In the past, vending machines have been used to dispense beverages. In one common configuration, cans or glass or plastic bottles are stacked in a vertical or offset-vertical columns and dispensed from the bottom of the columns into a holding area below the columns where the customer can retrieve the beverage. Generally, a funnel-type diverter will be used to divert the beverage to the location of the holding area and also to prevent the beverage container from being damaged during the drop. This configuration requires that the column be shorter than the height of the machine so that the beverage can be dropped into the holding area below the column. As a result, storage space that could be used to increase capacity is wasted on the holding area. This is undesirable because in the vending industry it is preferable to have the maximum capacity of product in a machine of a given size in order to maximize sales and maximize the time between product restocking.
Additionally, vending machines incorporating products, typically snacks and candy, have utilized trays having horizontal columns of product placed between each revolution of a helical shaft. The shaft is rotated one revolution, which causes an item near the end of the screw to be forced forward and become disassociated from the helical shaft. Typically, the product will drop from the front of the tray into a holding area that can be accessed by the customer to retrieve the item. The holding area must be lower than the lowest tray so that an item may drop into the holding area. As a result, space associated with the holding area is not used for storing product, thus wasting some usable space. Moreover, the helical shaft is not particularly suited for beverage containers.
Another type of vending machine, such as that shown in U.S. Pat. No. 6,556,889 to Rudick et al., uses an elevator to receive product that is dropped from sloping trays. The product slides down the sloped trays by the force of gravity into the elevator that is moveable to a location adjacent the tray. An actuator located between the lowermost beverage and the elevator selectively allows a beverage to pass into the elevator. The elevator then moves to a second location whereby a conveyor belt in the elevator conveys the beverage to one side of the elevator where it is conveyed into a holding area to the side of the elevator. However, because the vending machine of the '889 patent utilizes sloped shelves, some of the vertical capacity of the vending machine is wasted. Moreover, because product dispensation relies on sloping shelves, jamming of product can occur if the slope is insufficient to allow for simultaneous movement of the column of product (particularly if product spillage occurs causing sticky trays) or of the product is heavy (such as large glass bottles) and applies too much force to the product dispensation actuator.
Therefore, there is a need for a vending machine, particularly a beverage vending machine, that does not waste space for a holding area for delivery of the product or for product trays that require the tray to be sloping for delivery of the product to the consumer.
The present invention provides a method of moving an elevator to a product location in a vending machine to receive product from the product location, including the steps of: providing an indicator associated with each product location; providing a sensor associated with the elevator; moving the sensor first to a position near an expected position of one of the indicators; and searching for an actual position of the indicator. The present invention also provides an apparatus for performing the method.
While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will herein be described in detail preferred embodiments of the invention with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the broad aspect of the invention to the embodiments illustrated.
Referring to
As discussed above, the product drive member 24 is threaded onto the threaded shaft 22. Because the drive shaft 28 is urged counterclockwise, the drive shaft 28 urges the threaded shaft 22 clockwise through the mating gears 26 and 30. The result of the threaded shaft 22 being urged clockwise is that the product drive member 24 is urged to the front 11 of the row 12.
Referring to
In the preferred embodiment, the tray is comprised of two rows 12. Therefore, by locking the bases 16 together, a larger tray 10 comprised of any even number of rows 12 can be used within vending machines of various sizes. However, nothing should be construed to limit the invention any particular number of rows and more or fewer rows may be implemented within a tray without departing from the scope of the present invention, for example bases of only a single row that lock together to form a larger tray.
In order to use the device of the present invention, the bases 16 are interlocked together to form a proper width tray 10 suitable for a particular vending machine. Multiple rows of trays are further provided within the vending machine and the rows 12 of the trays 10 are filled with product 100 to be vended, as shown in
When the time for vending the product 100 arrives, an elevator 102, as shown in
Optionally, a sensor 103 may be provided on the elevator that detects the presence of an indicator 48 with respect to the product drive member 24, as shown in
Alternatively, rather than detecting the presence or absence of product directly, the product elevator 102 can attempt to vend product and if after a predetermined period of time no product 100 is dispensed, the vending machine will determine that no product is present within the row.
When the indicator 105 is a magnet, the system of the present invention finds the precise location of the product to be dispensed (so that the product dispenser drive 104 and the drive shaft 28 properly align) by finding the center of the magnetic field of the magnet to properly locate the elevator 102. The system accomplishes this by first moving to a position of about 0.320″ to the right or left of the expected X/Y coordinates of the selected product. Next, the elevator 102 is moved toward the expected position of the product row. The vending machine records a first position Xa where the sensor 103 first senses the indicator 105. The elevator 102 continues moving past the indicator 105 until the indicator is no longer sensed. The elevator 102 is then driven in the reverse direction and records the position Xb where the position sensor is activated. The vending machine then calculates the center position of X coordinate of the indicator 105 as Xcenter=Xa+(Xa−Xb)/2. Next, the elevator 102 is moved to a position about 0.5″ below the expected Y coordinate of the indicator and to the Xcenter X coordinate. The elevator 102 is then moved upwardly until the sensor detects the indicator and then an additional 0.160″. At this point, the elevator 102 is located in an acceptable position to extend the product dispenser drive 104 and rotate the drive shaft 28 to vend product. Alternatively, the center of the Y coordinate could be determined in the same manner as the X coordinate. In yet a further alternative variation, the X coordinate could be determined by finding leading edge of the indicator 105 and moving a predetermined distance just as with the Y coordinate above.
In another method of finding the center of the indicator 105 and referring to
To find the center of the indicator from the three positions detected, the system must find the point of intersection of the perpendicular bisectors of any two chords defined by the three positions. The first step to calculating the center point is to solve the equations for the lines containing segments AC and BC in the form ax+by=c. For each segment, the constants are determined using the following equations
aBC=yB−yC
bBC=xC−xB
aAC=yA−yC
bAC=xC−xA
The next step is to determine the equation for the perpendicular bisector of the lines containing AC and BC. These bisecting lines will contain the line segments EO and DO. The equation of the perpendicular bisector is −bx+ay=d. The constant d is determined by calculating the midpoint of the desired line segment and inserting the value for x and y, as shown below.
dDO=−bBC((xB+xC)/2)+aBC((yB+yC)/2)
dEO=−bAC((xA+xC)/2)+aAC((yA+yC)/2)
Now that the perpendicular bisectors have been found, the intersection of these two lines is calculated. The three equations below are used to calculate the position of the center point.
Det=−bBC*aAC+bAC*aBC
xO=(aAC*dDO−aBC*dEO)/Det
yO=(−bBC*dEO+bAC*dDO)/Det
As long as the two lines AC and BC are not parallel, the center point can be determined. Moreover, the center O can be calculated with any three points on the circle, regardless of their position. Thus, in an alternative embodiment, the system could make diagonal passes across the sensor 105 and still calculate the correct center point.
The preferred means for recording the above positions and calculating the product location is an electric circuit, more preferable an integrated circuit, such as an application specific integrated circuit or ASIC.
In the present invention, the new coordinates for the indicator 105 may be memorized by the vending machine such that, in the future, the elevator will proceed directly to the new position or, as is preferred, the coordinates are not memorized in any manner and they are redetermined with each product vend cycle. By not memorizing the coordinates, the precise coordinates are always detected and mis-vending of product is avoided. This is particularly useful when the dimensions of the vending machine may have changed, for example, as a result of moving the vending machine or changing the vending machine geometry as a result of changing product weight distribution.
While the specific embodiments have been illustrated and described, numerous modifications come to mind without significantly departing from the spirit of the invention.
The present application claims priority to U.S. Provisional Patent Application Ser. Nos. 60/701,269 filed Jul. 21, 2005, the contents of which are incorporated herein by reference, and is a continuation of U.S. patent application Ser. No. 11/421,935, the contents of which are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
60701269 | Jul 2005 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11421935 | Jun 2006 | US |
Child | 11490595 | Jul 2006 | US |