The present invention generally relates to a sorting system and method for sorting objects of different characteristics. More particularly, it relates to an automatic object sorting system to sort objects which are partially symmetric at least in one plane or their post cut portions.
Getting the dry fruits from farm to consumer is not an easy thing, as there are a lot of processes and step by step instructions that needs to be strictly followed to make sure this happens with retention of nutrition & quality. One of the processes in most of the dry fruit segments is cutting/cracking the outer hard shells of the dry fruits to get the whole kernel out safely. In few of the cases, the kernels/part of the kernels get stuck inside the shell even after cutting/cracking operation. If such shells containing kernel or part of kernel are not separated from the other empty shells, the amount of daily and yearly loss becomes huge for the respective processors. So to sort out these shells with kernels from rest of the empty shells becomes a highly laborious, time consuming and expensive task.
Few shell sorters are already available in the market. One of which includes multi-stage vibrating sieves to sort kernels from the shells immediately after the de-shelling operation. But this fails to solve the problem of separating the shells having kernels or part of the kernels from the rest of the empty shells. Another shell sorter includes air blowers or fans to force hit the shells having kernels or part of the kernels stuck inside them on the walls of closed containers to remove the kernels stuck inside the shell followed by the vibrating sieve and air separation. This comes with a drawback of significant broken kernels as an output. Both of the above sorting systems also lacks optical inspection of each individual shell due to which they significantly miss the accuracy to segregate the shells having kernels or part of the kernels from rest of the empty shells.
There are few patent documents in the prior art using similar technology. Patent application no. RU123691U1 titled “calibrator seeds melon” relates to agricultural engineering and can be used for seedbed preparation for seed melons. The calibrator comprises of multiple rollers rotating in the direction of movement of seed to the forward direction. Each roller has a flap covering the portion of the roller surface of which upper part is in contact with the roller surface and bottom forms a gap in relation to the next roller. The flap is adjustable to increase or decrease the distance between the two adjacent rollers. The seed melons are passed through the rollers to achieve the calibration purpose to get best sowing quality seeds.
Another patent application no. U.S. Pat. No. 5,279,427A titled “Rotary feed table for food product and sliver remover” relates to a roller bed for separating fines and slivers from sliced food product. It includes a plurality of rollers placed side by side on parallel roller shafts. Each roller is provided with alternative crown and flat surface structures around their periphery. A motor coupled to the roller shafts rotates the rollers which are synchronized with each other so that in the gaps between adjacent rollers, the crown portions of one roller coincide with the flat portions of adjacent roller. This arrangement moves properly sized product across the roller bed while allowing smaller fines and slivers to fall between the rollers.
Both of the inventions talk only about the size separation and calibration of objects and uses multiple rollers side by side for the same. Also they lack camera/sensor based sorting as per the size or any other characteristics of the object. So there is a need to have a system which sorts shells after de-shelling operation to separate empty shells from shells having kernel or part of the kernel inside them.
The present invention discloses an object sorting system for sorting objects that are partially symmetric at least in one plane or their post cut portions. In accordance with one embodiment of the present disclosure, the invention is illustrated considering the de-shelled shells of the cashew nut as the object of interest. Accordingly, the system includes at least one feeder for feeding shells, at least one roller pair arrangement, at least one pair of orientation flaps, an adjustable assembly, a first and second camera boxes, an ejection assembly and collection chutes.
Feeder receives the shells to be sorted from the hopper and feeds them to the roller pair assembly. The shells are fed uniformly over the gap between the rollers using a feeder so that the flow of shells at all points over the gap between the rollers is uniform.
The purpose of the roller pair is to guide and provide fixed orientation to the shells received from the feeder through them and to convey the shells which are relatively bigger than the gap between the rollers to one side of the pair of rollers towards the first collection chute. The roller pair assembly is inclined by 0 to 15 degrees towards the first collection chute to allow the shells to convey towards first collection chute. The roller pair assembly further comprises of a pair of orientation flaps placed parallel to each other and exactly below the pair of rollers by maintaining the same or more distance between the orientation flaps as compared to that of the distance between the rollers. The shells may get deflected and lose their orientation immediately after passing through the roller gap due to inertia, air resistance or other buoyancy forces. So a pair of orientation flaps placed exactly below the roller pairs helps to maintain the fixed orientation of the shells which was already achieved by the pair of rollers. An adjustable assembly is provided for adjusting the distance between the two rollers of the roller pair, distance between the two orientation flaps, distance between the roller pair and the pair of orientation flaps and the inclination of rollers towards the first collection chute.
A first and second camera boxes are arranged exactly below the orientation flaps by maintaining the distance between the two camera boxes relatively larger than the distance between the orientation flaps. Illuminating sources are provided with each camera box to illuminate the falling shells. As soon as the oriented shells exit from the gap between the orientation flaps, they are exposed to the cameras from camera boxes placed on either sides. The cameras from the camera boxes are focused towards the lower ends of the orientation flaps to capture the area of interest of each shell as soon as they start exposing themselves to the camera. The grade of each captured shell is decided and sent to the control panel based on the camera analysis. An ejection assembly is located beneath the viewing zone of the cameras from the camera boxes to eject the shells having kernel or part of the kernel stuck inside them based on the signals received from the control panel and get them collected in the second collection chute. The remaining empty shells are collected in the third collection chute.
The present disclosure also discloses a method for sorting shells having different characteristics. The method includes providing at least one feeder for uniformly feeding shells over the gap between the pair of rollers. Receiving the shells by the pair of rollers and guiding and providing them with a fixed orientation while passing through the gap between the rollers and conveying the shells which are relatively bigger than the gap between the rollers to one side of the pair of rollers towards the first collection chute. Inclining the pair of rollers by 0 to 15 degrees for conveying the shells towards the first collection chute. Receiving the shells guided and oriented by the pair of rollers by the pair of orientation flaps which are positioned and configured to avoid the deflection of falling shells caused immediately after passing through the gap between the rollers and to maintain the already achieved fixed orientation of shells by maintaining the distance between the orientation flaps equal to or more than the distance between the rollers.
Capturing the falling oriented shells as soon as they exit the gap between the orientation flaps and expose themselves to the cameras of the first and second camera box which are arranged exactly below the orientation flaps focusing towards the lower ends of the orientation flaps and by maintaining the distance between the two camera boxes relatively larger than the distance between the orientation flaps. Illuminating the falling shells by the illuminating sources provided with each camera box for proper characteristics capture of the shells. Deciding the grade of each falling shell and sending it to the control panel based on the camera analysis considering the kernel or part of the kernel stuck inside the shell. Ejecting the shells having kernel or part of the kernel stuck inside them based on signals received from the control panel by an ejection assembly located beneath the camera box to get them collected in the second collection chute. Collecting the remaining empty falling shells in the third collection chute.
The main objects of the present invention are listed below:
The purpose and application of the invention can best be understood from the description of the various drawings and embodiments provided herewith.
The present invention will now be described in detail with reference to the accompanying drawings.
According to one embodiment of the present invention, the proposed invention discloses an object sorting system which sorts objects in different types.
The shell sorting system comprises of a hopper (110) to introduce the shells in the shell sorting system. The feeder (120) is located below the hopper (110) to receive the shells from hopper (110) and feed the shells further into the gap between the pair of rollers (130) uniformly. A pair of rollers (130) are arranged horizontally below the feeder (120) in such a way that one roller is rotated in reverse to the other and thrusting upwards. The upward thrusting motion of the rollers (130) avoids the crushing or jamming of shells in between the rollers (130). It also helps to maintain the uniform flow of shells through the gap between the rollers (130). The rotating speed of the roller pair (130) is controlled by the control panel (200). The distance between the rollers (130) can also be adjusted by the adjustable assembly (150) based on the size of the shells to be passed through it. In one embodiment of the present invention, the gap between the rollers (130) as well as the gap between the orientation flaps may vary so as to pass the de-shelled shells of variable dimensions at the same time.
A first collection chute (190a) is provided at one end of the roller pair (130). The purpose of the roller pair (130) is to guide and provide fixed orientation to the shells received from the feeder through them and also to convey the shells which are relatively bigger than the gap between the rollers (130) to one side of the pair of rollers (130) towards the first collection chute (190a).
The roller pair assembly is inclined in the range of 0 degrees to 15 degrees towards the first collection chute (190a). The inclination is provided to push the shells which are relatively bigger than the gap between the rollers (130) to one side of the pair of rollers (130) into the first collection chute (190a). The inclination of the roller assembly is also adjusted by the adjustable assembly (150). These shells which are directed towards the first collection chute mainly includes uncut and asymmetric cut shells which were sliced or improperly cracked by the decorticator and so their size remains relatively bigger than the other shells. This removal also yields in proper orientation of remaining shells after passing through the roller gap towards the orientation flaps (140) due to restriction of space between the rollers (130) exactly to the size of the shells. In one embodiment of the present invention, when the inclination of the rollers (130) is 0 degrees or they are placed horizontally, then the rollers (130) that are used are threaded/grooved roller pair which will push the shells which are relatively bigger than the gap between the rollers (130) to one side of the pair of rollers (130) towards the first collection chute (190a) within predictable amount of time and the remaining shells will pass through the gap between the threaded/grooved rollers. The advantages of using threaded/grooved roller pair is that the conveying speed of shells which are relatively bigger than the gap between the rollers is controlled and conveying time of the shells to reach the first collection chute (190a) becomes predictable. The speed of the threaded/grooved rollers too can be controlled using the control panel (200).
In another embodiment of the present invention, a hook is provided along with the cameras/sensors in the vicinity of pair of rollers (130). The purpose of the hook is to dislodge the shell/shells which in case gets stuck in the gap between the rollers (130). Whenever the shell gets stuck anywhere between the gap of the rollers (130) the cameras/sensors immediately senses it and provide the feedback to the control panel (200). Control panel (200) on receiving the feedback, signals the hook provided in the vicinity of the rollers (130) to dislodge the stuck shell/shells and push them in the direction opposite to the first collection chute (190a) for collecting in additional collection chute. The application of automated hook ensures uninterrupted working of the system.
A pair of orientation flaps (140) is arranged exactly below the pair of reverse rollers (130) by maintaining a minimum gap between the flap and the roller surface. The pair of rollers (130) are always parallel with the pair of orientation flaps (140) and the distance between the orientation flaps (140) is equal to or more than the distance between the rollers (130). The distance between the orientation flaps (140) will be adjusted simultaneously as per the adjustment in the distance between the roller pair (130) by the adjustable assembly (150). Once the shells are passed through the roller pair (130), they gain orientation for the time being and may again get deflected due to inertia, air resistance or other buoyancy forces. So the purpose and arrangement of the orientation flaps (140) below the roller pair (130) is to maintain the orientation of the shells which was already achieved by the pair of rollers (130).
First and second camera boxes (160a and 160b) are arranged exactly below the pair of orientation flaps (140) by maintaining the distance between the two camera boxes relatively larger than the distance between the orientation flaps (140). Illuminating sources (170a and 170b) are provided along with each camera box (160a and 160b) for proper illumination of shells to be analyzed. The random falling shells get oriented and expose their two essential flat surfaces to the cameras of the camera boxes (160a and 160b) provided on both the sides opposite to each other. The cameras from both the camera boxes (160a and 160b) are focused at the lower ends of the orientation flaps (140), where the oriented shells actually start exposing themselves to the cameras. These falling shells uses orientation flaps (140) to achieve required orientation and expose themselves to the cameras from first and second camera boxes (160a and 160b) placed below the orientation flaps (140) for analyzing the presence or absence of the kernel or part of kernel inside them. The focusing of cameras towards the lower ends of the orientation flaps (140) itself enables the capturing and analyzing of the shells characteristics of interest to happen at very early stage and helps to predict the exact grade of each falling shell accurately and efficiently. Focusing the cameras towards the lower ends of the orientation flaps (140) also makes sure that the full advantage of the shells orientation is being taken by capturing all the necessary characteristics of the shell. The cameras in the camera boxes (160a and 160b) are arranged in different orientations based on the geometry and characteristics of interest of the objects to be analyzed. The grade data along with the position of each shell is sent to the control panel (200).
In one embodiment of the present invention, the cameras in the camera box can be advanced programmable cameras which can be “synchronous”, “asynchronous”, “regular”, “color”, “multi-spectral” cameras, advanced X-ray cameras, advanced spectrometer or combination thereof based on the requirement of the objects to be processed.
The system further comprises of an ejection assembly (180) with multiple ejection nozzles placed exactly below the viewing zone of the cameras from the camera boxes (160a and 160b) to eject the shells having kernel or part of the kernel inside them. Based on the inputs received from the control panel (200), ejection assembly (180) ejects the shells in respective collection chutes (190b and 190c). In one embodiment of the present invention, as shown in
The present disclosure also discloses a method for sorting shells after de-shelling operation based on different characteristics as illustrated in flowchart of
Cameras from the first and second camera boxes (160a and 160b) which are placed opposite to each other exactly below the pair of orientation flaps (140) by maintaining the distance between the two camera boxes (160a and 160b) relatively larger than the distance between the orientation flaps (140) are focused towards the lower ends of the orientation flaps (140). The oriented shells are exposed to the cameras as soon as they exit from the gap between the orientation flaps (140). Illuminating sources (170a and 170b) provided with each camera box, illuminates the shells for their proper inspection. Cameras from the camera boxes (160a and 160b) analyses the presence or absence of the kernel or part of the kernel inside the falling exposed shell at very early stage near the lower ends of the orientation flaps (140) taking the full advantage of the orientation of the shells. Based on the camera analysis, the grades of the shells are decided and are sent to the control panel (200). Control panel (200) signals the same to the ejection assembly (180) which then ejects the shells having kernel or part of the kernel into the second collection chute (190b). All the remaining empty falling shells are collected in the third collection chute (190c).
Number | Date | Country | Kind |
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201841037300 | Oct 2018 | IN | national |