TH78562A - - Google Patents

Abstract

DC60 Automatic Grain Sampler consists of a sampling station. Which is a collector Samples for removing material from seeds in the sampling station; Conveyor for conveying grain From the sampling station to the inside of the grain trays and conveyors for conveying the removed material From the seed to the responsive part of the sample tray Methods of invention include entering One seed at a time to the sampling station, taking samples from the seeds in the sampling station; Sample transfer into the sample tray and seed transport to the responsive part of the seed tray The sample can be tested and the seeds can be preserved according to the results of the test. Their response The automatic seed sampler consists of a sampling station. Which is a collector Samples for removing material from seeds in the sampling station; Conveyor for conveying grain From the sampling station to the inside of the grain tray and the conveyor for conveying the removed material. From the seed to the responsive part of the sample tray Methods of invention include entering One seed at a time to the sampling station, taking samples from the seeds in the sampling station; Sample transfer into the sample tray and seed transport to the responsive part of the seed tray The sample can be tested and the seeds can be preserved according to the results of the test. Their response

Claims (2)

Disclaimer (all) which will not appear on the advertisement page: Amendment 30/01/2019 Page 1 of 3 pages Disclaimer 1. Automatic seed sampling system which consists of Automatic sampling station; Sampler for extracting material from seeds in automated sampling stations; Automatic grain conveyor for conveying seeds from the automatic sampling station to Part in the seed tray; Automated sample conveyor for conveying material removed from the grain to the available Response in the sample tray -------------------------------------------------- -------------------------------------------------- 1.Automatic seed sampler including Sampling station; Sampler for removing material from seeds in the sampling station; Grain conveyor for transporting seeds from the sampling station to the inside of the seed trays; A conveyor for conveying the material removed from the grain to the reactive part. In the sample tray 2. Sampler claim 1, where the grain carrier is the compressed air conveyor 3. The sampler, where the sample collector is the compressed air conveyor 4. The sampler Collect an example of claim 1, which follows at least the table for support. One seed tray, which has a portion for each seed, and at least one tray with a portion for each. A number of samples and an aligner for moving the table in order to arrange the inner Ask the kernels on the table with the seed conveyor and arrange the parts with the response in the sample trays. Sampler 5. Samples according to claim 5, where the locator translates the table in a perpendicular direction with two hand directions. 6. The automatic seed sampler, which consists of: a collection tank for a certain number of seeds. Sampling station Sampling apparatus for removing material from seeds in the sampling station. Grain dispenser for delivering each seed from the hopper to the sampling station. Grain conveyor for transporting the seeds from the sampling station to the seed trays. In the sample tray 7, the sampler according to claim 6, where the grain carrier is the compressed air conveyor 8, the sampler claim 6, where the sample carrier is the pneumatic conveyor 9. Sampler, claim 6, which follows at least the table for support One seed tray, containing a certain amount of portions for each seed And at least one sampler tray Of the section for each sample And alignment machine for moving the table in order to arrange the sections In the seed trays, make a straight line on the grid with the seed conveyor and arrange the sections with the response in Sample tray with sample transport device 1 0. Sampler claim 9 where the aligner translates the table in a perpendicular direction. Bi-directional manual 1 1. A device for collecting samples from each number of seeds embedded in each part in the seed tray. A tank for keeping a certain amount of seeds Sampling station for retaining each seed where samples were taken Mechanism for extracting material from each grain in the sampling station. Grain Dispensers for the transport of single seeds from the hopper to the sampling station. The pneumatic seed carrier with the first end attached to the sampling station and the second end for the compressed air transport between the sampling station and the second end the compressed seed carrier with the first end attached to the collection station. Samples and a second tip for aerated transport, taken from the seed from the sampling station to the second end. Tables for the support of the multiplatformed seed trays and the multiparty sample trays, index mechanism for table translation, in order to successfully bring the different parts of the seed trays and sample trays to the arrangement. The second end of the aerated seed carrier of the compressed air seed carrier and the compressed air sample carrier respectively 1 2. Method of testing a number of seeds. Methods which include Possible seed feeding to the sampling station, retaining the seeds in the sampling station, scraping off the retained seeds. The sampling station, which is the transport of each sample to Each part in the sample tray, the seed transfer to the part of the seed tray with a known relationship to the In the sample tray, the responsive samples were transported, and each sample was tested. 1 3. Method of screening a number of seeds for stabilization. The method consists of feeding them one seed at a time to the sampling station. Which holds the seeds in the sampling station; Extracting samples from seeds preserved in the sampling station; Conveying each sample to Each part in the sample tray; The transport of seeds to part of a well-known correlated seed tray. With the part of the sample tray and the one in which the reactive sample was transported Individual testing for characteristics Seed separation in which its samples were tested positive for traits From the seed which samples Its contents were not tested positive for characteristic 1 4. Method to claim 13, in which the grain is transported by compressed air to each part of the It is in the seed trays from the sampling station 1 5. Method according to claim 13, where the samples are transported by compressed air from the station. Samples were collected to the sampling tray 1 6. Method of claim 13 where the process of scraping the samples from the seeds was obtained. This is done by dragging the multi-toothed instrument across the surface of the seed. 1 7. Method of claim 13 where the retention process is carried out in the sampling station. It consists of holding the seed against the surface which directs the seed relative to the Appearance surface scraping apparatus with minimal impact on seed persistence capacity 1 8. Method of seed sampling, which is embedded in a segmented tray. Which consists of sequential transport of each seed to the sampling station; Holding the seed in Sampling station; Scraping of the sample from the seed, transfer of the scraped sample to the part of the sample tray; Conveying of seeds to the response part in seed trays 1 9. Methods of mass seeding consisting of (a) removing samples from each seed in the population (b) individual transport. Samples to the known correlation isolation region (c) each test for the desired properties and (d) subsequently a seed separation, depending on the test results of the available samples. Their response 2 0. The method of claim 19, which consists of plants cultivated from seed, has been shown. The properties are coveted; Harvesting of seeds from cultivated plants and the repetition of steps (a) - (d) 2 1. Method according to claim 20, which consists of feeding each seed to the sampling station; Which involves removing the seed portion at the sampling station; Which is the transport of the seed and the sample from the seed in order to isolate the known area of the association; Sample testing for qualification; Seed separation based on the results of the testing of samples from each seed. 2. 2. Method of claim 21 where each sample was transported from the sampling station. At least part of the sample tray and where each seed is discharged by compressed air. From the sample station to the response part in the extracted seed trays 2. 3. Method according to claim 21, where the seed carrier and sample carrier are fixed position and where the seed trays and samples are located. The sample tray has been enlarged in an indexed table, which Relative to the seed carrier and the sample carrier 2 4. Method according to claim 21, where the material has been scraped from the seed to a depth not greater than approximately 3 mm. Right 21 where the sample was transported in a tube made of material 2 6. System for seed sampling. Which the system consists of A sampling station for treating each seed; Sampling mechanism for extracting material from seeds in the sampling station. Seed feeder for feeding each seed to a sampling station Sample transportation For transporting samples from the sampling station to a designated area. Table for sustaining one or more seed trays with a certain number of sections for each seed treatment and sample trays with a certain number of sections for preserving each sample from each seed Index mechanism for removing tables in order to Take the seed portion and arrange it with the ends. The finished first of the grained seed trays and the responsive part in the sample tray. In a straight line arrangement with the fixed ends of the sample chute 2 7. Methods of bulking up the volumes of grain, which have a desirable manner. Testing each seed for the desired characteristics. Cultivating plants from seeds which have been tested positive for their coveted traits. Removing seeds from seed culture And repetition of procedures (a) to (c) for multiple production 2 8. Methods of claim 27 where the desirable characteristics of the oil content and the test consist of the Image MR of Kernels 2. 9. Method for claim 28, where kernels are corn 3 0. Method for claim 28, where kernels are soybeans 3 1. Method of claim 27. Where the kernel is maize 3 2. Method for claim 27, where seed is soybean 3 3. Method under claim 27, where desirable traits are hereditary and where The test consists of removing a sample from each seed without destruction. Persistence 3 4. Method of claim 27, which consists of transporting the seeds to the sampling station, removing the samples from the seed without destruction. Its persistence ability; Transport of the seeds to the seed trays and the samples to the responsive parts of the sample trays 3 5. Method of claim 27, which consists of seed separation, which are based on test results. Each sample of the sample in the response section in the sample tray 3 6. Method for claim 27 which consists of feeding one seed at a time to the sampling station, removing the material from the parent seed. Without destroying seed persistence; Seed transport To one region, the transporting material that is taken from each seed to a second region that responds to the first; Which tests the material which is taken from each seed and is the separation of the seeds depending on the results of Testing of objects in the response region 3 7. Methods of taking tissue samples from the seed while retaining their capacity. In substantial seed persistence, a method which consists of dragging an auger with an edged with A number of cuts across the grain, the cutting edge is angled with respect to the direction of pulling, therefore at least two adjacent edges remain in contact with the seed during cutting. Taking tissue samples from the seed while having the ability to Extremely resistant to seeds A method which consists of dragging an auger with a number of cutting edges. Cross the seed so that the first tissue sample is removed and a cut in the seed and sample is taken. The second came out from the cut in the seed. 3 9. Sampling system for removing the sample from the seed while it was being treated. Tremendous seed persistence capacity A sampler which includes A pouring hole for holding a certain amount of seed. A sorting machine for sorting individual seeds from a certain number of seeds in the pouring compartment and delivering them to the outlet. At least one spreader, which has a number of walls for receiving and retaining each seed hole, which can be connected by selection to the outlet. The translator for the removal of the spreader, which relates to the effect of the sorting machine, hence the effect of the sorting machine supplies the seeds to each well in each spreader. A number of seed sampling stations Each seed collection station has an access point which contacts With the exit of the diffuser And the assembly of a chamber with a sample frame with a niche for receiving seeds and an internal sampling chamber where the seed portion is protruding; A support that can protrude Yes, for the width of the seed within the niche in the sampling frame; Drilling machine with Driven back and forth with a number of cutting edges, driven drilling machine in the groove in the sample frame In order to extract the sample from the seed portion in the recessed recess of the sample; Sample transport mechanism for transporting tissue samples removed by a puncture device. From seeds distant from each sampling station The seed transport mechanism for transporting the sample seeds away from each station. Sampling after collection 4 0. Sampling system according to claim 39 where each sampling station consists of: The tube for collecting seed samples from the cut, which was formed by the auger 4 1. Sampling system according to claim 39, where the transport system of the sample consists of tubes and nozzles for induction. Bring the differential pressure in the tube to transport the sample. 4. 2. Sampling system according to claim 39, where the seed transportation system consists of, however. And a nozzle for pressure induction that makes the difference in the tube in order to transport the seeds. 4. 3. Sampling system according to claim 39, which is further composed of an air nozzle, which is applied to the sample. 4 4. Sampling system according to claim 39, in which the diffuser consists of an external shell and a translatable shuttle inside the external shell, a shell containing a certain amount of Inlet openings and a number of outlet and shuttle openings, which have a certain number of walls, here the shuttle can be operated between the first position in which the walls are arranged with the inlet openings in order to The seeds were obtained through the opening of the entrance and the second position in which the walls were arranged with the opening of the Solution in order to release the seeds from the wall. 4. 5. Sampling system according to claim 39, where there are two diffusers. Each of which has A certain number of intersections along the way And here is the sampling station for each Spreader Path 4 6. Sampling system according to claim 39, which consists of at least one sample tray. Which has a certain number of walls and a translation mechanism for cutting the wall position in a straight line with an exit. 4. 7. Sampling system according to claim 39, which consists of one or more sample seed trays with a certain number of wells and a translation mechanism for aligning wells. 4 8. Sampling system according to claim 39, where the sorter for each sorting. Seeds from a certain amount of seeds in the pouring compartment and the delivery of seeds to the exit consists of a disk which has A certain number of openings in its surface And a vacuum system for the generation of suction at each opening a number of channels, dragging, suction and retention of the seeds liberally against the disk at the opening 4. 9. Methods of taking tissue samples from seeds. Methods which include Dragging an auger with a number of cutting edges across the seed surface in order to remove the tissue from the seed and then transport the tissue and seed in order to separate the area of association. It is known for that reason after tissue testing. Responsive kernels can be identified. 5 0. Claim 49 method where the cutting edge on the drilling machine is at a certain angle relative to the direction of drag 5 1. Clause 49. At 50 in the place of the cut on the boring machine, at an angle related to the direction of The drag in which at least two edges remain in contact with the grain is the same as a drill across the grain surface. 5. 2. Method according to claim 51 where the cutting edge on the drill is at an angle of 60 ํ. Which is about Direction of drag 5 3. Approach according to claim 51, where the seed is soybeans and the moisture content has been continued. The amount of soybean was approximately 8% before dragging the auger across the grain surface. 5. 4. Method of claim 53, which consists of managing soybean moisture content. However, at least about 12% of the drilling machine was dragged across the grain surface. 5. 5. Method of claim 49, which consists of the process of pressing the seeds while The auger was dragged across the surface of the grain. 5 6. Method according to claim 55, when the seed was pressed with force between approximately 2.5 and approximately 5 pounds 5 7. Method according to claim 55, where The seeds were pressed in a direction normally perpendicular to the The direction in which the auger is hauled against the grain. 5 8. Method according to claim 55, in which the grain is pressed in a direction normally sized with that direction. 5 9. Method by which the tissue sample is taken from the seed according to claim 55, where the cut edge on the auger is at an angle relative to the direction of the grain. Drag 6 0. Method of seed tissue sampling according to claim 55 where the cutting edge is at an angle. Which is related to the direction of drag, which at least two edges remain in contact with the grain because The auger was dragged across the surface of the grain. 6 1. Method of removing tissue samples from the seed pursuant to claim 60 where the upper cutting edge was removed. The auger is at an angle of 60 ํ in relation to the direction of drag 6 2. Method of claim 60 where the grain is soybeans. And has been dealt further So that the moisture content of soybeans was greater than 8% before dragging the drilling machine across the grain surface. 6. 3. Method according to claim 62, which consists of the management of soybean moisture content. At least 12% before dragging the auger across the seed surface. 6 4. Methods for removing tissue samples from the seed. Methods which include Dragging the auger with a number of cutting edges across the surface of the grain in order to remove the tissue. Away from the seed After tissue excision, which was formed by a puncture machine, and then transported tissue from the incision and seed, to isolate the known association area after at least one test. tissue Responding grain can be identified 6 5. Method according to claim 64, where the cutting edge on the drilling machine is at an angle relative to the direction of the drag 6 6. Method according to claim 65 in Where the cutting edge on the drilling machine is at an angle relative to the direction of Drag, where at least two edges remain in contact with the grain because the auger has been dragged, b. The surface of the grain 6 7. Method according to claim 66, where the cutting edge on the drill is at an angle. Size of 60 ํ. Direction of drag 6 8. Method for claim 66 where the seeds are soybeans and continue to handle moisture content 6 9. Method according to claim 68, which includes the management of soybean moisture content. At least approximately 12% before dragging of the auger across the grain surface 7 0. Method according to claim 64, which is followed by the pressing process while The auger was dragged across the surface of the grain. 7 1. Method according to claim 70, where the seed was pressed in the direction of It is normally perpendicular to the direction in which the auger is dragged across the grain. 7 2. Method according to claim 70, where the seed is pressed with a force of between 2.5 and approximately 5 pounds. According to claim 70, where the seeds are pressed in a direction normally parallel to the direction 7 4. Method according to claim 70, where the cutting edge on the drill is at an angle relative to the direction of drag. 70 where the cutting edge is on the drilling machine at an angle relative to the direction Of drag, in which at least two edges remain in contact with the grain because the auger has been dragged 7 6. Method according to claim 74, where the cutting edge on the drilling machine is at an angle of 60 ° relative to the Direction of drag 7 7. Approach to claim 74 where seeds are soybeans and manage moisture content of The soybean was then to be approximately 8% greater than before dragging the machine across the grain surface. 7 8. Method of claim 77, which consisted of managing soybean moisture content. To be at least approximately 12% before dragging the bore across the seed surface. 7. 9. Methods for removing tissue samples from the seed. Methods which include Dragging the auger with a number of cutting edges across the surface of the grain in order to remove the tissue. Away from the seed After tissue excision from the incision formed by the perforator and then following the tissue transport which was removed by the perforator, the tissue was cut away from the incision and the seed to separate the area of association that was Known for this reason after testing at least one sample The responsive seed tissue could be identified. 8 0. Method for claim 79 where seeds were soybeans and moisture content management of Soybeans next to be approximately 8% greater than before dragging the auger across the grain surface 8 1. Method according to claim 80, which consists of managing the moisture content of soybeans to At least approximately 12% before dragging the auger across the grain surface 8. 2. Methods for seed analysis in genetically different seed populations. Methods which include The removal of the sample, which consists of cells containing DNA, was removed from the seeds in the field without To be affected by the persistence of the seed growing; Extraction of DNA extracted from the sample for the presence or absence of genetic markers;