KR20190090483A - Agricultural working machine including flow distribution system - Google Patents

Abstract

The present invention relates to an agricultural working vehicle having a flow rate distribution system, and more specifically, to an agricultural working vehicle having a flow rate distribution system, which is able to, in a hydraulic system in which a plurality of valves are serially connected to successively supply a working fluid, have a branch structure, which branches a part of a flow rate supplied to a front end valve among the plurality of valves, and supplies it to a rear end valve placed on the rear end of the front end valve, and to simultaneously drive a plurality of hydraulic apparatuses, which operate by receiving the working fluid from the front end valve and the rear end valve. According to the present invention, the agricultural working vehicle (1) having the flow rate distribution system (100) comprises: an oil pump (110) which receives power from an engine to generate a flow of the working fluid; a plurality of valves (120) which transfer the working fluid supplied from the oil pump (110) to a hydraulic apparatus; and a flow rate branch unit (130) which branches a partial flow rate from the working fluid supplied to a front end valve (120a) among the plurality of valves (120) to supply it to a rear end valve (120b) by detouring the front end valve (120a).

Description

AGRICULTURAL WORKING MACHINE INCLUDING FLOW DISTRIBUTION SYSTEM}

The present invention relates to an agricultural work vehicle equipped with a flow distribution system, and more particularly, branching a portion of the flow rate supplied to the front end valve of the plurality of valves in a hydraulic system in which a plurality of valves are connected in series to supply hydraulic oil sequentially. And a branch structure for supplying to a rear end valve positioned at a rear end of the front end valve so that a flow distribution system capable of simultaneously driving a plurality of hydraulic devices operated by receiving hydraulic oil from the front end valve and the rear end valve is provided. It is about agricultural work vehicle.

In a conventional agricultural work vehicle 1 such as a tractor, as shown in FIG. 1, various operations such as steering control (10 in FIG. 1) and lifting / lowering control of a work machine (20 in FIG. 1) are performed using a hydraulic system. In addition, the hydraulic pressure may be transmitted to the work machine for driving the attached work machine.

In this case, in the agricultural work vehicle 1 such as a tractor can be configured a hydraulic system with a single pump, using a lot of open center system (open center system) method that can simplify the structure. More specifically, FIG. 2A illustrates a hydraulic system of an open center system type according to the prior art. As can be seen in Figure 2a, conventionally a plurality of valves connected in series using one oil pump 30 (for example, the front loader valve 40, the auxiliary control valve 50, the lift control of Figure 2a) Valve 60) to be supplied with the operating oil sequentially. However, in this case, when the hydraulic fluid is used in the valve located at the front end, the hydraulic fluid connected to the valve at the rear end may be difficult to operate because the hydraulic fluid is not supplied to the valve located at the rear end (for example, FIG. If hydraulic fluid is used in the auxiliary control valve 50 in 2a, the hydraulic device cannot be driven in the lift control valve 60).

More specifically, in FIG. 2A, when the oil pump 30 supplies a flow rate of 60 Litter per minute (LPM), the front loader valve 40 uses all of the flow rates of 60 LPM for driving the front loader. In the auxiliary control valve 50 and the lift control valve 60 can not be provided with the flow rate required for the operation, it is impossible to perform the driving and lifting operation of the work machine.

Furthermore, in the hydraulic system according to the prior art, there is a problem that it is difficult to perform a task in which a plurality of hydraulic devices are to be driven at the same time. More specifically, for example, when a worker removes the front loader and mounts a work machine at the rear of the farm work vehicle 1 and then simultaneously lifts and lowers the work machine while driving the work machine (for example, tongs on a tractor) In the case of lifting and holding the workpiece, the flow rate must be supplied to the lift control valve 60 to elevate the work machine while supplying the flow rate to the auxiliary control valve 50 to drive the work machine. However, in this case, while the auxiliary control valve 50 consumes all or a substantial amount of the flow rate of 60LPM supplied from the oil pump 30, the lift control valve 60 supplies a flow rate for lifting the work machine. The problem may arise that it is difficult to lift the work machine while driving the work machine.

On the other hand, as can be seen in Figure 2b, it is also possible to consider a structure in which some valves are connected in parallel to drive a hydraulic device connected to a plurality of valves at the same time, in this case the load (or pressure) at each valve As the flow rate supplied to each valve changes from time to time, there may be a problem that the driving speed of the hydraulic device attached to each valve is not controlled constantly (for example, the auxiliary control valve 50 and the lift control in FIG. 2B). When the valve 60 is connected in parallel, the driving speed of the hydraulic device connected to the auxiliary control valve 50 and the lift control valve 60 operates unevenly).

Accordingly, in the hydraulic system of the agricultural work vehicle 1 such as a tractor, even when the hydraulic oil is used in the valve at the front end, it is possible to drive the device by receiving the hydraulic oil from the valve at the rear end. Even if it is desirable to be able to constantly adjust the flow rate supplied to each valve, it is not yet proposed a proper solution to this problem.

Republic of Korea Utility Model Registration No. 20-0349206 (2004.04.21)

The present invention has been made to solve the above problems, even when using the hydraulic fluid in the valve of the front in the hydraulic system of the agricultural work vehicle, such as a tractor can receive a hydraulic oil from the valve of the rear end to drive a plurality of hydraulic devices at the same time It is aimed at providing agricultural work vehicles.

Furthermore, an object of the present invention is to provide an agricultural work vehicle that can constantly adjust the flow rate supplied to each valve even when the hydraulic oil is supplied to a plurality of valves in the hydraulic system of the agricultural work vehicle such as a tractor.

Other objects and advantages of the present invention will become apparent to those skilled in the art from the following detailed description.

In order to solve the above problems, the agricultural work vehicle 1 according to an embodiment of the present invention, the oil pump 110 for generating a flow of operating oil by receiving power from the engine; A plurality of valves 120 for delivering hydraulic oil supplied from the oil pump 110 to a hydraulic device; And a flow rate branch unit 130 which diverges a part of the flow rate from the working oil supplied to the front end valve 120a of the plurality of valves 120, bypasses the front end valve 120a and supplies it to the rear end valve 120b. Characterized in that.

Here, the plurality of valves 120 are connected in series, the hydraulic oil may be sequentially supplied from the front valve 120a to the rear valve 120b.

In this case, the flow rate branch unit 130 may branch a predetermined flow rate set from the hydraulic oil supplied to the front end valve 120a and supply it to the rear end valve 120b.

In addition, the flow rate branch unit 130 may be provided with a flow rate setting device 132 that allows the operator to set the flow rate branched from the hydraulic oil supplied to the front end valve (120a).

Further, the flow rate setting device 132 may control whether or not to supply a partial flow rate to the rear end valve 120b by branching the hydraulic fluid supplied to the front end valve 120a according to the operator's setting. .

At this time, the front valve 120a is any one of the auxiliary control valve 50 for providing hydraulic pressure to the work machine and the lift control valve 60 for providing the hydraulic pressure for lifting the work machine, the rear end valve 120b is It may be another one of the auxiliary control valve 50 for providing the hydraulic pressure to the work machine and the lift control valve 60 for providing the hydraulic pressure for lifting the work machine.

According to the present invention, the following effects can be achieved.

First, in an agricultural work vehicle having a flow rate distribution system according to an embodiment of the present invention, even when hydraulic oil is used in a front end valve among a plurality of valves, a part of the flow rate supplied to the front end valve branches to the front end valve. By supplying to the rear end valve located at the rear end of the, there is an effect that the hydraulic oil can be driven from the front end valve as well as the rear end valve and simultaneously drive a plurality of hydraulic devices.

Further, in the agricultural work vehicle having a flow distribution system according to an embodiment of the present invention, even when the operating oil is supplied to a plurality of valves at the same time, by adjusting the flow rate supplied to each valve, it is connected to the plurality of valves It is possible to constantly control the driving speed of each hydraulic device.

1 is an illustration of an agricultural work vehicle 1 equipped with a conventional hydraulic system.
2A and 2B are diagrams for explaining a hydraulic system in a conventional agricultural work vehicle 1.
3A and 3B are block diagrams of a flow distribution system 100 according to an embodiment of the present invention.
4 and 5 are views illustrating the operation of the flow distribution system 100 according to an embodiment of the present invention.
6 is a perspective view of the flow distribution system 100 provided in the agricultural work vehicle 1 according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments will be described in detail below with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terms first, second, etc. may be used to describe various components, but the components are not limited by the terms, and the terms are used only for the purpose of distinguishing one component from another Is used.

Hereinafter, exemplary embodiments of the agricultural work vehicle 1 equipped with the flow distribution system 100 according to the present invention will be described in detail with reference to the accompanying drawings.

First, FIG. 3A illustrates a block diagram of a flow distribution system 100 provided in an agricultural work vehicle 1 such as a tractor according to an embodiment of the present invention. As can be seen in Figure 3a, the flow distribution system 100 according to an embodiment of the present invention, from the oil pump 110, the oil pump 110 to generate a flow of working oil by receiving power from the engine A plurality of valves 120 for delivering the supplied hydraulic oil to the hydraulic device and a part of the flow rate from the hydraulic oil supplied to the front end valve 120a of the plurality of valves 120 diverge the front end valve 120a to bypass the rear end valve. It may be configured to include a flow branch 130 for supplying to (120b). In this case, the plurality of valves 120 may be connected in series so that the hydraulic oil may be sequentially supplied from the front valve 120a to the rear valve 120b.

Therefore, the flow distribution system 100 of the agricultural work vehicle 1, such as a tractor according to the present invention, even when the hydraulic fluid is used in the front end valve 120a of the plurality of valves 120, the hydraulic fluid is also supplied to the rear end valve 120b. In addition to being able to drive a plurality of hydraulic devices at the same time, and even in the case of supplying hydraulic fluid to the plurality of valves 120 at the same time in the flow distribution system 100 of the agricultural work vehicle 1, such as a tractor, each valve 120 By constantly adjusting the flow rate supplied to the), it is possible to constantly control the driving speed of each hydraulic device connected to the plurality of valves (120).

Hereinafter, the flow distribution system 100 according to an embodiment of the present invention will be divided in detail for each component to examine in more detail.

First, in the flow distribution system 100 of the agricultural work vehicle 1 according to an embodiment of the present invention, the oil pump 110 supplies the working oil to the plurality of valves 120, the plurality of valves 120 It will drive the hydraulic device connected to).

In this case, the oil pump 110 may be applied without particular limitation as long as it is an oil pump 110 capable of appropriately supplying a predetermined flow rate of working oil to the plurality of valves 120.

Subsequently, a plurality of valves 120 are provided in the flow distribution system 100 according to the embodiment of the present invention. At this time, the plurality of valves 120 to deliver the hydraulic oil supplied from the oil pump 110 to each hydraulic device connected to the plurality of valves 120, in particular the plurality of valves 120 is connected in series The hydraulic oil supplied from the oil pump 110 may be sequentially supplied from the front valve 120a to the rear valve 120b.

Furthermore, the flow rate distribution system 100 according to an embodiment of the present invention diverts a portion of the flow rate from the hydraulic oil supplied to the front end valve 120a and bypasses the front end valve 120a to supply the rear end valve 120b. It may include a branch 130.

Therefore, the hydraulic system of the agricultural work vehicle 1, such as a tractor according to the present invention, even when the hydraulic fluid is used in the front valve 120a of the plurality of valves 120, the hydraulic fluid is supplied from the rear valve 120b. In addition to driving the hydraulic device at the same time, even when the hydraulic fluid is supplied to the plurality of valves 120 at the same time in the flow distribution system 100 of the agricultural work vehicle 1 such as a tractor is supplied to each valve 120 By constantly adjusting the flow rate, it is possible to constantly control the driving speed of each hydraulic device connected to the plurality of valves (120).

For example, in the agricultural work vehicle 1 having the flow distribution system 100 according to an embodiment of the present invention, as shown in FIG. 4, a rear end valve of the plurality of valves 120 is provided. A part of the flow rate is diverted from the hydraulic oil supplied to the front end valve 120a (the auxiliary control valve) positioned at the front end of the lift control valve, thereby bypassing the front end valve 120a and the auxiliary control valve. By providing the flow rate branch unit 130 to the lift control valve), even when the hydraulic fluid is used in the front end valve 120a (the auxiliary control valve) of the plurality of valves 120, the front end valve 120a, the auxiliary control valve By branching a part of the flow rate supplied to) and supplying to the rear end valve (120b, lift control valve), the hydraulic fluid is also supplied from the rear end valve (120b, lift control valve) it is possible to drive a plurality of hydraulic devices at the same time. .

In this case, the flow rate branch unit 130 may be configured by using a throttle valve, etc. In addition, the flow rate branch unit 130 branches the flow rate from the hydraulic oil supplied to the front end valve 120a (auxiliary control valve). If the structure can be supplied to the rear end valve (120b, lift control valve) by bypassing the 120a, the auxiliary control valve) can be applied to the present invention without particular limitation.

In addition, the flow rate branch unit 130 may branch a predetermined flow rate set from the hydraulic oil supplied to the front end valve 120a (the auxiliary control valve) and supply it to the rear end valve 120b (the lift control valve).

Accordingly, in the flow distribution system 100 according to an embodiment of the present invention, when the hydraulic oil is simultaneously supplied to the plurality of valves 120 (for example, the front end valve 120a and the auxiliary control valve in FIG. 4) and Even when the hydraulic fluid is supplied to the rear valve 120b (lift control valve) at the same time, the flow rate is uniformly supplied to each valve 120 according to the set flow rate, so that each valve is changed in accordance with the load variation in each valve 120. It is possible to suppress the driving speed deviation of the hydraulic device which may appear while the flow rate supplied to the 120 is changed, and to constantly control the driving speed of the plurality of hydraulic devices operating by receiving hydraulic oil from the plurality of valves 120. Will be.

In addition, the flow rate branch unit 130 may be configured to include a flow rate setting device (132, shown in Figure 6) that allows the operator to set the flow rate branched from the hydraulic oil supplied to the front end valve (120a, auxiliary control valve). Can be. Further, the flow rate setting device 132, according to the operator's setting whether to branch off some of the flow from the hydraulic fluid supplied to the front valve (120a, auxiliary control valve) to supply to the rear end valve (120b, lift control valve). It is also possible to control whether or not (i.e., to set the flow rate to be branched or to set whether or not the flow rate is branched).

Accordingly, the operator sets the flow rate setting device 132 according to the work to be performed by him, and supplies the flow rate and the rear end valve 120b (lift control valve) supplied to the front valve (120a, auxiliary control valve). The flow rate may be adjusted, or further, the entire flow rate may be adjusted to be supplied to the front end valve 120a.

Furthermore, in the flow distribution system 100 according to an embodiment of the present invention, the flow branch 130 is connected to the front valve (120a, auxiliary control valve) and the rear valve (120b, lift control valve). It is also possible to branch the flow rate so that each hydraulic device being driven can be driven.

For example, as shown in Figure 5, the total flow rate of the hydraulic fluid supplied from the oil pump 110 via the front loader valve is 60LPM, the hydraulic device connected to the front valve (120a, auxiliary control valve) In order to drive a flow rate of at least 10LPM, and a flow rate of at least 40LPM is required to drive a hydraulic device connected to the rear end valve (120b, lift control valve), the flow branch 130 is in the operator's setting Accordingly, by adjusting the flow rate supplied to the front end valve 120a (subsidiary control valve) from 10 to 20 LPM, and the flow rate supplied to the rear end valve 120b (lift control valve) within the range of 40 to 50 LPM, the front end valve 120a, Auxiliary control valve) and the hydraulic pressure connected to the rear valve (120b, lift control valve) can be distributed so that the flow can be driven at the same time.

That is, as can be seen in the hydraulic system of Figure 2a according to the prior art, in the agricultural work vehicle 1, such as a tractor to provide a hydraulic pressure for the auxiliary control valve 50 for providing hydraulic pressure to the work machine and the work machine lifting and lowering When it is necessary to simultaneously supply hydraulic fluid to the lift control valve 60 to perform the lifting and lowering operation of the work machine together with the driving of the work machine, while it is difficult to perform this in the conventional hydraulic system, the flow rate according to an embodiment of the present invention. In the distribution system 100, as shown in FIG. 4, the auxiliary control valve 50 and the lift control valve 60 are configured as the front valve 120a and the rear valve 120b, respectively. By appropriately adjusting the flow rate supplied to the lift control valve 60 and driving the work machine mounted on the agricultural work vehicle 1 such as the tractor and the like as well as lifting and lowering the work machine. Can be carried out (eg when lifting the workpiece while holding the workpiece with the tongs in the tractor).

In addition, the auxiliary control valve 50 and the lift control valve (above) using the auxiliary control valve 50 as the front valve 120a and the lift control valve 60 as the rear valve 120b. Although the case of simultaneously supplying the hydraulic oil to 60) has been described, the present invention is not limited thereto, and the present invention is not limited to the auxiliary control valve 50 and the lift control valve 60, but also in the case of various types of valves 120. It can be widely applied.

For example, when the front loader valve 40 of FIG. 2A is applied as the front valve 120a and the auxiliary control valve 50 of FIG. 2A is used as the rear valve 120b, the front loader valve 40 and By dividing and supplying the flow rate to the auxiliary control valve 50, it is also possible to simultaneously drive the work loader attached to the front loader and the rear three-point link of the agricultural work vehicle 1 such as a tractor.

Furthermore, as can be seen in Figure 3b, in the flow distribution system 100 according to an embodiment of the present invention is provided with a plurality of rear end valves (120b) that can be supplied with the operating oil supplied bypassing the front valve (120a) May be Accordingly, together with the hydraulic device connected to the front valve 120a (ie, N valve 120a in FIG. 3B), the plurality of rear valves 120b (ie, N + 1 valve 120b1 in FIG. 3B). In addition, hydraulic pressure may be supplied to each hydraulic device connected to the N + 2 valve 120b2) to be driven simultaneously.

In addition, referring to Figure 3b, in the flow distribution system 100 according to an embodiment of the present invention, the flow branch section 130 is the front end of the front end valve 120a (that is, the N valve 120a in Figure 3b) It is not necessary to supply the flow rate branched at to the immediately following rear valve 120b (ie, the N + 1 valve 120b1 in FIG. 3b), and in some cases the subsequent rear valve 120b (for example, 3B may be supplied to the N + 2 valve 120b2).

That is, the flow distribution unit 130 in the flow distribution system 100 according to an embodiment of the present invention is one or more of the rear end valve 120b set by the flow rate setting device 132 of the plurality of rear valves (120b). The flow rate set by the flow rate setting device 132 can be branched and supplied at the same time.

Accordingly, in the flow distribution system 100 according to an embodiment of the present invention, by flexibly adjusting the flow rates supplied to the valves 120 according to the work to be performed, the flow rate distribution corresponding to a wide variety of working environments is more limited. It can be efficiently distributed and performed.

Furthermore, the flow distribution system 100 according to an embodiment of the present invention is provided at the rear of the agricultural work vehicle 1 on which the work machine is mounted, and the auxiliary control valve 50 providing the hydraulic pressure to the work machine includes a shear valve ( 120a), and the lift control valve 60 to provide a hydraulic pressure for the lifting and lowering of the work machine may be configured by applying the rear end valve (120b).

For example, FIG. 6 illustrates a flow distribution system 100 provided at the rear of the agricultural work vehicle 1 according to the exemplary embodiment of the present invention.

First, Figure 6 (a) illustrates a conventional flow distribution system 100 provided in the rear of a conventional agricultural work vehicle (1), the hydraulic oil is input to the hydraulic device such as a working machine through a plurality of valves 120 Will be supplied.

In contrast, Figure 6 (b) illustrates a flow distribution system 100 according to an embodiment of the present invention. As can be seen in Figure 6 (b), the flow distribution system 100 according to an embodiment of the present invention is provided with a flow rate setting device 132, such as a flow rate setting dial, the operator is supplied to the front end valve (120a) It is possible to set the flow rate is branched from the operating oil to be supplied to the rear end valve (120b), and further branched flow rate from the hydraulic oil supplied to the front end valve (120a) according to the setting of the operator to supply to the rear end valve (120b) You can also set whether or not.

Accordingly, the operator performs the operation of setting the flow rate setting device 132 at the same time as performing the cable connection work for supplying the working oil to the work machine at the same place, such as the rear of the agricultural work vehicle (1), thereby conveniently driving the work machine You can proceed with the settings.

In particular, as can be seen in comparison with Figure 6 (a) and Figure 6 (b), the flow distribution system 100 according to an embodiment of the present invention is a partial flow rate from the hydraulic fluid supplied to the front end valve (120a) A structure for branching and applying the branched flow rate to the front end of the rear end valve 120b and a flow rate setting for setting a flow rate branched from the hydraulic oil supplied to the front end valve 120a and supplied to the rear end valve 120b Device 132 may be added. Accordingly, when driving a plurality of hydraulic devices, even if the hydraulic fluid is used in the front end valve 120a of the plurality of valves, a part of the flow rate supplied to the front end valve 120a is branched and positioned at the rear end of the front end valve 120a. By supplying to the rear end valve 120b, the hydraulic oil can be supplied from not only the front valve 120a but also the rear end valve 120b to simultaneously drive a plurality of hydraulic devices.

Furthermore, in the flow distribution system 100 according to an embodiment of the present invention, even when the hydraulic oil is simultaneously supplied to the plurality of valves 120, the driving speed of the plurality of hydraulic devices is controlled by constantly adjusting the flow rate supplied to each valve. Can be controlled constantly.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments described in the present invention are not intended to limit the technical spirit of the present invention but to illustrate the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

1: Agricultural work vehicle 10: Steering device
20: lifting device 30: oil pump
40: front loader valve 50: auxiliary control valve
60: lift control valve 70: oil tank
100: flow distribution system 110: oil pump
120: valve 120a: shear valve
120b: rear end valve 130: flow control unit
132: flow rate setting device 140: oil tank

Claims (6)

Oil pump 110 for receiving the power from the engine to generate a flow of working oil;
A plurality of valves 120 for delivering hydraulic oil supplied from the oil pump 110 to a hydraulic device; And
A flow branch (130) for branching a part of the flow rate from the hydraulic oil supplied to the front end valve (120a) of the plurality of valves (120) to bypass the front end valve (120a) and to supply the rear end valve (120b);
Agricultural work vehicle (1) having a flow distribution system 100, characterized in that it comprises a. The method of claim 1,
The plurality of valves (120) are connected in series, the agricultural work vehicle having a flow rate distribution system (100), characterized in that the operating oil is sequentially supplied from the front end valve (120a) to the rear end valve (120b). The method of claim 1,
The flow rate branch unit 130,
The agricultural work vehicle (1) having a flow rate distribution system (100) characterized in that for supplying to the rear end valve 120b by branching a predetermined flow rate set from the hydraulic oil supplied to the front end valve (120a). The method of claim 1,
The flow rate branch unit 130,
An agricultural work vehicle (1) having a flow rate distribution system (100), characterized in that the worker has a flow rate setting device (132) for setting a flow rate branched from the hydraulic oil supplied to the front end valve (120a). 5. The method of claim 4,
The flow rate setting device 132,
According to the setting of the operator having a flow rate distribution system 100 characterized in that it is possible to control whether or not to supply a partial flow rate from the hydraulic fluid supplied to the front end valve (120a) to supply to the rear end valve (120b) Agricultural work vehicle (1). The method of claim 1,
The front end valve 120a is any one of an auxiliary control valve 50 for providing hydraulic pressure to a work machine and a lift control valve 60 for providing hydraulic pressure for lifting and lowering the work machine.
The rear end valve 120b is another one of the auxiliary control valve 50 for providing hydraulic pressure to a work machine and the lift control valve 60 for providing hydraulic pressure for lifting and lowering the work machine. .

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