阅读说明：本技术 具有改进的根部切割器齿轮箱组件的甘蔗收割机 (Sugarcane harvester with improved base cutter gearbox assembly ) 是由 考希克·阿尼尔巴伊·达马尼 于 2020-03-17 设计创作，主要内容包括：一种具有改进的根部切割器齿轮箱组件的甘蔗收割机。本发明涉及一种甘蔗收割机并且更5具体地涉及一种具有改进的根部切割器齿轮箱组件的甘蔗收割机。改进的根部切割器齿轮箱组件包括被描绘为根部切割器单元的根部切割器齿轮箱的配置。如所描绘的,输入接口是花键连接器,其被配置为接收液压马达的输出轴。被配置为使得在接口处接收到一个液压马达的10旋转动力的输入接口引起小齿轮(2)旋转。小齿轮(2)又使主齿轮(1)和惰轮正时齿轮(3)旋转。然后惰轮正时齿轮(3)使主齿轮(4)旋转。用在根部切割器齿轮箱处的上述齿轮使用被设计为保持和减轻每个齿上的负载并产生力从一个齿到下一个齿的平滑15过渡的最佳螺旋角。从而减少振动、磨损、噪音并延长使用寿命。(A sugar cane harvester having an improved base cutter gearbox assembly. The present invention relates to a sugar cane harvester and more particularly to a sugar cane harvester having an improved base cutter gearbox assembly. The improved base cutter gearbox assembly includes a configuration of a base cutter gearbox depicted as a base cutter unit. As depicted, the input interface is a splined connector configured to receive an output shaft of the hydraulic motor. An input interface configured such that 10 rotational power of one of the hydraulic motors is received at the interface causes the pinion (2) to rotate. The pinion (2) in turn rotates the main gear (1) and the idler timing gear (3). The idler timing gear (3) then rotates the main gear (4). The above-described gears used at the base cutter gearbox use an optimal helix angle designed to maintain and relieve the load on each tooth and create a smooth 15 transition of force from one tooth to the next. Thereby reducing vibration, abrasion, noise and prolonging service life.)

1. A sugar cane harvester with an improved base cutter gearbox assembly comprising a pair of rotatable base cutters (7a, 7b), a helical gearbox assembly connected to the base cutters (7a, 7b) and a hydraulic motor (5) for driving the helical gearbox assembly;

the pair of rotatable base cutters (7a, 7b) having protruding blades (8a, 8 b);

characterized in that the gearbox assembly comprises: main gears (1) and (4) having a plurality of serrations on the outer circumference; a pinion gear (2) having a plurality of saw teeth on an outer circumference thereof and engaged with the saw teeth of the main gear (1); an idler timing gear (3) accommodating a spline coupler having a plurality of serrations on an outer periphery thereof and meshing with the serrations of the pinion gear (2) and the serrations of the main gear (4).

2. The sugar cane harvester with improved base cutter gearbox assembly of claim 1 wherein the main gear (1, 4), the pinion (2) and the idler timing gear (3) have optimum helical angle teeth.

3. The sugar cane harvester with an improved base cutter gearbox assembly according to claim 1, characterized in that the base cutters (7a, 7b) are operatively connected with the main gear (1, 4) by means of vertical shafts (6a, 6b), respectively.

4. The sugar cane harvester with improved base cutter gearbox assembly of claim 1 wherein the pinion gear (2) is driven by the motor (5) through a splined connector (2) connected to a shaft of the motor (5).

5. A method of operating a sugar cane harvester having an improved base cutter gearbox assembly, the method of operation comprising the steps of:

a) receiving rotational power from the hydraulic motor (5) to the spline connector through the output shaft;

b) rotating the pinion (2) by means of a splined connection;

c) rotating a main gear (1) and an idler timing gear (3) by a pinion (2);

d) the main gear (4) is rotated by an idler timing gear (3).

e) A pair of rotatable base cutters (7a, 7b) are rotated by the main gears (1, 4) via the vertical shafts (6a, 6b), respectively.

Technical Field

The present invention relates to a sugar cane harvester, and more particularly to a sugar cane harvester having an improved base cutter gearbox assembly.

Background

There are various types of sugar cane harvesters in the art that harvest growing sugar cane stalks by cutting the cane at the root of the cane and then transferring the cut cane to a collection vehicle such as a cane carriage or cane cart. The sugar cane harvester may include different types of harvesting devices. Harvesting apparatus for a sugar cane harvester may include components for cutting, chopping, sorting, transporting, and collecting and processing sugar cane plants. Typically, harvesting devices include crop separator assemblies, knock down roller assemblies, base cutter assemblies, feed rollers, cutting drums, and the like.

For dynamic crop harvesting, a harvester having the above harvesting apparatus may be moved along a field, wherein the harvesting apparatus performs collection and processing of material from a crop plant train. The base cutter is configured to minimize the amount of soil fed into the harvester with the crop. The base cutter gear box of prior art sugar cane harvesters has a spur gear with the surface in rolling contact but with straight cut teeth on the face; one or both teeth are always in contact with the other gear. This incomplete face engagement means that spur gears are more noisy and vibrate more than helical gears.

Furthermore, the life of the prior art base cutter gearbox with spur gears is much shorter than that of helical gears. After about three years they are usually replaced. Frequent replacement requires more capital and increases maintenance, downtime, and waste disposal costs.

Furthermore, in the prior art, the base cutter gearbox causes too much noise and vibration, which means low precision and limited service life. Noisy and vibrating rotating machines can present a number of quality problems: the rotating parts are not properly balanced; the tolerance of the mating parts is too large; and the parts are not sufficiently rigid to bend under load and cause misalignment.

Furthermore, a disadvantage of the prior art base cutter gearbox is that the second quality indicator is overheated. It equates to low efficiency and wasted energy. Heat generation in rotating machines can also have many causes, including inefficient design, misalignment, incorrect fit, and seal resistance. The low-quality gear reducer is a main cause of excessive energy consumption. These gearboxes can become very hot.

Accordingly, there is a significant need to invent a sugar cane harvester with an improved base cutter gear assembly to avoid noise and vibration, misalignment, excessive energy consumption, improper fit, seal resistance and overheating.

Object of the Invention

It is a primary object of the present invention to overcome the problems associated with the base cutter gear box assembly of a sugar cane harvester by providing an improved base cutter gear assembly for proper harvesting in the field.

It is another object of the present invention to provide an improved base cutter gearbox assembly to maintain and alleviate the load on each tooth and create a smooth transition of force from one tooth to the next, reduce vibration, wear and noise and extend service life.

It is a further object of the present invention to provide an improved base cutter gearbox assembly for allowing efficient gear meshing.

Moreover, it is another object of the present invention to provide an improved base cutter gearbox assembly for improving efficiency and providing an efficient design to eliminate misalignment, improper fit, seal resistance and overheating.

Moreover, another object of the present invention is to provide an optimized base cutter gearbox.

Disclosure of Invention

The present invention relates to a sugar cane harvester, and more particularly, it relates to a sugar cane harvester having an improved base cutter helical gear box assembly. The improved base cutter helical gearbox assembly has a configuration depicted as a base cutter unit. As depicted, the input interface is a spline connector configured to receive an output shaft of a hydraulic motor. The input interface is configured such that rotational power of one of the hydraulic motors received at the interface causes the pinion to rotate. The pinion gears in turn rotate a main gear and idler timing gear. The idler timing gears then rotate the main gear. The above-described gears used at the base cutter gearbox use an optimal helix angle designed to maintain and alleviate the load on each tooth and create a smooth transition of force from one tooth to the next, thereby reducing vibration, wear and noise, and extending service life.

Drawings

Other objects, advantages and novel features of the invention will become apparent from the following detailed description of the embodiments when considered in conjunction with the drawings.

Fig. 1 shows a schematic diagram of a base cutter gearbox assembly for a sugar cane harvester according to the present invention.

Figure 2 shows parts of a base cutter gearbox assembly for a sugar cane harvester according to the present invention.

Detailed Description

Before the present invention is explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of the components set forth in the following drawings. The invention is capable of other embodiments than those described and of being practiced or of being carried out in various ways. It is to be understood that the phraseology or terminology employed herein is for the purpose of description and not of limitation.

Harvesting is an important component of a sugar cane production system. Manual harvesting of sugar cane requires farmers to manually cut the cane stalks with large choppers or knives, so farmers who harvest sugar cane often feel tired after working for several hours and need to have frequent breaks. Manual harvesting of sugar cane can result in muscle and joint damage. Mechanical harvesters mitigate the laborious physical activity and hazards associated with manual harvesting. The cane harvester prepares a large amount of cane for production in a short time. Sugar cane harvesters are large agricultural machines used to harvest and partially treat sugar cane. Essentially a storage vessel with a mechanical extension device on a truck, the machine cuts the stalks at the root, strips the leaves, and then cuts the cane into segments. And then deposit them into on-board containers or individual vehicles traveling alongside. The waste material is then sprayed back into the field where it acts as a fertilizer.

A sugarcane combine harvester is provided with: a crop separator mechanism with a crop separator that helps move the sugarcane to the over-ride feed roller; a base cutter; a feed roll system; a cutting system; a cleaning device (i.e. a primary shaker) and a lift system comprising a secondary cleaning device (i.e. a secondary shaker). The present invention is particularly directed to an improved base cutter assembly.

Now, as shown in fig. 1, the base cutter assembly includes a base cutter, a helical gear box assembly connected to the base cutter, and a hydraulic motor for driving the helical gear box assembly. The base cutters include a pair of rotatable base cutters (7a, 7b) having protruding blades (8a, 8b) for cutting the cane stalks from their roots. The pair of rotatable base cutters (7a, 7b) are directly connected to the helical gearbox assembly by means of vertical shafts (6a, 6b) whereby the base cutters (7a, 7b) begin to rotate to harvest stalks at the roots, strip the leaves and then cut the cane into segments.

Referring now to fig. 1 and 2 in combination, the gearbox assembly comprises: main gears (1) and (4) having a plurality of serrations on the outer circumference; a pinion gear (2) having a plurality of teeth on the outer circumference thereof and engaged with the teeth of the main gear (1); an idler timing gear (3) which accommodates a spline coupler having a plurality of serrations on an outer periphery thereof and meshes with the serrations of the pinion gear (2) and the serrations of the main gear (4). The main gears (1, 4), pinions (2) and idler timing gears (3) have optimized helical angle teeth designed to hold and relieve the load on each tooth and create a smooth transition of forces from one tooth to the next, thereby reducing vibration, wear, noise and extending life. The tooth profile of the gear is very precise. These units are sealed packages. The oil filled housing does not require oil change. The base cutters (7a, 7b) are connected to the main gear (1, 4) by means of vertical shafts (6a, 6b), respectively. The pinion (2) is driven by a motor (5) through a spline connection to a shaft of the motor (5).

As shown, during operation, the input interacts with a splined connector configured to receive an output shaft of a hydraulic motor (5). The input interface is configured such that a rotational power is received at the interface with the aid of the hydraulic motor (5), by means of which rotational power the pinion (2) starts to rotate. The pinion (2) in turn rotates the main gear (1) and the idler timing gear (3), whereby the main gear (4) starts to rotate. The helical gearbox is positioned in the harvester throat above the base cutter (7a, 7 b). The base cutters (7a, 7b) are located between the front wheels of the harvester so that pitch of the harvester does not affect the cutting height when traversing uneven terrain. Rotation of the main gear (1, 4) in turn rotates the base cutters (7a, 7b) via the vertical shafts (6a, 6 b).

The invention has been described with respect to specific embodiments. It is to be understood that the above description is only illustrative of the present invention and is not intended to limit or restrict the present invention thereto. Many other specific embodiments of the invention will be apparent to those skilled in the art in light of the foregoing disclosure. All alternatives, modifications and variations of the present invention are readily acceptable within the scope of the appended claims without departing from the spirit of the invention. The scope of the invention should, therefore, be determined not with reference to the above description, but instead should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.