| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 一种新型用于割台的绞龙机构 | CN201710590303.7 | 2017-07-19 | CN107318366A | 2017-11-07 | 宋翔文; 曹树坤; 申昊; 王恒; 马令然 |
| 本发明公开了一种新型用于割台的绞龙机构,属于机械制造技术领域,为解决现有技术中绞龙的一体导致割台无法折叠且占据空间位置大的问题。本发明包括轴承座、转动架、L型支撑板、横推液压缸、推力液压缸、连接板、导流板、前置方钢、绞龙连接毂、轴向侧板、绞龙、合页、液压缸固定座、支撑方管,轴承座与轴向侧板通过轴孔配合,轴承座与绞龙连接毂同轴心配合,转动架与连接板通过螺栓连接,连接板与L型支撑板相互配合,横推液压缸与液压缸固定座通过螺栓连接,各段绞龙通过连接毂将各段绞龙配合起来,液压缸固定座与支撑方管相互配合。本发明属于玉米收获机械技术领域,结构简单,可实现绞龙自动分段折叠、减小占据空间位置。 | ||||||
| 2 | ACOUSTIC MATERIAL FLOW SENSOR | EP15840433 | 2015-09-14 | EP3190866A4 | 2018-05-02 | GELINSKE JOSHUA N; BATCHELLER BARRY D; NYSTUEN PAUL A; REICH ADAM A; THUROW BRADLEY R; SCHLEUSNER BRADLEY K |
| A grain quality sensor comprising a lens, a filter, a photosite array, an illumination source, and an electronics module, wherein the illumination source directs light containing a known set of wavelengths onto a crop sample, wherein the lens picks up light reflected by the crop sample and directs it into the filter, which allows light to pass into different parts of the photosite array such that certain locations on the photosite array only get certain frequencies of the reflected light, wherein the electronics module is electrically connected to the photosite array and capable of determining which parts of the photosite array received light and what frequency the light received was, wherein the electronics module can analyze the optical data received by the photosite array, and wherein the analysis of the optical data is used to determine the composition of different parts of the crop sample. | ||||||
| 3 | AUTOMATIC LOAD CONTROL FOR SELF-PROPELLED WINDROWER | EP15706564.0 | 2015-01-30 | EP3099156A1 | 2016-12-07 | SOLDAN, Daniel; NAFZIGER, Brendon; BOLLINGER, Shane |
| A windrower has a hydrostatic header drive system with a header drive pump and one or more header drive motors. The windrower also has a chassis with wheels coupled thereto, an engine, and a ground drive system coupled to the wheels and the engine. A control system has plural sensors having first, second, and third sensors, wherein the first sensor monitors engine load, the second sensor monitors hydrostatic header drive pressure, and the third sensor monitors ground speed. The control system has one or more controllers configured to receive input from the plural sensors, compare the input with respective target values for engine load, header drive pressure, and ground speed throughout a range of ground speeds defined based on an operator configured maximum ground speed, and automatically adjust the ground speed based on the comparison. | ||||||
| 4 | 농업 운반기에 구축될 수 있는 알맹이 작물에 대한 자동 연속 수거시스템 | KR1020090072273 | 2009-08-06 | KR1020110014762A | 2011-02-14 | 박정기 |
| PURPOSE: An automatic grain crops collection system is provided, which can pack grain crops in the fixed quantity while removing foreign material. CONSTITUTION: An automatic grain crops collection system comprises: an automatic grain crops rake instrument which successively collects grain crops including soils and transfers them rearward; a horizontal transfer apparatus eliminating foreign material included in grain crops while transferring the grain crops to the rear of the rake instrument; a vertical transfer apparatus transferring grain crops transferred by the horizontal transfer apparatus upward; and a grain crops recovery system. | ||||||
| 5 | 마늘 수확용 빗질기 | KR1020080058082 | 2008-06-19 | KR1020090132029A | 2009-12-30 | 강병재 |
| PURPOSE: An arranging machine for garlic harvest is provide to facilitate garlic harvest, to prevent garlic from damaging, and to easily remove vinyl sheets put on a garlic field. CONSTITUTION: An arranging machine for garlic harvest includes a pair of rotation supports(30), a shaft(40) rotatably supported on an agricultural machinery, a comb member(50) which is formed in a comb shape, rotatably connected with the shaft, and placed in the front of a garlic picker, a plurality of prong members(60) which are hung on the comb member and rotatably installed in the shaft, respectively, a plurality of elastic members(70) which apply force to make the comb member and prong members pull each other, and a hanger(80) which hangs and supports the comb member on the agricultural machinery. | ||||||
| 6 | 땅속작물 수확장치 | KR1020100046045 | 2010-05-17 | KR1020110126392A | 2011-11-23 | 김정선 |
| PURPOSE: An apparatus for harvesting an underground crop is provided to increase working efficiency and harvest efficiency by simultaneously cutting the stem of the crops and harvesting the underground crop. CONSTITUTION: A body(110) prevents the cut stem and underground crops from being scattered. A support unit(112) is formed on both upper sides of the body. A reinforcement unit(113) is connected from the middle of the support unit to the rear of the upper side of the body. A through hole is formed in the middle of the upper side of the body. A discharge member is formed on the lower side of the rear of the body. A bracket is installed in the lower side of the body. A plurality of rollers are arranged in the bracket. An excavating member excavates the underground crop. A mounting bracket is installed on the lower side of the middle of the body. | ||||||
| 7 | 땅속작물 수확장치용 절단부재 | KR1020100045685 | 2010-05-14 | KR1020110126007A | 2011-11-22 | 김정선 |
| PURPOSE: A cutting member for a root crops harvesting device is provided to improve work efficiency by simultaneously performing cutting and collecting the stem of crops. CONSTITUTION: A cutting member for a root crops harvesting device comprises a body(110), a gear-box(120), a rotary shaft(130), a plurality of cutting blades(140), a plurality of combining bodies, a rake(160), and a driving unit(170). A plurality of cutting blades are installed in order to corresponded to the location of furrows in the longitudinal direction of the rotary shaft. In the center of a plurality of cutting blades, a combining hole is formed. In the center of the combining body, a through-hole is formed. In the external diameter of the combining body, a plurality of insertion holes are radially formed. In the surface of the combining body, a plurality of mounting holes are radially formed. The driving unit rotates the rotary shaft by being delivered with power from a driving shaft. | ||||||
| 8 | SWATHER WITH A SINGLE OR DOUBLE RAKING FRAME | EP13795571.2 | 2013-09-10 | EP2894961B1 | 2018-11-14 | GIOVANNINI, Adelmo |
| A swather having a horizontal bar with a device for connection to a towing vehicle and a generally horizontal bar, transverse to the first one, each end of which is associated with a generally vertical member bearing a wheel. The assembly of the transverse bar and the vertical members being associated with generally horizontal long arms directed toward a first end of the first horizontal bar and pivotally connected to the transverse bar or the vertical members, so that the arms, when extended to a working position, provide a V-shaped or Y-shaped configuration. Each arm is equipped with a pivoting wheel with tire at its end remote from the transverse bar, or distal end, and with wheel rakes. At least the pivoting wheels with tires are equipped with shock absorbing means capable of attenuating impulsive loads due to impact of the wheels against ground irregularities. | ||||||
| 9 | NON-IMAGE-BASED GRAIN QUALITY SENSOR | EP15839749 | 2015-09-14 | EP3192011A4 | 2018-05-02 | BUTTS NICHOLAS L; BREMER MARSHALL T; TOLSTEDT JONATHAN L |
| A grain quality sensor comprising a lens, a filter, a photosite array, an illumination source, and an electronics module, wherein the illumination source directs light containing a known set of wavelengths onto a crop sample, wherein the lens picks up light reflected by the crop sample and directs it into the filter, which allows light to pass into different parts of the photosite array such that certain locations on the photosite array only get certain frequencies of the reflected light, wherein the electronics module is electrically connected to the photosite array and capable of determining which parts of the photosite array received light and what frequency the light received was, wherein the electronics module can analyze the optical data received by the photosite array, and wherein the analysis of the optical data is used to determine the composition of different parts of the crop sample. | ||||||
| 10 | AUTOMATIC LOAD CONTROL FOR SELF-PROPELLED WINDROWER | EP15706564.0 | 2015-01-30 | EP3099156B1 | 2018-03-21 | SOLDAN, Daniel; NAFZIGER, Brendon; BOLLINGER, Shane |
| A windrower has a hydrostatic header drive system with a header drive pump and one or more header drive motors. The windrower also has a chassis with wheels coupled thereto, an engine, and a ground drive system coupled to the wheels and the engine. A control system has plural sensors having first, second, and third sensors, wherein the first sensor monitors engine load, the second sensor monitors hydrostatic header drive pressure, and the third sensor monitors ground speed. The control system has one or more controllers configured to receive input from the plural sensors, compare the input with respective target values for engine load, header drive pressure, and ground speed throughout a range of ground speeds defined based on an operator configured maximum ground speed, and automatically adjust the ground speed based on the comparison. | ||||||
| 11 | ACOUSTIC MATERIAL FLOW SENSOR | EP15840433.5 | 2015-09-14 | EP3190866A1 | 2017-07-19 | GELINSKE, Joshua N.; BATCHELLER, Barry D.; NYSTUEN, Paul A.; REICH, Adam A.; THUROW, Bradley R.; SCHLEUSNER, Bradley K. |
| A grain quality sensor comprising a lens, a filter, a photosite array, an illumination source, and an electronics module, wherein the illumination source directs light containing a known set of wavelengths onto a crop sample, wherein the lens picks up light reflected by the crop sample and directs it into the filter, which allows light to pass into different parts of the photosite array such that certain locations on the photosite array only get certain frequencies of the reflected light, wherein the electronics module is electrically connected to the photosite array and capable of determining which parts of the photosite array received light and what frequency the light received was, wherein the electronics module can analyze the optical data received by the photosite array, and wherein the analysis of the optical data is used to determine the composition of different parts of the crop sample. | ||||||
| 12 | SWATHER WITH A SINGLE OR DOUBLE RAKING FRAME, DEVICE FOR ARMS WITH WHEEL RAKES AND CORRESPONDING WHEEL RAKES | EP13795571.2 | 2013-09-10 | EP2894961A2 | 2015-07-22 | GIOVANNINI, Adelmo |
| A swather having a horizontal bar with a device for connection to a towing vehicle and a generally horizontal bar, transverse to the first one, each end of which is associated with a generally vertical member bearing a wheel. The assembly of the transverse bar and the vertical members being associated with generally horizontal long arms directed toward a first end of the first horizontal bar and pivotally connected to the transverse bar or the vertical members, so that the arms, when extended to a working position, provide a V-shaped or Y-shaped configuration. Each arm is equipped with a pivoting wheel with tyre at its end remote from the transverse bar, or distal end, and with wheel rakes. At least the pivoting wheels with tyres are equipped with shock absorbing means capable of attenuating impulsive loads due to impact of the wheels against ground irregularities. | ||||||
| 13 | PICKUP REEL FOR A CROP HARVESTING HEADER | US16196371 | 2018-11-20 | US20190082601A1 | 2019-03-21 | Glenn Raymond HONEY; Lee Glenn HARPER |
| A crop harvesting header including a pickup reel mounted for rotation about a reel axis is disclosed and includes a plurality of reel bats peripherally disposed on the reel each having a plurality of outwardly extending fingers and being rotatable about a bat axis. A cam track adjacent to and surrounding the reel axis is immobilized w.r.t. the header and includes a cam surface and a guide surface. A linkage associated with each reel bat has first and second spaced apart cam followers that engage the cam surface at respective points of contact. The cam surface causes displacement of the linkage while traversing the cam track during rotation of the reel, the linkage being coupled to cause rotation of the reel bat about the bat axis for changing an angle of attack of the fingers. A guide follower disposed for engagement of the guide surface at a third point of contact between the first and second points of contact has an offset between the guide surface and the cam surface along the cam track selected to cause each of the first and second cam followers to maintain contact with the cam surface and the guide follower to maintain contact with the guide surface while traversing the cam track. | ||||||
| 14 | DEVICE FOR REMOVING VINES FROM SWEET POTATO AND THE LIKE | US15608875 | 2017-05-30 | US20180343795A1 | 2018-12-06 | Peter Jerry VanBerlo |
| A vine removal device comprises a frame and a pair of spaced-apart vine agitators movably carried by the frame so as to form a vine-feeding maw or throat between the vine agitators. A driven vine-cutter is movably carried by the frame and driven relative to the frame, and is disposed in registration with the maw to receive and cut vines fed into the maw by the vine agitators. One or more drive mechanisms are drivingly coupled to the vine-cutter and the vine agitators to drive the vine-cutter and the vine agitators. The vine agitators capture the vines and feed them into the maw, where the vines are cut into mulch by the vine-cutter. A vine removal implement may comprise a plurality of the vine removal devices arranged in side-by-side relation to traverse along a series of sweet potato rows. | ||||||
| 15 | Look-ahead crop mass predictive sensor | US14853990 | 2015-09-14 | US09775290B2 | 2017-10-03 | Bradley K. Schleusner; Marshall T. Bremer; Nicholas L. Butts; Flemming Schøler |
| A crop mass predictive sensor, comprising an imaging device, a laser-based device such as a LIDAR, a first radar emitting a frequency of energy that is absorbed by plant mass, and a second radar emitting a frequency of energy that passes through plant mass without being absorbed, wherein the imaging device, laser-based device, first radar, and second radar are focused on the crop material in front of an agricultural vehicle, and the information gathered from the imaging device, laser-based device, first radar, and second radar is used to calculate an estimated mass for the crop material that is about to enter the agricultural vehicle. | ||||||
| 16 | Crop quality sensor based on specular reflectance | US14853978 | 2015-09-14 | US09723784B2 | 2017-08-08 | Marshall T. Bremer; Nicholas L. Butts |
| A crop quality sensor, comprising an illumination source, an imaging device, and a processor executing application software. The illumination source is shone onto a crop sample, and an image is taken with the imaging device of the illuminated crop sample. The software executing on the processor is used to analyze the image to identify the outlines of individual kernels and to identify which of those outlines contain a specular highlight, indicative that the kernel is whole and unbroken, while the absence of such a specular highlight is indicative of a broken kernel. | ||||||
| 17 | Automatic load control for self-propelled windrower | US15113598 | 2015-01-30 | US09668419B2 | 2017-06-06 | Daniel Soldan; Brendon C. Nafziger; Shane Bollinger |
| A windrower has a hydrostatic header drive system with a header drive pump and one or more header drive motors. The windrower also has a chassis with wheels coupled thereto, an engine, and a ground drive system coupled to the wheels and the engine. A control system has plural sensors having first, second, and third sensors, wherein the first sensor monitors engine load, the second sensor monitors hydrostatic header drive pressure, and the third sensor monitors ground speed. The control system has one or more controllers configured to receive input from the plural sensors, compare the input with respective target values for engine load, header drive pressure, and ground speed throughout a range of ground speeds defined based on an operator configured maximum ground speed, and automatically adjust the ground speed based on the comparison. | ||||||
| 18 | REEL SYSTEM | US15353487 | 2016-11-16 | US20170055452A1 | 2017-03-02 | Glenn HONEY |
| A crop harvesting header includes a reel rotatable about a reel axis. The reel has a reel bat supported at a spaced distance from the reel axis. The reel bat can pivot about a bat axis radially spaced from the reel axis. The reel bat has a crop collection member that extends generally away from the bat axis. The reel bat can move in a cyclical path around the reel axis during rotation of the reel. The reel bat can vary the angle of the crop collection member about the bat axis as the reel rotates about the reel axis. A sun gear is provided that may be positioned in axial alignment with the reel axis. A planetary gear system is rotatable about the sun gear. The planetary gear system interacts with the sun gear, and causes said planetary gear system to effect pivotal movement of the reel bat about its bat axis. | ||||||
| 19 | MODULAR GATHERING PLATFORM FOR GRAIN HARVESTERS | US15192631 | 2016-06-24 | US20170000028A1 | 2017-01-05 | Luiz Henrique BERTINO |
| A modular gathering platform for grain harvesters, for coupling to the front of a grain harvester or processor, with means to gather plants previously prepared in one or more rows by at least one central belt conveyor with functional side by side coupling means to other equal harvesting conveyor belts, all of them positioned with their variable inclination, with their front extremity stays level with the ground to gather a row that was previously prepared, while their opposite extremities are also equally aligned with their respective anti jamming roll, these rolls and the upper extremities of the conveyors belts are assembled on the front of a transversal mounting structure that, by its outer rear, has an ample exit for harvested plants, as it also equipped with articulated means for coupling to the front of a general machine that will process the harvested plants. | ||||||
| 20 | NON-IMAGE-BASED GRAIN QUALITY SENSOR | US14853971 | 2015-09-14 | US20160078611A1 | 2016-03-17 | Nicholas L. Butts; Marshall T. Bremer; Jonathan L. Tolstedt |
| A grain quality sensor comprising a lens, a filter, a photosite array, an illumination source, and an electronics module, wherein the illumination source directs light containing a known set of wavelengths onto a crop sample, wherein the lens picks up light reflected by the crop sample and directs it into the filter, which allows light to pass into different parts of the photosite array such that certain locations on the photosite array only get certain frequencies of the reflected light, wherein the electronics module is electrically connected to the photosite array and capable of determining which parts of the photosite array received light and what frequency the light received was, wherein the electronics module can analyze the optical data received by the photosite array, and wherein the analysis of the optical data is used to determine the composition of different parts of the crop sample. | ||||||
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