application of air pressure to the cylinder. The spring closure is not controllable and on occasion can cause the gate to snap shut, resulting in a pinched finger and possible injury to a user.
An object of the present invention is to provide an improved ice dispense system for an ice dispenser, which accurately dispenses selected predetermined quantities of ice.
Another object is to provide such an ice dispense system having an ice dispense chute that is easily removable from an ice and beverage dispenser on which it is mounted to facilitate cleaning of both the chute and the ice and beverage dispenser.
A further object is to provide such an ice dispense system having electronics that perform a self-diagnostic test of the system every time it is turned on.
Yet another object is to provide such an ice dispense system that is user programmable to precisely control both the quantities of ice dispensed and the quantities of ice introduced into the ice chute to refill the chute following a dispense.
A yet further object is to provide such an ice dispense system having visual displays to assist a user in programming the system.
A still further object is to provide such an ice dispense system having a gate that is moved between ice chute closing and opening positions by a dual acting pneumatic cylinder that is pneumatically driven in both directions.
A yet further object is to provide such an ice dispense system in which clearance is maintained between a gate that closes a lower end of an ice chute, and in which the force with which the gate is driven to its chute closing position is limited in order to provide safety for a user of the system.
The present invention provides an ice and beverage dispenser which has a forwardly extending ice chute that is fastened to the dispenser by means that are visible to a user and easily operated. The ice chute has a transparent front cover that allows a user to visually see the amount of ice in the chute, both before and after an ice dispense, and has a diverging shape from top to bottom to ensure that ice traveling through the chute does not jam or stick in the chute. The ice chute and dispenser are constructed so that the ice chute front cover may conveniently, with one hand of a user, be removed from the dispenser for cleaning and then easily replaced. Service and cleaning of the ice chute is much more easily accomplished in a shorter period of time, which is particularly advantageous since regular cleaning of the ice chute is usually mandated by various sanitation codes and regulations.
Additional novel features of the ice portion control system of the invention include the following:
Powering up the unit initiates a self-diagnostic test that interrogates a control circuit and keypad interface for the control circuit The interrogation checks the state of values stored in a microprocessor and inputs/outputs to and from the control circuit A keypad interface test interrogates the state of the keypad by checking the open/closed loop resistance values of various button switches on the keypad, and the resistances measured are compared with predetermined resistance valves.
Ice stored in a bin is introduced into an upper end of the ice chute to be dispensed from a lower end of the chute. To ensure a constant and consistent dispense of ice, a relationship is established between the time a gate at the lower end of the ice chute is opened to dispense a predetermined quantity of ice and the time required for an agitator in the ice bin to be operated to push the same predetermined quantity of ice from the bin into the upper end of the ice chute to refill the chute following a dispense of ice. This relationship is a proportional relationship incorporating an integer constant that can be changed by the user through a programming mode in order to accommodate differences in quantities of ice dispensed from the chute and quantities of ice introduced into the chute to refill the chute. Increasing such constant results in an increase in the time spent operating the agitator to push ice from the storage bin into the upper end of the chute to refill the chute, while decreasing the constant decreases agitator operating time and thereby decreases the amount of ice pushed into the upper end of the chute. These adjustments allow the user to compensate for different types of ice that have different dispense flow rates from the bin and through the lower outlet from the chute.
To ensure that the ice dispenser is intuitive and easy to use, it is provided with visual indicators, such as LEDs that accommodate convenient and accurate visual programming of the dispenser. The LEDs are used during programming modes of the ice dispenser to visually inform the user as to predetermined upper and lower limits of programming. Such programming is employed, for example, to set ice chute dispense and ice chute refill times for selected quantities of ice, i.e., to set the various opening times of an ice dispense gate at a lower end of the ice chute and the associated operation times of an ice bin agitator that pushes ice from the bin into the upper end of the chute to refill the chute following an ice dispense. These times can be adjusted based upon a user's specific applications and requirements. Another visual indicator is a service LED that informs the user at any point in time what state the ice dispense unit is in. A further visual indicator is used to inform the user as to what operational mode the ice dispense unit is in, which operational modes may be automatically or manually implemented and are differentiated by specific lighting conventions.
To improve the reliability of an interface by means of which a user initiates a predetermined ice dispense, flat membrane keypad technology is employed. The flat membrane keypad is fully flat and flush for convenient activation by the user. Feedback provided by the keypad is non-tactile and consists of audible noises from the ice dispenser as it operates in response to a keypad input The flat membrane keypad is submersible, so it may be cleaned without suffering delamination or other damage. The flat membrane keypad works by sensing a change in a resistance value across the keypad upon the user pressing a desired ice portion size button.
The front cover of the ice chute incorporates quick release and indexing tab features that allow the user to use one hand to remove the cover for cleaning. This ensures that the cover can conveniently be removed daily for cleaning, and the quick release and indexing tab features are easy and intuitive to use.
To open and dose an ice dispense gate at a lower ice outlet opening from the ice chute, a pneumatics system is used and incorporates a dual-acting pneumatic cylinder that is activated to both open and close the ice dispense gate. The cylinder is mounted in a horizontal orientation at the lower end of the ice chute, so that any moisture or condensate originating from the ice chute cannot drip onto and run down the rod or nose of the cylinder. To avoid injury to the user, the pneumatic system has a protective cover to protect a user's fingers from accidentally coming into contact with the cylinder. In addition, another safety feature consists of providing the ice dispense gate with a size and configuration so that, when it is closed, a gap exists between it and the ice chute interior to ensure that if the gate closes while the user's fingers are in the lower end of the ice chute, severe damage to the user's fingers will not occur.
As a further safety feature for the pneumatic system, a pressure relief valve is upstream of the air supply to the pneumatic cylinder to prevent the cylinder from exerting a closing force on the ice dispense gate that is greater than an allowable predetermined closing force, thereby to further mitigate the potential for severe damage to a user's fingers. Also, the pneumatic system is provided with a manual bypass system, so that should the system fail in the closed position of the ice dispense gate, the user can manually bleed air out of the system and enable the ice dispense unit to be manually operated for continued dispensing of ice to customers.
The ice portion and control system is particularly adapted for use on an ice and beverage dispensing machine to ensure constant and consistent delivery of ice and beverages to customers. The system incorporates unique features that provide a greater ability to conveniently and thoroughly clean the system and an improved ergonomic design to enable better access to beverage valves of the ice/beverage dispenser and the ice chute. Such ergonomic design features include a one piece merchandiser that accommodates attachments to the merchandiser, which attachments can be removed to allow the exposed surface of the merchandiser to be readily cleaned with no dead spots; easier access to and better visibility of the beverage dispensing valves and ice chute with no intrusions; and a visually less intrusive design with a unique front side profile.
Further, as the ice chute and the ice dispense point are more easily viewed by a user, beverage and/or ice dispenses may be made with less spillage and waste and, therefore, greater profit and customer satisfaction.
Ease of service and customer ease of use are increased by a cup lid dispenser which, unlike prior cup lid dispensers, does not obscure the ice and beverage dispense area. To achieve this result, the cup lid dispenser is mounted in front of the dispense area and is angled or sloped from the top downwardly away from the customer, thus increasing his/her view of the ice and beverage dispensing operation. Further, the sloped cup lid dispenser is fastened to the dispenser in a manner that enables it to be easily removed for service and or cleaning of the cup lid dispenser and/or ice and beverage dispenser. The cup lid dispenser is somewhat like that shown in co-pending U.S. patent application Ser. No. 07/204,423, filed Jun. 9, 1988, the teachings of which are specifically incorporated by reference herein.
The bin bottom wall 34 is centrally apertured for upward, liquid sealed passage of a shaft 36 of the agitator drive motor 26, the motor being mounted on the bottom wall exteriorly of the bin. Carried on the shaft within the bin interior is the agitator 24 which has a plurality of radial arms 38 that generally follow the contour of the bottom wall and extend into the trough and engage the mass of ice in the bin to cause the same to rotate. A rod 40 may optionally be provided and extend from side to side and top to bottom within the bin to provide a fixed resistance against which the rotating mass of ice is moved to facilitate agitation and separation of the ice mass into discrete particles that will readily move through the bin ice discharge passage 30.
Ice may be manually introduced into the bin 22 to fill and refill it. Alternatively, to more conveniently maintain a supply of ice in the bin and automatically replenish ice discharged from the bin, an icemaker 42, having an ice outlet 44 in communication with an upper end of the bin, may optionally be provided. To control the icemaker 42 in a manner to maintain ice at a selected level in the bin, one approach contemplates that a thermostat 46 be on an inside wall of the bin below the icemaker spout 44 and at a level at which ice is to be maintained. The icemaker is operated to produce and introduce ice into the bin in response to signals from the thermostat, such that when the thermostat does not sense the presence of ice around it, the icemaker is operated to produce ice, and when the thermostat senses the presence of ice, the icemaker is turned off. During ice production, the agitator may be periodically operated to level ice introduce by the icemaker into the bin, so that the bin is uniformly filled with ice.
The ice dispenser 20 is for vending ice into cups, the operation of which in doing so will subsequently be described in greater detail. In general terms, the invention provides an improved ice portion control system for the ice dispenser, which operates the ice dispenser in a manner to accurately dispense predetermined quantities of ice, depending on the size of beverage being served. For the purpose, the ice dispenser includes a microprocessor based controller or control circuit 48 that, among other functions performed, controls operation of the agitator motor 26, as well as operation of a pneumatic system, indicated generally at 50, which drives a double acting pneumatic cylinder 52 that opens and closes an ice dispensing gate, indicated generally at 54, at a lower ice outlet opening from an ice chute, indicated generally at 56. An upper open ice inlet opening to the chute communicates with the ice bin outlet passage 30 from the bin 22. When the bin agitator 24 is rotated by the motor 26, it pushes ice through the bin passage 30 into the open upper ice inlet opening to the ice chute 56 to fill the chute with ice, with the amount of ice moved into the chute being dependent upon the time of operation of the agitator. When the pneumatic system 50 operates the pneumatic cylinder 52 to open the ice dispense gate 54, ice is dispensed from the lower ice outlet or discharge opening from the chute, with the amount of ice dispensed being dependent upon the time for which the ice dispense gate is opened.
In the disclosed embodiment, it is intended that a control system provide automatic dispensing of four different selected quantities of ice, although depending upon user requirements, fewer or more than four different selected quantities of ice may be automatically dispensed. As seen in
If it is assumed that the ice chute 56 can be emptied in 410 ms, the controller or control circuit 48 keeps track of the amount of ice left in the chute for any given ice dispense operation. If enough ice is present in the ice chute to satisfy a particular ice dispense, the ice dispense is allowed. While ice is being dispensed the agitator 24 is operated to move ice in the bin through the bin passage 30 and into the open upper end of the ice chute to refill the chute. While the agitator is running, the controller keeps track of how much ice has been put back into the chute. In particular, in response to an ice dispense operation, the motor 26 is energized to operate the agitator 24 for a time duration that refills the chute with an amount of ice in accordance with the amount dispensed, thereby assuring that the ice chute is refilled fully after a dispense. The controller keeps track of the amount of ice in the chute, and if an ice dispense is requested and at the time enough ice is not available in the chute to provide the quantity of ice required, the dispense operation is not allowed until the agitation time calculated to occur before the next dispense is allowed has elapsed, thus ensuring sufficient refilling the ice chute to fully satisfy the dispense operation. The controller uses the time set for the “XL” dispense to calculate the rate at which the ice is replenished, where TXL=410 ms.
The ice dispense system of the invention provides for increased speed of service, intuitive and easy to use operation and reliable ice dispenses. Advantageous features of the system include a self-diagnostic test when the system is turned on; a user changeable ratio of ice dispense time versus agitation time, to ensure that the chute is refilled with a proper amount of ice after a dispense operation; a visual programming bar LED to assist a user in programming the system; a service LED to provide a user with a visual indication of system status; a switch allowing a user to selectively change system operation between an automatic ice dispense mode and a manual ice dispense mode; a lighted push-button for operation by a user to dispense ice when the system is in manual mode; and a flat membrane switch keypad operable by a user to dispense selected amounts of ice.
Referring to the flow chart of
On completion of the self test, the unit proceeds to energize the motor 26 to operate the agitator 24 and move ice in the bin 22 through the bin outlet passage 30 and into the open upper end of the ice chute 56 to fill up the chute with ice prior to a first dispense. The agitation time is based on the “XL” or extra large ice dispense amount setting, and a 10 second delay is introduced for the first ice dispense to give the agitator sufficient time to fill the ice chute before an ice dispense is initiated. On completion of the 10 second delay, the status or results of the self test is displayed through the service LED, such that a red service LED indicates to the user that the ice dispense system failed the self-diagnostic test and that the system requires service, and a green service LED indicates to the user that the system passed the self diagnostic test.
After the start up protocol is complete, and with reference to the flow chart of
As will be discussed, the outer cover of the ice chute is transparent, and the amount of ice in the chute is visible to the user. Consequently, if after occurrence of agitation of ice in the bin it is seen that the ice chute is not completely filled with ice, the user has the option of pressing the manual ice dispense button to initiate agitator operation and filling of the ice chute with ice. This feature ensures that the ice chute can manually be filled by the user, if and as necessary, if the set agitation time is incorrect.
With reference to
The ice dispense time programming mode allows the user to use the 10 LED graduated programming bar 160 to adjust all four ice dispense sizes according to the user's particular requirements. The ice dispense times available through programming, with each graduation on the LED graduated programming bar representing a change of 20 ms, are: (1) Small Ice Dispense/Portion Size (16 oz cup), for which the user can adjust the dispense time in a range from about 50 ms to 230 ms; (2) Medium Ice Dispense/Portion Size (21 oz cup), for which the user can adjust the dispense time in a range from about 80 ms to 260 ms; Large Ice Dispense/Portion Size (32 oz cup), for which the user can adjust the dispense time in a range from about 150 ms to 330 ms; and Extra Large Ice Dispense/Portion Size (42 oz cup), for which the user can adjust the dispense time in a range from about 230 ms to 410 ms. These adjustments enable the user to consistently dispense a required amount of ice for the various cup sizes.
Software coding for the ice dispense system involves a direct relationship between ice dispense time and agitation time, which relationship may be expressed as:
A
T
=D
T
·R
A
where AT is the agitation time or the time of operation of the agitator 24 in response to occurrence of an ice dispense; DT is the time for which the ice dispense occurs and the ice dispense gate 54 is opened; and RA is the agitation ratio and may be a constant. In other words, when the ice dispense gate 24 is opened for a time DT to dispense a selected amount of ice from the ice chute 56, in order to refill the ice chute with substantially that same amount of ice, the agitator 24 must be operated for an agitation time AT, which time AT is directly related to the time DT and can be expressed as the time DT multiplied by the relationship ratio RA between DT and AT.
The user is given the flexibility to change the agitation ratio RA in order to change the agitation time AT that takes place in response to a particular ice dispense time DT. This enables the user to correct for inaccuracies as may exist in refilling the chute, so that the ice chute is always fully filled with ice in response to an ice dispense, and so that the agitator is not operated for significantly longer than is required to refill the chute, for all the different ice types to be dispensed. In other words, the ability of a user to reprogram and change the value of RA ensures that agitation occurs for the correct amount of time, depending upon the length of dispense DT. This prevents the ice chute from being filled to less than its capacity or ice in the hopper from being overly agitated, resulting in a poor quality of ice dispensed. A user can enter a programming mode and change the agitation ratio by “2” ratio increments per lighted bar graph so that there is an agitation ratio increment from 10 to 28.
The ice dispense system has two programming modes, one of which is a dispense time DT programming mode and the other of which is an agitation time AT programming mode. With reference to
To change the time of the agitation that occurs in response to an ice dispense, and with reference to
Ice dispenses are initiated by pressing a selected portion size button S, M. L or XL on the flat membrane keypad 102. The keypad is contemplated to be non-tactile and that the feedback received by the user be audible when ice is being released from the ice chute 56 into a cup or container. The keypad consists of varying layers which are adhered together, resulting in a liquid repellant keypad. Due to the environment in which the ice and beverage dispensing unit is located, there will be instances of beverage and food splashing onto the unit and cleaning fluids being used to clean the unit There is, therefore, a need to have a robust keypad design to meet the day to day environment in which the unit is located, and the keypad 102 meets that criteria. The keypad works by sensing a change in resistance value across the keys. By depressing each key, the user changes this resistance value, resulting in an ice dispense. The keypad advantageously incorporates texts or letters, as opposed to symbols, to inform the user which button is to be pressed to dispense a particular ice portion size. The effective area of the buttons is relatively large to increase keypad button targeting.
All low voltage circuits are all located in the controller 48. The mains power on/off switch also is located in the controller, and the systems modes of automatic and manual are controlled by the controller. In addition, the portion control system is controlled by the controller, and for the purpose of visual feedback in manual mode, the manual ice dispense push-button switch 104 is lighted, and the service LED 164 is switched off, to indicate to the user that the unit is in manual mode. In automatic mode, the service LED lights to inform the user that the ice dispense system is in automatic mode.
The ice chute 56 is shown in
The ice chute 56 is designed for ease of removal of the cover 110 from the chute body 112. This enables the internal surfaces of the ice chute to readily be exposed for daily cleaning. With particular reference to
As mentioned, the ice chute cover 110 is visually transparent, and advantageously the ice chute body 112 is made of a black plastics material to provide a black background for better visualization of ice in the chute, so that the user has a clear view of the amount of ice in the chute. This enables the user to readily determine whether there is sufficient ice in the chute to satisfy an ice dispense. The mounting of the ice chute 56 on the ice/beverage dispenser 100 also places the ice chute in a position to better facilitate visual observation by the user as to how much ice is present in the ice chute
The mechanical chute gate 114 and the interior of the lower end of the chute 56 are configured and dimensioned so that a gap 132 (
With reference also to
The default position of the chute gate 114 is closed, where the gate is extended into and remains in the lower end of the ice chute, to ensure that if there is a failure of the ice dispense system, the ice chute gate will remain closed and ice will not be or continue to be dispensed from the chute. As a further safety feature, a relief valve 138 is upstream of the pneumatic cylinder 116 in the air line that provides pressurized air to the air inlet 136 to the cylinder. The relief valve prevents excess air pressure, for example air at a pressure above about 40 psi, from reaching the cylinder in order to prevent the cylinder from exerting excessive closing forces on the chute gate 114 via a piston rod 140 of the cylinder, thereby to further limit any harm to the user should his finger be in the lower end of the ice chute when the gate closes. To enable the cylinder to vent in either its open or closed position, it is contemplated that the system use a 5/2 pneumatic solenoid valve 172 that receives air through a filter/regulator 174, to control the pneumatic cylinder.
Also for safety purposes, a manually operated bypass valve 142 is upstream from the pneumatic cylinder 116 in the air line that provides pressurized air to the cylinder air inlet 136. The bypass valve permits the user to bypass incoming pressurized air to the cylinder air inlet 136, thereby removing the gate dosing force of the pressurized air on the cylinder. The arrangement ensures that if the cylinder, pneumatics or electronics are faulty, the pressurized air that is applied to the cylinder to close the chute gate 114 can be removed to enable the user to manually open the ice chute gate.
The new ice chute design incorporates the cup rest 118 (
As seen in
As seen in
As seen in
The ice portion and control system is particularly adapted to be used on an ice and beverage dispensing unit to ensure a constant and consistent delivery of ice and beverage to an end user. The system incorporates unique features that enable a higher degree of cleanliness than the prior design, together with improved ergonomics to enable better access to beverage valves and the ice chute. These unique features include a one piece merchandiser that allows removable attachments to be made to it, such as cup lid dispensers that can be removably attached to the merchandiser in a manner to accommodate their convenient removal for cleaning of both the cup lid dispensers and merchandiser surfaces, and that that can then readily be reattached to the merchandiser. The ergonomics of the system accommodate improved and easier access by a user to the beverage dispensing valves and ice chute, without interference from intrusions, thereby providing better visibility of the beverage valves and ice chute.
While embodiments of the invention have been described in detail, various modifications and other embodiments thereof may be devised by one skilled in the art without departing from the spirit and scope of the invention, as defined in the appended claims.
This application claims benefit of provisional application Ser. No. 60/853,856, filed Oct. 24, 2006.
Number | Date | Country | |
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60853856 | Oct 2006 | US |