This invention generally relates to a pill feeding mechanism, and more particularly to orienting a group of pills, and controlling a flow rate of the group of pills exiting the pill feeding mechanism.
Pharmacies and chemists often dispense pills to customers or patients on receiving a prescription from the customer or patient. The pharmacist working at the pharmacy will often manually identify, verify and count pills based on the prescription received prior to providing the customer with the pills prescribed. Often, due to human error a pharmacist may miscount the number pills to provide to the customer resulting in the customer not receiving the prescribed number of pills. Further, the pharmacist may accidentally provide the customer with different pills than those prescribed to the customer, which places the customer in harm's way. To overcome these problems many automated methods have been developed to count and/or identify pills. However, in order to function efficiently and accurately, the automated methods often require, as an input, a controlled rate of flow of pills having a specific orientation. Thus, it is beneficial for accurate and efficient pill identification, verification, and counting that a system be developed to provide the automated systems with a controlled rate of flow of pills having a specific orientation.
A pill feeder separates and orients a group of pills and controls a flow rate of the pills exiting the pill feeder. Some embodiments of the pill feeder include a rotating surface, such as a rotating disk that moves pills within the feeder and at least one gate that controls passage of pills to an exit path. The rotating disk receives pills and moves the pills through one or more gates that separate the pills into a single file line in a controlled orientation. For example, the pill feeder can include one or both of a lift gate and a separator gate. The lift gate rises to a height that allows a pill through the lift gate in a flat orientation and prevents pills stacking on top of one another. The rotating disk moves the pills to the lift gate and through the lift gate to orient the pills. The rotating disk next moves the pills to the separator gate that opens to allow a single-file line of pills through the separator gate. The line of pills is then guided out to an exit chute via an exit path. A mixer can be included in the center of the rotating disk that counter-rotates relative to the rotating disk to prevent jams of the pills in areas where the pills may become jammed between the center of the rotating disk and the outside wall, in particular between the lift gate and separator gate, or before the lift gate. The pill feeder provides a flow of single-file pills that can be used with various mechanisms, such as a pill verifying system. In one embodiment, an alternative exit path (e.g., alternative to the exit path of the exit chute) guides pills on the rotating disk to an alternative exit chute. An alternative exit path gate allows pills to enter, or prevents pills from entering, the alternate exit path. Pills that travel down the alternate exit chute collect in a funnel with a pivot gate. When a container is pressed against the pivot gate, the pills are released from the funnel into the container.
The figures depict various embodiments of the present invention for purposes of illustration only. One skilled in the art will readily recognize from the following discussion that alternative embodiments of the structures and methods illustrated herein may be employed without departing from the principles of the invention described herein.
The pill feeder 100 can also be used to separate and orient groups of other types of objects that may be irregularly shaped, such as bolts, nuts or washers. Similar to receiving pills, the pill receiving area 105 receives a group of irregularly shaped objects. The mechanisms in the disk housing 110 and the separator housing 115 act on the irregularly shaped objects releasing the objects, one by one, in a controlled orientation and at a controlled rate.
The pill receiving area 105 receives pills from the pill loading area 125 and transfers the pills to the pill control mechanisms within the separator housing 115. The user primarily interacts with the pill feeder 100 through the pill receiving area 105. The pill feeder 100 may be used with pills of varying sizes, shapes, and textures, and may include capsules, tablets and other medication types, though generally similar pills are used with the pill feeder 100 at a single time. For example, a pill may be oblong in shape, purple in color and have a gelatinous coating or circular in shape, white in color and have a chalky texture. As examples, the pill feeder 100 may be used with a hundred large round pills or thirty small oblong pills to feed pills individually through the exit chute 120. The user places pills in the pill receiving area 105 from the pill loading area 125 individually or in groups.
Components of the disk housing 110 and separator housing 115 move pills from the pill receiving area 105 to the exit chute 120. In one embodiment, the disk housing 110 houses a moving surface, such as a disk, and a motor to rotate the disk that is used to move the pills throughout the housing. A disk or a generally circular-shaped surface is one example of a moving surface that can be used in the pill feeder. Other shapes are also possible for both the moving surface and the housing. In some embodiments, the moving surface has a conveyor belt design. The separator housing 115 includes components that control the orientation of the pills and separate pills from one another. A sensor controls the speed of the disk rotation such that pills exiting the chute 120 leave the pill feeder 100 at a controlled speed. Thus, pills placed in the pill receiving area 105 fall on the rotating disk and the rotating disk moves the pills to the exit chute 120. The exit chute 120 includes an entry area on one end for receiving a pill from the pill feeder 100 and at least one exit area at another end for providing the pill to a mechanism or object attached to the pill feeder 100. In addition to a controlled rate of exit, the entry area of exit chute 120 typically receives the pills at a controlled orientation, such as on a flat side of the pill.
The rotating disk 205 is a circular platter rotating about a center spindle, and in this embodiment, generally moves the pills counterclockwise within the separator housing 115. The pills moving counterclockwise mean the pills generally move around from the pill receiving area 105, through a lift gate 210, which orients the pills, to a separator gate 225, which separates the pills, to an exit path 240 where the exit rate is controlled to the exit chute 120.
The rotating disk 205 is made of a material that provides sufficient friction to the pills to move the pills as the disk rotates. For example, the rotating disk 205 may be made of textured plastic with de-bossed patterns. As pills are manufactured with a variety of textures, some of which may be very smooth, the friction on the surface of the disk is sufficient to move these smooth pills. The surface of the rotating disk 205 is also ridged, scored, hatched, or otherwise textured in various embodiments to provide additional friction and to dislodge pills that may get jammed or stuck.
As the pills are moved by the rotating disk 205 from the pill receiving area 105, the pills come in contact with the lift gate 210. The lift gate 210 is located on the rotating disk 205 in the rotation direction of the rotating disk 205 relative to the receiving area 105 (e.g., downstream from the receiving area 105 in the direction of the movement of the disk 205). In one embodiment, the lift gate 210 is attached to a post or a lift post 212. In another embodiment the lift gate 210 pivots open along an axis horizontal and above the rotating disk 205. The post 212 is raised or lowered vertically, or pivoted, by a lift gate motor 215, thereby raising, lowering or rotating the lift gate 210. The lift gate 210 prevents the pills from stacking on top of each other as they pass through the lift gate 210 by providing vertical clearance only for the height of a single pill or for a height slightly greater than that of a single pill. The lift gate 210 also ensures that the pills that pass through the gate 210 rest on the same dimension or edge of the pill. Thus, the lift gate 210 organizes the pills by allowing only pills that are oriented in a particular way (e.g., on a side) to pass the lift gate 210. For example, both stacked and rolling pills may be prevented from passing the lift gate 210 by the position of the lift gate 210.
In one embodiment, the lift gate 210, in a closed position, initially rests close to the rotating disk 205. After the pill feeder initiates operation, the lift gate 210 is gradually raised. The lift gate 210 is raised to a height that allows for at least one pill, in an orientation, to pass through the gate 210. As the gate 210 rises, the pill profile that is lowest among the pill orientations passes under the lift gate 210. As described below, a lift gate sensor 220 detects when a pill passes the lift gate 210 and is used to determine when to stop raising the lift gate 210. By gradually rising, the lift gate 210 allows the pill feeder 100 to accommodate a variety of types of pills without using pill height or size information ahead of time to determine an appropriate height.
In one embodiment, lift gate 210 opens vertically allowing for at least one pill, in an orientation, to pass through the gate 210, by sliding along a track using a gear rack and pinion 1105 as shown in
Returning now to the description of
In one embodiment, the lift gate 210 has ridges 310 extending outward from the face of the lift gate 210. In an alternative embodiment, other textures or surfaces may be used on the face of the lift gate 210 or depressions made in the face of lift gate 210. For example, the lift gate may be textured with bumps, curved ridges, divots, or other features. These textures (e.g., ridges 310) help re-orient pills that roll against the lift gate 210 when the rolling pills come in contact with the face of the lift gate 210. In one embodiment, parts or the whole of the surface of the lift gate 210 are be textured.
In one embodiment, the rotating disk 205 has ridges either rising from the surface of the rotating disk 205 or embedded in the surface of the rotating disk 205 (not shown). The ridges are angled in any suitable direction, such as diagonally across the surface of the rotating disk 205 or radially outward from the center of the rotating disk 205. The ridges may assist in the orientation of pills and disrupt pills that are rolling on the rotating disk 205. As the rotating disk 205 turns, the ridges contact the pills, including when the pills interact with other objects such as the lift gate 205 or separator gate 225. Hence, the pills are turned or disrupted at the gates when impacted by the ridges on the rotating disk 205. In other embodiments, depressions or other structures present on the rotating disk 205 are used to assist in the orientation of the pills.
Referring again to
In one embodiment, the separator gate 225 initially rests close to the surface of the rotating disk 205 and the mixer 250 in the closed position. The separator gate 225 is rotated away from the mixer 250 to open the separator gate 225 to a position that allows for one pill, in an orientation, to pass through the gate 225.
In one embodiment, the separator gate 225 is positioned at an angle with respect to the direction of movement of the pills along the rotating disk 205. Thus, pills make contact with the separator gate 225 at an angle. The angle of the gate assists in orienting pills thereby preventing jams at the opening of the gate 225. As pills make contact with the angled gate 225, the pills turn along the surface of the angled gate 225. Furthermore, as pills are moved against the surface of the separator gate 225, the angled position of the separator gate 225 causes the pills that don't pass through the separator gate 225 to move along the surface of the gate towards the mixer 250. As described further below, the mixer 250 counter-rotates relative to the direction of movement of the rotating disk 205. When a pill contacts the mixer 250, the mixer 250 moves the pill backwards relative to the direction of rotation of the rotating disk 205, which reorients the pill and frees up the opening of the separator gate 225 for other pills to pass between the separator gate 225 and mixer 250. In other embodiments, the angle of the separator gate 225 with respect to the direction of movement of the pills may be changed before, after or during the movement of pills through the gate 225.
The separator gate 225 in varying embodiments may have a variety of geometries specifying the shape of the front face of the gate. In one embodiment, the separator gate 225 has a plow like front face 1405 curving into the face of the separator gate 225 as shown in
Referring again to
In one embodiment, the knobs on the mixer 250 are spaced apart and smoothly extend from the mixer 250, rising gradually from the exterior of the mixer 250. The shape and spacing of the knobs on the mixer 250 may prevent pills from being pressed between the mixer 250 and any adjacent structure in the pill feeder 100. If a pill is between a knob and an adjacent structure, the curvature of the knob pushes the pill gently outward from the center of the mixer 250, reducing the likelihood of the pill becoming trapped. The spacing of the knobs ensure that there is variation in the mixing process, and that there is room for pills caught by the mixer 250 to move backwards without disrupting the flow of the pills in the center of the rotating disk 205. In one embodiment the knobs are evenly spaced around the circumference of the mixer. In another embodiment the knobs are asymmetrically spaced around the circumference of the mixer. The knobs in one embodiment are substantially smooth so as to prevent the pinching of pills as they come in contact with the mixer 250.
In one embodiment, the knobs on the mixer 250 are in a threaded pitch design extending from the bottom face of the mixer 250 in an angle as shown in
Returning to the discussion of the mixer 250 with respect to
In one embodiment, sensors are configured to detect a pill jam, occurring for example at the lift gate 210 or the separator gate 225. The sensors configured to detect a pill jam include the lift gate sensor 220, separator gate sensor 230, and additional sensors positioned ahead of the lift gate 210 or separator gate 225 (not shown). In various embodiments, other permutations and combinations of sensors is configured to detect a pill jam, for example in one embodiment, only the sensors positioned ahead of the lift gate 210 and separator gate 225 are used to detect jams. These sensors detect a pill by determining that the sensor senses a pill for a prolonged period of time at a location. When the sensors detect a jam, the pill feeder 100 reverses the direction of rotation of the rotating disk 205 or reverses the direction of rotation of the mixer 250. In various configurations, one or both of these is reversed. After a period of time, the rotation of direction is returned to the previous direction to continue pill feeding. While the direction is reversed, the rotating disk 205 may rotate in the same direction as the mixer 250.
The exit path 240 guides the pills from the separator gate 225 to the exit chute 120. In one embodiment the exit path 240 is a pair of guide rails attached to the separator housing 115. When the separator housing 115 is closed on the disk housing 110, the pair of guide rails is located just above a portion of the rotating disk 205. In one embodiment the exit path 240 is positioned to substantially orient the exit path 240, such that the exit path gradually moves across the rotating disk 105 from the separator gate 225 to the exit chute 120, approaching the exit chute 120 at an angle. The angle of the exit path 240 as it moves across the rotating disk 205 enables the pill to move from the separator gate 225 to the exit chute 120 despite the centripetal force experienced by the pill. The shape and positioning of the exit path 240, ensures that a pill leaving the separator gate 225 can exit the pill feeder 100 at a controlled rate, while maintaining a controlled orientation.
In one embodiment, pills exit the separator gate 225 and make contact with the rails of the exit path 240. The pills experience a centripetal force due to the rotating disk 205 along an arc of the radius of the rotating disk. When the pills enter the exit path 240, the centripetal force moves the pills towards the outer rail 270. The outer rail 270 of the exit path 240 guides the pill outward from the center of the rotating disk 205 back towards the exit chute 120 as it is being pushed outwards. As the pill enters the middle section of the exit path 240, the centripetal force moves the pill towards the inner rail 275 of the exit path 240. The inner rail 275 continues to guide the pill towards the exit chute 120, while maintaining the orientation of the pill. The angle of the inner rail 275, when interacting with the pill, causes a component of force to direct the pill outward from the center of the rotating disk 105.
In one embodiment the exit path 240 consists of a pair of rails that are initially curved as they leave the separator gate 225 and gradually straighten out as they approach the periphery of the rotating disk 205. Given the centripetal force experienced by the pill, the shape and positioning of the exit path 240 ensures that the pill enters the exit chute 120 at a controlled rate and in a controlled orientation. The initial radius of curvature of the curved portion of the exit path 240 ensures that pills being pushed outwards are guided without pause or interruption towards the periphery of the rotating disk 205. The radius of curvature of the exit path 240 is large enough to accommodate pills of different sizes and shapes. Without the radius of curvature, pills entering the exit path 240 would be forced vertically outward against the exit rails and may not experience an outward component of force significant enough to move the pills away from the center of the rotating disk, resulting in pills coming to a stop against the rails of the exit path 240.
The position of the end of the exit path 240 on the periphery of the rotating disk influences the orientation of the pill as it exits the pill feeder 100. In the embodiment of
Referring again to
In one embodiment, a coupler 255 positioned between the exit path 240 and the exit chute 120 couples the exit chute 120 to the exit path 240. The coupler 255 provides a smooth transition between the exit path 240 and the exit chute 120, such that pills exiting the exit path 240 may be directed to the exit chute 120 without changing orientation. In one example, the coupler 255 gradually extends from the periphery of the portion of the rotating disk 205 including the exit path 240 and couples with the exit chute 120. As shown, the coupler 255 does not rotate with the rotating disk 205 and in one embodiment the coupler 255 is attached to separator housing 115.
In some embodiments, a controller (not shown) receives sensor inputs from the various sensors and controls operation of the rotating disk 205, lift gate 210, separator gate 225, mixer 250, and additional mechanical components as described throughout. The controller in varying embodiments is implemented as a processer executing instructions on a memory, a hardware circuit, or a combination thereof Thus, the controller operates the lift gate motor 215 to raise the lift gate 210, controls rotation of the rotating disk 205, and so forth. The controller may receive indications from the lift gate sensor 220, separator gate sensor 235, and exit path sensor 245 to identify and monitor the location of pills within the pill feeder and use the sensor indications as described herein. Thus, the controller identifies when to stop raising the lift gate 210 based on the lift gate sensor 220, adjust the speed of rotation of the rotating disk based on rate of pills detected by the exit path sensor 245, and detect pill jams based on sensor information. Jams may be detected based on occlusion of various sensors or a failure of the exit path sensor to detect pills in the exit path when other sensors are occluded.
In certain embodiments, the controller may also receive an identification of a pill type for the pills to be input to the pill receiving area 105. The controller in one embodiment accesses a look-up table or database to retrieve settings to operate the pill feeder based on the pill type. The settings may include a height at which to set the lift gate or a width to set the separator gate. These lift gate and separator gate settings are used to set the height of the lift and separator gate in an embodiment. In addition, the settings may specify a rate at which to turn the rotating disk 205 and a rate and direction to turn the mixer 250. The settings may also indicate behaviors to clear jams for the particular pill type, such as parameters and/or patterns for changing the rotation of the rotating disk 205 or the mixer 250.
In one embodiment, an alternative exit path gate 710 opens or closes at the opening of the alternative exit path 705. The alternative path gate 710 controls entry to the alternative exit path 705 and allows pills to enter the alternative exit path 705 or prevents pills from entering the alternative exit path 705. In one embodiment, when in a closed position, the alternative exit path gate 710 is the guide rail of the exit path 240 nearer the center of the rotating disk 205. In this way, when the alternative exit path gate 710 is closed, the pills are directed by the alternative exit path gate 710 towards the exit chute 120 as described above. When the alternative exit path gate 710 is opened, the pills continue to travel the direction of the rotating disk towards the alternative exit path 705. In one example, a motor controls the opening and closing of the alternative exit path gate 710. In one example, the operator of the pill feeder 100 determines when to open and close the alternative exit path gate 710. Alternatively, the pill feeder 100 automatically opens or closes the alternative exit path gate 710 when an identified condition is satisfied, such as when a threshold number of pills have entered the exit chute 120.
In one embodiment, the alternative exit path 705 includes a pair of alternative exit path rails 715 that guide the pills from the alternative exit path gate 710 to the periphery of the rotating disk 205 similar to the guide rails described above with respect to the exit path 240. In one embodiment, the alternative exit path rails 715 are initially curved and straighten out as they approach the periphery of the rotating disk 205. As the pills interact with the alternative exit path rails 715 the initial curvature of the alternative exit path rails 175 allow the alternative exit path rails 715 to gradually change the direction of motion of the pills on the rotating disk 205. The alternative exit path 705 can be shorter or longer as desired, and can be shaped or can include projections, ridges, etc. to help effectively move pills along the path and avoid having pills get caught along the path.
In one embodiment, the position of the exit chute gate 805 is linked to the position of the alternative exit path gate 710. For example, when the alternative exit path gate 710 is in the open position, the exit chute gate 805 is in the closed position blocking off the opening to the exit chute 120. Similarly, when the alternative exit path gate 710 is in the closed position, the exit chute gate 805 is in the open position, allowing pills to enter the exit chute 120 via the exit path 240. The exit chute gate 805 may have a textured surface, smooth surface or a layered surface to aid in the guiding of the pills through the alternative exit path 705.
The foregoing description of the embodiments of the invention has been presented for the purpose of illustration; it is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Persons skilled in the relevant art can appreciate that many modifications and variations are possible in light of the above disclosure.
The language used in the specification has been principally selected for readability and instructional purposes, and it may not have been selected to delineate or circumscribe the inventive subject matter. It is therefore intended that the scope of the invention be limited not by this detailed description, but rather by any claims that issue on an application based hereon. Accordingly, the disclosure of the embodiments of the invention is intended to be illustrative, but not limiting, of the scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 61/864,468, filed Aug. 9, 2013, U.S. Provisional Application No. 61/926,870, filed Jan. 13, 2014, and U.S. Provisional Application No. 61/990,257, filed May 8, 2014, each of which is incorporated by reference in its entirety.
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PCT/US2014/050443 | 8/8/2014 | WO | 00 |
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