Patent Application
20200048065
The present disclosure relates to article sortation, and more particularly to a system and method for container filling processes involving a chute.
Different kinds of diversion chute are known in the art, for example, a gradient or gravity conveying chute. Use of a diversion chute to fill a container, though advantageous for many applications, can have various undesirable outcomes. If, for example, the closest wall of a container to the end of the diversion chute is not sufficiently close to the chute, materials or articles intended for deposit could fall outside rather than inside the container. Another possible undesirable outcome is the breakage of materials or articles during, or in relation to, container filling.
The volume of a container can greatly exceed the volume of an article deposited therein. The likelihood of article breakage on container filling will be high in certain instances, for example, depositing a small and fragile article in a large container from a height comparable to the height of the container. The article will be in gravitational freefall from the moment no normal force is exerted, for example, when the article leaves the lower end of a gradient chute and falls through the air until the article strikes an upper surface of a heap of articles in the container (air resistance will generally be negligible). The longer an article is in freefall, the greater the speed and therefore the impulse on striking the heap of articles.
Article breakage risk will be even higher, in general terms, if a large container is filled with generally small articles of arbitrary size, shape and orientation in an automated process that ignores the extent of container filling throughout the filling process. This can lead to an unstable weight distribution, quite apart from overflow, and a shifting of contained articles in transport. Container filling with articles of arbitrary size, shape and orientation will generally result in a low packing density, increasing the odds of article breakage during container filling or transport.
Filling a container with irregular and possibly different-sized articles can also significantly increase the odds of a substantial non-uniform distribution of mass in a container. Irregular mass distribution will be especially likely if the articles are deposited from a single location or limited range of locations, for example, the end of a gravity conveying chute that has a fixed orientation with respect to the container. Non-uniform article mass distribution is potentially problematic for the structural integrity of the container before and during transport.
Indiscriminate filling of a container with different-sized and irregularly-shaped articles can also be an ineffective use of space, increasing the cost of transporting the contained goods by increasing the number of bins needed to contain them.
There are, then, several possible reasons to monitor various aspects of a container filling process. For such reasons and others, it is desirable to develop systems and methods for improving container filling processes involving chutes. Despite advances in this area, further improvements are possible.
In view of the foregoing, it is an object of the present disclosure to provide an improved system and related methods of automatic filling of a container with articles of arbitrary size, shape and orientation. In an aspect of the present invention, the system comprises a chute, an extensible member and one or more proximity sensors. The chute is configured for having an entrance end through which an article enters the chute, a chute bed for conveying the article, and an exit end through which the article exits the chute. The extensible member is configured for being mechanically coupled to the chute and moving between a retracted position and at least one extended position. The one or more proximity sensors are configured for detecting the presence and fill level of the container. The at least one extended position of the extensible member does increase the length of the chute bed and the retracted position of the extensible member does not increase the length of the chute bed, and the extensible member adopts a position in response to the fill level detected by the one or more proximity sensors.
In an embodiment of the present invention, a chain, a sprocket, a motor, a motor shaft, and an extensible member are used to vary the length of a variable-length chute. A signal is sent to the motor, causing it to rotate accordingly. Rotating the motor rotates the shaft, which is mechanically coupled to the motor. Rotating the shaft rotates the sprocket, which is mechanically coupled to the shaft. Rotating the sprocket moves the chain, which is mechanically coupled to the sprocket. Moving the chain moves the extensible member of the chute, which is mechanically coupled to the chain.
In another embodiment of the present invention, a container is filled with articles from a chute with an attached extensible member configured for extending chute length, one or more proximity sensors detect a container fill level, and one or more proximity sensors detect the extensible member position. If the detected fill level is below a first predetermined amount, there are four possible actions. One, if the fill level is below a second predetermined amount and the extensible member is in a retracted position, move the extensible member to an extended position and the allow transfer of articles to the chute. Two, if the fill level is below a second predetermined amount and the extensible member is in an extended position, maintain the extensible member in the extended position and allow the transfer of articles to the chute. Three, if the fill level is above a second predetermined amount and the extensible member is in an extended position, move the extensible member to a retracted position and allow the transfer of articles to the chute. Four, if the fill level is above a second predetermined amount and the extensible member is in a retracted position, maintain the extensible member in the retracted position and allow the transfer of articles to the chute. If, by contrast, the fill level is above a first predetermined amount, there is one possible action: disallow the transfer of articles to the chute.
These and other objects, aspects and advantages of the present invention will be better appreciated in view of the drawings and following detailed description of preferred embodiments.
For a fuller understanding of the invention, reference is made to the following detailed description, taken in connection with the accompanying drawings illustrating various embodiments of the present invention, in which:
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout.
Referring to
In an embodiment of the present invention, a reversibly-extensible member 18 has approximately the same contour as the bed of a conveyor chute 10 (
Extension or retraction of a reversibly-extensible member 18 can alter the effective length of a conveyor chute 10. The range of extension can be, in an embodiment of the present invention, from the original length of the conveyor chute 10 (no extension of the reversibly-extensible member 18,
In an embodiment of the present invention, a reversibly-extensible member 18 can be extended or retracted to ensure the absence of a horizontal or vertical gap between the end of a chute 10 and the top of the nearest wall of a container 14 (
In an embodiment of the present invention, a conveyor chute 10 is a flatbed chute, that is, a chute with a flat conveying surface, as in
Referring more specifically to
In an embodiment of the present invention, a drive controller assembly 24 can be encompassed by a variable-frequency drive (VFD). The main drive controller assembly of the VFD can be the drive controller assembly 24, which can be in electrical communication with a drive interface 22 (
In an embodiment of the present invention, a reversibly-extensible member 18 can have at least two normal positions: “fully retracted” and “fully extended” relative to the end of a conveyor chute 10. Representative illustrations are provided in panels A and B of
In an embodiment of the present invention, whether a container 14 is below (
In an embodiment of the present invention, a reversibly-extensible member 18 can be configured for movement between pre-determined positions. The position of the reversibly-extensible member 18 (
One or more proximity sensors can be used to monitor the position of a reversibly-extensible member 18. These one or more proximity sensors for can be positioned in various convenient locations, for example, key locations underneath the chute 10. In an embodiment of the present invention, these one or more proximity sensors collectively can display several states, reflecting different possible states of the reversibly-extensible member 18. In one embodiment of the present invention there are five states of reversibly-extensible member 18 and of the one or more proximity sensors used to monitor its position: 1) “high normal” (no container 14 is present, or a container 14 is present and more than half full, as in
In an embodiment of the present invention a reversibly-extensible member 18 can be maintained in close proximity to the bed of a conveyor chute 10 by a frame 38 of the conveyor chute 10, as in
Referring to
In an embodiment of the present invention, a conveyor chute 10 is oriented at an angle 56 relative to horizon so that the lower end of the conveyor chute 10 will be at approximately the same height as the wall of a container 14 and the upper end of the conveyor chute 10 will be at a greater height (see
In an embodiment of the present invention, a drive interface 22 is in electrical communication with a drive controller assembly 24, which is used to drive a motor 26 (
In an embodiment of the present invention, one or more proximity sensors 40 are located above a container 14, as shown in
In an embodiment of the present invention, at least one of the one or more proximity sensors 40 can be an ultrasononic sensor. Such sensors can emit acoustic pulses, detect reflections of the emitted pulses, measure the time elapsed between sending and receiving pulses, and calculate the corresponding distance based on the speed of sound in air.
Each of the one or more proximity sensors 40 can be configured to send an electrical signal to a drive interface 22. The drive interface 22 can be a RS-485 interface. The electrical signal can encode the distance from the respective proximity sensor 40 to an upper surface 54 of a heap of articles in a container 14 within the respective sensing cone 52 of the proximity sensor 40. In an embodiment of the present invention, each of the one or more proximity sensors 40 can have an RS-485 communications interface. All of the one or more proximity sensors 40 can thus communicate over a single network that can be monitored by a single drive interface 22.
A drive interface 22 can respond to signals received from one or more proximity sensors 40. If one or more of the detected distances between the one or more proximity sensors 40 and an upper surface 54 of a heap of articles in a container 14 within the respective sensing cones 52 is initially greater than a certain threshold distance but becomes less than this distance in the course of a filling process, the drive interface 22 can send an electronic signal to a drive controller assembly 24 of a motor (not shown), causing a change in one or more determinants of a container filling process. One such determinant can be, for example, the rate at which articles are conveyed to the container 14 or the length of a chute 10 used to convey articles to the container 14. The one or more proximity sensors 40 can thus be used to limit physical damage to articles in a container filling process and increase the uniformity of the distribution of mass in the container 14.
Referring to
In step 504, the drive controller assembly sends a related electronic signal to a motor, commanding the motor to rotate in one of two directions.
In step 506, the motor rotates a shaft, which is mechanically coupled to the motor.
In step 508, the shaft rotates a sprocket, which is mechanically coupled to the shaft.
In step 510, the sprocket moves a chain, which is mechanically coupled to the sprocket.
In step 512, the chain moves a reversibly extensible member of a chute, which is mechanically coupled to the chain.
Referring to
At step 604, a second set of one or more proximity sensors, detects a position of the extensible member.
At step 606, if the fill level is below a first predetermined amount, then go to step 608. Otherwise, go to step 616.
At step 608a, if the fill level is below a second predetermined amount and the extensible member is in a retracted position, then at step 608b, move the extensible member to an extended position and allow the transfer of articles to the chute.
At step 610a, if the fill level is below a second predetermined amount and the extensible member is in an extended position, then at step 610b maintain the extensible member in the extended position and allow the transfer of articles to the chute.
At step 612a, if the fill level is above a second predetermined amount and the extensible member is in an extended position, then at step 612b move the extensible member to a retracted position and allow the transfer of articles to the chute.
At step 614 (if the fill level is above a second predetermined amount and the extensible member is in a retracted position), maintain the extensible member in the retracted position and allow the transfer of articles to the chute. Here, the conditional is unnecessary, as it is the only follow-on possibility if the condition in step 606 is satisfied.
At step 616 (if the fill level is above a first predetermined amount), disallow the transfer of articles to the chute. Again, the conditional is superfluous, as it has already been applied in step 606; the condition in step 606 is not satisfied.
The present invention can be used to decrease the likelihood of article breakage on being deposited in a container, increase the uniformity of the distribution of mass in a container, and increase the effectiveness of space utilization in a container in relation to an automatic container filling process. The present invention can also be used to improve automated container filling by making use of real-time monitoring of fill level. Electronic signaling related to fill level and the adjustment of aspects of the filling process can be used to limit the breakage of articles of arbitrary shape and size used to fill the container. The method will be especially useful if the articles are non-uniform in shape, size and orientation.
As used herein, ‘arbitrary shape and size’ means “any size or shape small enough to fit into a container.”
‘Article’ means “an object, for example, a unit of merchandise.”
‘Container’ means “a collection receptacle that is, in general, much larger than an individual article used to fill it.
‘Conveyor chute’ means “a sloping channel, slide, shaft, funnel or conduit for conveying articles away from a location at a higher gravitational potential, for example, the location of a diverter arm on a conveyor line, to a location at a lower gravitational potential, for example, a container.”
‘Fill level’ of a container means “the extent of filling” the container, “the upper surface of the heap of articles deposited” in the container.
The RS-485 standard defines the electrical characteristics of drivers and receivers used to implement a balanced multipoint transmission line in a serial communications system. Two signal lines are needed. The voltage of one is the inverse of the other, enabling bidirectional communication by a single twisted pair cable over a broad frequency range. The RS-485 driver makes use of three-state logic. This enables the selective deactivation of individual transmitters in the communications system and makes the driver useful for industrial control applications. The individual transmitters can be sensors, the sensors can be used to monitor container filling.
‘Ultrasonic sensor’ means “a non-contact sensor that operates by the propagation of sound waves.” The distance to the detected object is determined by a sound transmission time. The range of an ultrasonic sensor in air can be on the order of 1 m, the spatial resolution of the distance measurement can be within a fraction of a centimeter, background signal suppression can be excellent, there can be an analog output signal in real time in the milliampere range, there can be additional switching output, and the output signal can be sent to a drive interface conforming to a standard communications protocol.
Ultrasonic sensors are useful for monitoring the filling of containers with objects of arbitrary size, shape and orientation, because they can measure the distance to or position of materials of different morphology. Sensor utility, moreover, can be independent of the color or surface finish of the materials detected and unimpaired by reflections from transparent objects. Furthermore, ultrasonic sensors are not affected by any dust or dirt that might be present on the materials. Such qualities make ultrasonic sensors reliable devices for level-detection applications, for example, monitoring the distance to material deposited in container to prevent overfilling.
An ultrasonic sensor can have two independent analog outputs. This can enable monitoring of two fill levels, for example, a lower level and an upper level. In this case, a first independent output setting can indicate a minimum fill level, and a second independent output setting can indicate a pre-determined maximum fill level. A single sensor can send a switching signal when the pre-determined maximum fill level is reached, providing concurrent feedback and a voltage or current output.
A switching signal that indicates a pre-determined maximum fill level can be used for a variety of purposes. For example, the switching signal can be used to alter one or more properties of a gradient chute to influence the filling process. The switching signal can also be used to block the chute, disallowing the flow of articles altogether. An alternative is to use the switching signal to adjust some property of the chute, for example, the gradient or the length. A proximity sensor can thus be used to increase the operational efficiency of container filling, for example, the collection of articles of arbitrary size, shape and orientation.
‘Variable frequency drive’ means “a VFD drive system comprising three key elements: an alternating current (AC) motor, a main drive controller assembly and a drive interface.” A VFD allows control over the direction and speed of a motor shaft by control over the amplitude and frequency of the voltage signal sent from the drive controller assembly to the motor. The motor can be a three-phase induction motor coupled to a reducer to increase torque.
Many additional modifications and other embodiments of the invention will come to the mind of one skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is understood that the invention is not to be limited to the specific embodiments disclosed, and that modifications and embodiments are intended to be included within.
The foregoing is provided for illustrative and exemplary purposes; the present invention is not necessarily limited thereto. Rather, those skilled in the art will appreciate that various modifications, as well as adaptations to particular circumstances, are possible within the scope of the invention as herein shown and described.
