BR102020002819A2 - A HARVESTER TO CUT PLANTATIONS - Google Patents

Abstract

a harvester (100) for cutting crops is presented. the harvester (100) comprises a main frame (107), a frame (105) mounted on the main frame (107), an axis (110) located inside the frame (105), where at one end of the axis (110 ) there is a drive belt disk (115) and the other stitch is mounted on the main frame (107). furthermore, the combine (100) contains an eccentric weight (130) coupled to the shaft (110) and a blade (125) located at one end of the main structure (107). the drive belt disk (115) is connected to a power source. the drive belt disc (115) operates using a power source. when the drive belt disk (115) is driven by the power source, the disk (115) rotates the shaft (110). in addition, the eccentric weight (130) coupled to the axis (110) oscillates due to the change in its center of gravity. Due to its construction, the rotary movement of the shaft (110) is converted into oscillatory movement and the oscillatory movement is transferred to the blade (125). the oscillatory movement of the blade (125) is used to cut the crops as soon as they come into contact with the blade (125).

Description

A HARVESTER TO CUT PLANTATIONS FIELD OF THE INVENTION

[001] The present invention relates to agricultural tools such as harvesters. More specifically, the present invention relates to a harvester used to cut certain crops such as sugar cane, corn, sorghum and so on.

TECHNICAL STATUS

[002] Certain crops such as sugarcane, sorghum and other similar plants are known to be grown around the world. It is also known that sugar cane is native from tropical to temperate regions and that it has robust, articulate and fibrous stems that are rich in sugar. Typically, sugarcane can measure between two and six meters in height depending on the nature of the soil and climatic conditions. After being planted, a single sugar cane plant can be harvested several times and only needs to be replanted after a few years depending on the conditions and the type of harvest. After the first harvest, there is the growth of a new cane stem which is called "cane soca". After the second harvest, there is the growth of a new cane stem which is called "resoca".

[003] The harvest of sugar cane consists of cutting it at the base of the stem, removing the leaves, cutting into pieces of consistent sizes and, later, transporting it. Usually, sugarcane is harvested using a cane harvester that contains a cutting device.

[004] Several types of sugar cane harvesters have been introduced in the past. An example is United States patent 9894832. In US9894832B2, a cutter and a method for controlling it for harvesting sugarcane are described. The cutter may include a cutting spindle, a conveyor spindle, at least one power source for rotating the spindles, one or more blades attached to the cutting spindle and one or more transport devices attached to the conveyor spindle. The cutting spindle or the transport spindle can be configured to rotate together. The cutting spindle or the transport spindle can be rotated at different speeds using at least one power source. For example, a controller can determine the cutting speed of the cutting spindle and the transport speed of the transport spindle and control the power source to rotate the cutting spindle and the transport spindle at the cutting and transport speeds respectively.

[005] Another example is the United States patent 8452501. US8452501B1 presents a sugarcane harvester with an automatic height-cutting system that keeps cutting height consistent even when changing field conditions. After the operator has selected the height of the initial cut, the automatic system maintains the height even when there are changes in terrain conditions.

[006] Another example is the patent 8240115 also from the United States. US8240115B2 shows a sugarcane harvester (1) with a cabin (23), a chassis (5), a tip cutting device (2), a cane line divider device (3), a device base cutter (14), a set of rollers (6) to transport the cane, a cane cutting device (15), a cane cleaning device (8), a motor, an elevator (9) located on the central portion comprising a 180 degree rotation mechanism and a motor (12) located at the rear, regardless of the chassis. Each of the rollers (6) is powered by at least one hydraulic motor housed within the roller itself, with an opening provided in the chassis through which the motor can be removed.

[007] Although the harvesters presented above are capable of cutting sugar cane and even other crops, they do have some problems. Harvesters are huge and, as a result, they cannot be used by small farmers and many of them end up cutting cane by hand. In addition, the harvesters used to cut sugar cane do not cut it evenly, for example, and the choppers leave a comb-like structure in the sugar cane, affecting their growth later. In addition, small farmers need to walk through the sugarcane plantations to cut them, which can hurt them.

[008] In addition, large, heavy and fully automated harvesters compact the soil and damage the roots of the cane, which means that farmers have to replant the cane more often, thus increasing the cost of harvesting the cane.

[009] For this reason, there is a need for a harvester that has an oscillating blade that cuts the sugar cane and that does not damage the growth of the cane and the drift.

SUMMARY OF THE INVENTION

[010] One of the main objectives of the present invention is to supply the need for a harvester that contains an oscillating blade that can cut crops overcoming the problems of the state of the art.

[011] The present invention provides a harvester to cut crops. The harvester comprises a housing and an axle within the housing. The shaft has a drive belt disk at one end and a blade or chipper at the other. The drive belt disk and blade are coupled to the shaft with the aid of a pivot bearing. The harvester has an eccentric weight located on the other side of the axle. The blade is mounted on the main structure that holds the cutting blade; the shaft rotates freely in the bearing. In the event of an obstacle, such as a stone, the operation of the main structure is interrupted. The shaft continues to rotate freely at the bearing base without interrupting the drive. The oscillation movement is due to shaft misalignment due to the eccentric weight and the rotation of the shaft. The harvester further comprises a coupler used to couple the counterweight to the harvester, e.g., to the blade. The drive belt disk operates using a power source. When the drive belt disk is driven by the power source, the disk itself causes the shaft to rotate. In addition, the eccentric weight attached to the axle fluctuates due to the change in its center of gravity. Due to its construction, the rotary movement of the axis is converted into oscillatory movement and the oscillatory movement is transferred to the blade. The oscillating movement of the blade is used to cut the plants as soon as they come into contact with the blade.

[012] The drive belt disk is operated using a power source that can include an internal combustion engine, a hydraulic drive pump or an electric drive driven by a generator or battery.

[013] In one aspect of the present invention, a support system is mounted to the combine. The support system consists of an elongated rod attached to the wheels. The elongated stem is made up of guide rails arranged at an inclination of 30 to 90 degrees in relation to the elongated stem, causing the crops cut by the blade to fall off the guide rails, thus ensuring that the harvested and cut material does not become an obstacle to movement ahead of the support system.

[014] The above aspects, additional features and advantages of the invention will become more evident from the detailed description below, also making reference to the attached drawings, elucidating them.

BRIEF DESCRIPTION OF THE DRAWINGS

[015] The illustrative models of the present invention will be described in detail below, in line with the attached figures where:

[016] FIG.l represents the perspective view of the harvester 100 used to cut the crop, according to the model of the present invention;

[017] FIG.2 represents the harvester 100 containing a counterweight 140, according to the model of the present invention;

[018] FIG.3 represents the harvester 100 containing a movement stop 150, according to the model of the present invention;

[019] FIG.4 represents the harvester 100 containing a vibration stop 155, according to the model of the present invention;

[020] FIGS.5A, 5B and 5C represent the position of the blade in alignment with the neutral position, e.g., the central position, on the right and on the left, respectively, according to the model of the present invention;

[021] FIG.6 represents the harvester 100 coupled to a soil plow 200, according to the model of the present invention;

[022] FIG.7 represents the harvester 100 coupled to a support system 250, according to the model of the present invention;

[023] FIG.8 represents the support system 250 coupled to a trailer 300, according to the model of the present invention;

[024] FIG.9 represents the support system 250 coupled to an animal 310, according to the model of the present invention;

[025] FIG.10 represents the support system 250 coupled to a vehicle 350, according to the model of the present invention.

DETAILED DESCRIPTION

[026] The following detailed description is intended to provide examples of implementation for a person skilled in the art and is not intended to limit the invention to the presentation explained here, since a person skilled in the art will understand that variations can be substituted within the scope of the invention as described.

[027] The present invention provides a harvester to cut crops. The harvester comprises a housing and an axle within the housing. The shaft has a belt at one end and a blade or chipper at the other. The drive belt disk and blade are coupled to the shaft with the aid of a pivot bearing. The harvester has an eccentric weight that is screwed directly to the axle, which pierces the weight and is attached with a screw. The eccentric weight is located on the other side of the shaft. The blade further comprises a coupler used to couple the counterweight to the combine, e.g., the blade. The drive belt disk operates using a power source. When the drive belt disk is driven by the power source, the disk itself causes the shaft to rotate. In addition, the eccentric weight attached to the axle fluctuates due to the change in its center of gravity. Due to its construction, the rotary movement of the axis is converted into oscillatory movement and the oscillatory movement is transferred to the blade. The oscillating movement of the blade is used to cut the plants as soon as they come into contact with the blade.

[028] Various models of the combine to cut crops will be explained with the help of Figures 1 - 10.

[029] According to FIG.1, a perspective view of the sugarcane harvester or cutter or cutting device 100 used to cut crops, according to the model of the present invention, is presented. The combine 100 comprises a housing 105. The housing 105 can be made of metal or any other suitable material. Frame 105 is mounted to main frame 107. Main frame 107 serves as the base on which frame 105 is mounted. Combine harvester 100 contains a shaft 110 within housing 105. At one end, shaft 110 contains a drive belt disk 115 coupled with a pivot bearing 120. At the other end, shaft 110 is mounted to main frame 107. In one main frame tip 107, there is a blade or chipper 125. At the other end of shaft 110, a second bearing can be added to secure the position of shaft 110. Blade 125 is attached to shaft 110 using mechanisms such as fasteners, straps, soldering or others.

[030] In addition, the harvester 100 contains an eccentric weight 130 contained at the other end of the shaft 110. The blade 125 also contains a coupler 135 used to attach a counterweight to the harvester 100, eg, to the blade 125. According to FIG. 2, a counterweight 140, eg, is shown in the main structure 107 coupled to the blade 125, according to the model of the present invention. In addition, the harvester 100 has a movement stop mounted on the frame 105. In FIG. 3, the movement stop 150 of the combine 100 is shown. The movement stop 150 may include rubber or springs. It should be noted that the combine 100 has two movement stoppers 150, each mounted on a different side of the structure 107. The movement stopper 150 is adjustable allowing you to configure the exact shape and / or reach of the blade 125 according to the center line of the main structure cutting device 107. In addition, the movement stop 150 has the functions of damping and suspension.

[031] In addition, the combine 100 has a vibration stopper or damper 155, as shown in FIG.4. The vibration stop 155 can be mounted on the movement limiter 150. The vibration stop 155 flattens the height range. In addition, the vibration stop helps to define the range of movement of the blade 125 in the event of sudden external movements, ensuring that energy is stored to assist in accelerating the blade 125 again. According to FIG.5A, 5B and 5C, the position of the blade in alignment with the neutral position, e.g., the central position, on the right and on the left, respectively, are presented according to the model of the present invention.

[032] In order to operate the combine 100 to cut crops such as sugar cane, corn, sorghum and the like, the combine 100 is coupled to a power source to drive the drive belt disk 115. The source of energy can be obtained through one or more methods.

[033] In one example, the combine 100 can be coupled to an internal combustion engine (not shown) to drive the drive belt disk 115. In another example, the combine 100 can be coupled to a hydraulic pump (not shown) ) to drive the drive belt disk 115. In yet another example, the combine 100 can be attached to a battery (not shown) to electrically drive the drive belt disk 115. The battery can be contained in the combine 100 or can be contained externally to the combine 100. For example, the battery can transfer electrical energy from sources such as another battery or generator, eg, from the PTO (English power take off) of a tractor or an ICE (from the English internal combustion engine).

[034] When the drive belt disk 115 is driven by the power source, the drive belt disk 115 rotates the shaft 110. In addition, the eccentric weight 130 coupled to the shaft 110 oscillates due to the change in the center of gravity. Due to the construction or coupling of the shaft to blade 125, the rotary movement of shaft 110 is converted into oscillatory movement, and the oscillatory movement is transferred to blade 125. The oscillatory movement of blade 125 is used to cut crops, such as sugar cane, sorghum or other similar to cane, when they come in contact with blade 125. It is necessary to specify that the height of blade 125 must be adjusted in order to cut the plantations at a certain height from the ground.

[035] Combine harvester 100 can be operated in conjunction with one or more mechanisms or machines by those who are versed in the technique of moving harvester 100 forward or backward to cut crops. It is necessary to specify that the cut occurs only in the direction of drive of the drive belt disk 115, which is directed according to the orientation of the blade teeth. In FIG. 6, there is shown the combine 100 coupled to a soil plow 200, according to the model with the model of the present invention. As can be seen, the combine 100 can be coupled to the front plow 200 from the front. The operator can push or move the soil plow 200 containing the harvester 100 in such a way that the blade 125 oscillates with the operation of the drive belt disk 115 and the shaft 110, and cut the plants that come into contact with the plow. solo 200 is moved forward. When the combine 100 is connected to the soil plow, the drive need not necessarily be through a drive belt; it can also be driven directly by a drive shaft or hydraulically.

[036] In one implementation, the combine 100 can be placed on a support system 250 to facilitate the movement of the combine 100 in the field. In FIG.7, the harvester 100 coupled to the support system 250 is shown, according to the model with the model of the present invention. The support system 250 contains an elongated rod 255 coupled to wheels 260 arranged at both ends. In addition, the elongated rod 255 may have guide rails 265 at both ends. Guide rails 265 are adjusted depending on the growing conditions of the cane. It should be clear to a person skilled in the art that the guide rails 265 are arranged at an angle between 30 and 90 degrees in relation to the elongated stem 255. The combine 100 is arranged between the guide rails 265. It is necessary to specify that the guide rails 265 they must be arranged in an inclination in such a way that the guide rails 265 ensure that the plants, such as those of sugar cane, are pushed inwards, ensuring that they are aligned with the blade 125. Therefore, when the support 250 containing the combine 100 is moved forward, the crops, such as those of sugar cane, are aligned with the blade 125 and are cut. The cut sugar cane must fall off the guide rails 265 to ensure that they do not become an obstacle to movement ahead of the support system 250 containing the combine 100.

[037] The support system 250 can be operated with the aid of different mechanisms. In FIG.8, the support system 250 coupled to the trailer 300 is shown, according to an exemplary model of the present invention. As can be seen, the support system 250 can be coupled to the trailer 300 in such a way that the operator can push the trailer 300 to move the support system 250 containing the harvester 100 forward to cut the crops.

[038] In another implementation, the support system 250 can be pulled by an animal 310 in order to move forward the support system 250 containing the harvester 100 to cut the crops. In FIG.9, the support system 250 coupled to an animal 310 with the aid of a cable, according to an exemplary model of the present invention, is shown. Animal 310 is guided forward in such a way that the support system 250 is pulled and the harvester 100 is moved forward. As explained above, the combine 100 contains a blade 125 that oscillates with the aid of an internal combustion engine or battery. When the combine 100 is moved forward, the oscillating blade 125 comes into contact with the crop and cuts it. The cut plants must then fall off the guide rails 265 to ensure that they do not become an obstacle to movement ahead of the support system 250 containing the harvester 100.

[039] In another implementation, the support system 250 can even be pulled by a vehicle 350, such as a tractor in order to move forward the support system 250 that contains the harvester 100 to cut the crops. In FIG.10, a support system 250 coupled to a vehicle 350 is shown, according to an exemplary model of the present invention. Vehicle 350 may contain a three-point hitch 355, where one of the hitch points 360 may be used to guide the harvester 100, eg, the drive belt disc 155. In order to operate the harvester 100, the vehicle 350 is turned on and the combine 100 is operated with the aid of a 360 steering cable. The vehicle 350 is moved forward in such a way that the support system 250 is pulled and the combine 100 is also moved forward. As explained above, the combine 100 contains the blade 125 oscillating with the aid of an internal combustion engine or electrically (generator or battery). When the combine 100 is moved forward, the oscillating blade 125 comes into contact with the crops and cuts them. The cut plants must then fall off the guide rails 265 to ensure that they do not become an obstacle to movement ahead of the support system 250 containing the harvester 100.

[040] When the harvester is moved forward, the sugar cane is lifted from the ground, so that the blade can cut it. As is known, sugar cane does not always grow strictly in a straight line, it can be vertical, but it can also grow lying on the ground. In order to cut the cane that grows in different directions, it is guided to the side of the blade with the aid of drills or guide rails, away from the main plantation awaiting cleaning and transportation. In addition, the blade can be of different shapes, which will assist in cleaning and transporting it to a sugar cane truck.

[041] Based on those described above, it is clear that the combine 100 can be used to cut crops, such as sugar cane, using a single oscillating blade. The oscillating blade is driven by an internal combustion engine or an electric motor.

[042] Since the small farmer or operator does not have to contact the plantation, the harvesting process becomes more secure. In addition, the combine that contains a single oscillating blade can be guided through all types of sugarcane plantations. The harvester is a cutting device that is affordable for small farmers, which reduces the cost of manually harvesting sugarcane.

[043] As specified above, the height of the blade in relation to the ground can be adjusted based on local conditions, such as rough terrain, low and swampy terrain or even on compacted soil. Thanks to this characteristic, the farmer can have the freedom to harvest sugar cane in all circumstances. In addition, due to the migration of farmers to the cities and the reduction of labor, the harvester provides an easy solution for small farmers to harvest sugarcane.

[044] Due to the design of the combine, crops can be cut with a minimum number of moving parts, thus reducing the weight of the combine. Through its efficient design, the farmer will be able to harvest without damaging the roots of the sugar cane and without compacting the soil.

[045] It should be clear to a person skilled in the art that the use of the harvester to cut crops includes, but is not limited to, sugarcane, corn, bamboo, etc.

[046] The above description provides a better understanding of the objectives and advantages of the present invention. Different models can be made based on the concept of this invention. It should be known for all purposes presented on this subject that it should be interpreted purely for illustrative purposes and not strictly.

Claims (10)

Combine harvester (100) to cut crops, the harvester being composed of:
a main structure (107);
a housing (105) mounted on the main structure (107);
an axle (110) located inside the housing (105), where one end of the axle (110) has a drive belt disc (115) and the other end is mounted on the main frame (107);
an eccentric weight (130) coupled to the shaft (110) and
a blade (125) located on one side of the main structure (107);
characterized by containing the drive belt disk (115) connected to a power source for its activation, thus the drive belt disk (115) rotates the shaft (110) resulting in the eccentric weight oscillation (130) due to the change at its center of gravity, in which the rotary movement of the axis (110) is transferred to the blade (125) to cut the plants as soon as they come into contact with the blade (125). Combine harvester (100) according to claim 1, characterized by having a power source to drive the drive belt disk (115) which includes an internal combustion engine, a hydraulic pump, a battery and an electric power source . Combine harvester (100) according to claim 1, characterized by having a drive belt disk (115) coupled to the shaft (110) through a pivoting bearing (120). Combine harvester (100) according to claim 1, characterized by having a counterweight (140) mounted to the main structure (107). Combine harvester (100) according to claim 1, characterized by having a support system (250) for assembling the harvester (100), in which the support system (250) consists of an elongated rod (255) coupled to the wheels (260), in which the elongated rod (255) still contains guide rails (265). Combine harvester (100) according to claim 5, characterized in that the guide rails (265) are arranged so as to be inclined to guide and raise the plantations towards the blade (125). Combine harvester (100) according to claim 6, characterized by having guide rails (265) arranged at an inclination of 30 to 90 degrees in relation to the elongated stem (255) so that the plants cut by the blade (125) fall out of the guide rails (265) thus ensuring that they do not impede movement in front of the support system (250). Combine harvester (100) according to claim 5, characterized by having a support system (250) coupled to a trailer (300) or vehicle (250) to move the harvester (100). Combine harvester (100) to cut crops, the harvester being composed of:
a housing (105) mounted on the main structure (107);
an axle (110) located inside the housing (105), where one end of the axle (110) has a drive belt disc (115) and the other end is mounted on the main frame (107);
an eccentric weight (130) coupled to the shaft (110) and
a blade (125) located on one side of the main structure (107);
characterized by containing the drive belt disk (115) connected to a power source for its activation, thus the drive belt disk (115) rotates the shaft (110) resulting in the eccentric weight oscillation (130) due to the change at its center of gravity, in which the rotary movement of the axis (110) is transferred to the blade (125) to cut the plants as soon as they come into contact with the blade (125); and
the harvester (100) further comprises a support system (250) for mounting the harvester (100), in which the support system (250) contains an elongated rod (255) coupled to the wheels (260), in which the rod elongated (255) contains guide rails (265), plus the guide rails (265) arranged at an inclination of 30 to 90 degrees in relation to the elongated stem (255) so that the plants cut by the blade (125) fall out the guide rails (265) thus ensuring that they do not impede movement in front of the support system (250). Combine harvester (100) according to claim 9, characterized by having a support system (250) coupled to a trailer (300) or vehicle (250) to move the harvester (100).

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