This application is a continuation of International Patent Application No. PCT/AT03/00149 filed May 26, 2003, and published as International Publication Number WO 03/103860A1 on Dec. 18, 2003, which in turn claims priority to Austrian Application No. 359/2002 filed Jun. 5, 2002, now Austrian Patent AT 006 405.
1. Field of the Invention
The Invention refers to a chip-sorting device for gaming chips and counters, specifically those of varying colors and according to the overall concept of Claim 1.
2. Background of the Art
Sorting devices for gaming chips have been well known for a long time. In GB2061490, a patent for a sorting device was published, whereby gaming chips were gasped by a conveyor chain and passed by a characteristic recognition system. This approach is disadvantageous in its requirement for considerable space, specifically for the chain. It is further disadvantaged by the high manufacturing costs, as the chain is comprised of many individual links that are additionally provided with spring-loaded bolts, for the dispensing of the gaming chips.
GB2254419 describes a sorting device, whereby the gaming chips are held by a transport disc and subsequently transferred to a chain, where they are recognized and gathered together, to be distributed. This arrangement requires less space than the aforementioned. This relies upon elastic components in order to hold individual chips for transfer from the disc to the chain and in the chain itself. It is these elastic elements that permit only certain-sized chips to pass through—the gaming chips that are larger than the designated threshold diameter are a mechanical burden/load to the system and are never distributed/transferred to the chain. The gaming chips smaller than the designated diameter cannot be grasped by the chain; therefore, additional chain is necessary, leading to higher manufacturing costs.
U.S. Pat. No. 6,381,294 is a well-known chip-sorting device whereby the advancement of the chips is brought about by a chain that is expensive to maintain.
The goal of this Invention is avoiding these disadvantages and putting forth a chip-sorting device of a different type, which has lower manufacturing costs and utilizes less space, and thereby, is able to handle sorted gaming chips and counters of vastly differing dimensions.
Consistent with such an Invention would be this Sorting Plan/Proposal that introduces the aforementioned type of device that achieves the designated characteristics of the claims. This describes a sorting device for the sorting of gaining chips comprising a base frame 36, a collection container 1, an oblique transport disc 3 adjoining the collection container 1, the oblique transport disc 3 separating and receiving gaming chips 27, a gaming chip characteristic identification system (not depicted) positioned adjacent the transport disc 3, a transfer device 11 distributing the gaming chips 27 in removal units 12 according to characteristics identified in the gaming chip characteristic identification system, removal units 12 having a U-shaped cross-section, the sorting device having a transport for transferring the gaming chips 27 directly from the transport disc 3 to the removal units 12, and a radially external region of the transport disc 3 containing recesses 8 into which the gaming chips 27 are separated, the sorting device provided with at least one ejector 14 that can be inserted at least partially from one side of the transport disc 3 into the recesses 8 to lift an edge 15 of the gaming chips 27 above a front face of the transport disc 3 lying opposite the at least one ejector 14, whereby a blade 16 located on a removal unit 12 slides under the gaining chip 27 with a lifted edge, and the gaming chip 27 with a lifted edge is placed on the blade 16.
A sorting device for the sorting of gaming chips 27 has a base frame 36, a collection container 1 an oblique transport disc 3 adjoining the collection container 1, the oblique transport disc 3 separating and receiving gaming chips 27, a gaming chip characteristic identification system positioned adjacent the transport disc 3, a transfer device 11 distributing the gaming chips 27 in removal units 12 according to characteristics identified in the gaming chip characteristic identification system, removal units 12 having a U-shaped cross-section, the sorting device having a transport for transferring the gaming chips 27 directly from the transport disc 3 to the removal units 12, and a radially external region of the transport disc 3 containing recesses 8 into which the gaming chips 27 are separated, the soiling device provided with at least one ejector 14 that moves so as to be inserted at least partially from one side of the transport disc 3 into the recesses 8 to lift an edge 15 of the gaming chips 27 above a front face of the transport disc 3 lying opposite the at least one ejector 14, whereby a blade 16 located on a removal unit 12 slides under the gaining chip 27 with a lifted edge, and the gaming chip 27 is placed on the blade 16.
Through the proposed measures, there is the possibility to advance and sort gaining chips and counters of varying dimensions, using a cost efficient and simple method. The technically expensive and maintenance-intensive use of the chain is not advantageous. That sorting device is not sensitive to the varied sizes of gaming chips and counters. During the elevation of the chips and the simultaneous rotation of the transport disc, the chips are automatically removed from the transport disc and organized within removal units.
Thereby, there is, through the features of an ejector 14, suitably rotatable, a substantially L-shaped lever, the shorter arm of which can be inserted into the recesses 8 and the rotating movement of the ejector 14 is controlled by means of a cam 19, the advantage of clean and gentle delivery of the gaming chips 27 into the removal units.
Referring to the collection container 1, the side of the transport disc 3 not adjacent to this container has a cogwheel 22. Via a preferably magnetic coupling 24, the cam 19 drives a pinion 23 to render it certain that the distribution movement for a single gaining chip 27 or counter, relative to the movement of the transport disc 3, is always constant, even when the transport speed is altered or adjusted.
Through the features wherein the magnetic coupling 24 may be activated by a microprocessor, the organization of the gaming chips 27, in conjunction with the characteristic recognition system, can be easily programmed and regulated.
Through the features wherein every removal unit 12 and ejector 14 is arrayed with a magnetic coupling 24 and pinion 23, several removal discs can be loaded.
The removal unit 12 has a removal device that is arrayed, which covers a fundamentally L-shaped removal lever's 28 longer arm 28a. The arm 28a is in a groove that runs the length of the floor of the removal unit 12 and goes under where the gaming chips 27 and counters are found. These features allow a portion of the sorted gaming chips 27 and counters to be easily and readily removed from the removal units 12.
Through the features of a shorter arm 29 of the removal lever 28 moving in the direction of the longer arm 28a or that the movement of the shorter arm 29 along the longer arm 28a is governed by an adjustable screw 30, the number of gaming chips 27 and counters removed from the removal units 12 can be set. Toward this end, the movement arc of the removal lever 28, with reference to a removal lever 28 that may swivel around an axle 31 at a parallel level to the movement direction of the shorter arm 29, is anticipated.
Through the features of the shorter arm 29 of the removal lever 28 encountering a spring 33, which pushes the shorter arm 29 against the gaming chips 27 and counters, the removal lever 28 lies in close proximity to the gaming chips 27 and counters.
Through the features of each removal unit 12 having a sensor 35 to detect when the removal unit 12 is at full level, it can be reliably determined when the removal unit 12 has reached full capacity.
Based upon the designated characteristics of the rotation speed of the transport disc 3 determining the success rate of the characteristic recognition system in identifying gaming chips 27 and counters, the rate of advancement/transport of the gaming chips 27 and counters is appropriate for the system.
The designated characteristics of the characteristic recognition system utilizing sensors to differentiate size and color combinations of gaming chips 27 and counters and a spectrometer being placed in the characteristic recognition system, to differentiate wavelengths of the colors undetectable by the human eye describe the characteristic recognition system that is preferably employed.
Through the designated characteristics of the base frame 36 being on roller/casters 37, the base frame 36 has the capability to be adjusted for varying table heights.
The invention is better illustrated by the drawings as follows:
The device consists of a collection container 1 (also called a hopper), open from above, for played gaming chips and counters, attached to the base frame 2.
The advancement transport outfitting is comprised of a circular collection disc 3, and is mounted tightly on a drive axle. An axle 4 is housed in the base frame 2 and is connected to a motor 5.
The collection disc 3 is driven by a number of cylinder bodies/rollers 6 housed in caged frames 7 and arrayed axially. This axial array may be overridden if the central axle 4 is frozen.
In practice, the gaming chips 27 and counters are collected in the hopper 1, where they fall to the lowest point/bottom by gravity and are taken up within recesses 8 in the collection disc 3. The openings in the collection disc 3 display at least the diameter of the largest chips for processing of the desired round gaming chips 27 or counters. The depth of the cavities is set by the thickness of the collection disc 3. By the use of round holes, the gaming chips 27 and counters slide into the holes during the rotation of the collection disc 3 onto the base frame 2.
The collection disc 3 advances the gaming chips 27 and counters optionally serially/in rows at an angle of approximately 135 degrees from above; whereby, they are passed before a color sensor, which detects the combination of color and size variations. Depending upon chip color and design, the sensor conveys a signal to the regulating microprocessor. This regulating microprocessor decides, based upon programmable organization of colors, upon routing the gaming chips 27 and counters into the appropriate removal units 12.
Alternatively, recognition of the gaming chips 27 and counters can be achieved through a spectrometer in the characteristic recognition system, which differentiates based upon wavelength undetectable to the human eye. In order to accomplish this, the gaming chips 27 and counters must be pigment coded.
After recognition, the distribution of the gaining chips 27 and counters into the removal units 12 is effected. This activity covers about 90 degrees of the collection disc 3.
The actual distribution of gaining chips 27 and counters is well viewed in
Through continuous movement of the collection disc 3, the gaming chips 27 or counters are pushed onto the blade 16, where they rest/remain. As another counter 21 finds itself on the blade 16, it is ultimately lifted, and the earlier counter is placed underneath the latter. This process repeats until the removal unit 12 is filled with gaming chips 27 or counters of the same type.
In
In case of a jam during the transfer of the gaming chips 27 and counters into the removal units 12 a brief decline/drop of the collection disc 3 may be anticipated. Toward recognition of a jam, the power of the motor 5 may be monitored, or the sensor of the collection disc 3 may be queried/assessed.
Toward the furtherance of the transport function and the simultaneous reduction of wear-and-tear on all the moving parts of the machine, it is recommended that suitable transport speed of the machine be maintained, with respect to the quantity of gaming chips and counters to be sorted. The setting of the speed can influence the rate (if and how many) of free chips, that is, not in the recesses 8 of the collection disc 3.
The removal units 12 for sorted gaming chips 27 and counters are visible in
With the adjustable screw 30, the quantity of gaming chips 27 and counters lifted out by the “cutter” 26 can be finely adjusted/regulated.
The insertion of a pressure spring 33 assures that the thin shank of the L-shaped lever 28 remains underneath the counters 21; however, it is not absolutely required.
In order to prevent overfilling of the removal units 12 with gaming chips 27 or counters, every removal unit 12 is provided with a sensor 35. As soon as the “cutter” 26 reaches its endpoint, a sensor delivers a signal to the microprocessor regulation, which prevents further delivery of gaming chips 27 and counters to the unit in question. The sensor 35 can, for example, be either an optical or magnetic sensor. In order to achieve this, a permanent magnet 34 must be embedded in the floor of the cutter 26. The device can be adjusted to different heights with a variety of means in
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Number | Date | Country | |
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Parent | PCT/AT03/00149 | May 2003 | US |
Child | 11004006 | US |