JP3671934B2 - Hydraulic equipment for powered vehicles - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hydraulic device for a power vehicle, and more particularly to a hydraulic device such as a front mower or a tractor having a hydraulic continuously variable transmission (HST).
[0002]
[Prior art]
Conventionally, in a power vehicle equipped with a hydraulic continuously variable transmission, a dedicated charge pump is provided in addition to the hydraulic pump and hydraulic motor constituting the hydraulic continuously variable transmission, and the charge oil from the charge pump is hydraulically supplied. This is supplied to a check valve in the continuously variable transmission.
[0003]
[Problems to be solved by the invention]
By the way, in the case of such a conventional device, there is a problem that the size of the entire unit of the hydraulic continuously variable transmission increases if there is a charge pump, and it is possible to accommodate the hydraulic continuously variable transmission in a mission case in a compact manner. In addition, there is a problem that the cost increases as the number of dedicated parts increases.
[0004]
[Means for Solving the Problems]
The present invention is proposed in order to solve the above problems, and the following technical means have been taken. That is, small-diameter rear wheels 3 and 3 that are steering wheels, large-diameter front wheels 2 and 2 that are driving wheels, an all-hydraulic steering device 5 that steers the rear wheels 3 and 3, and work on the front of the fuselage In a power vehicle provided with a hydraulic lifting device having a hydraulic cylinder 64 for moving the machine up and down and a hydraulic continuously variable transmission 26 for running the machine, the operation sent from the hydraulic pump 40 driven by the rotational power of the engine 12 A part of the oil is sent to the fully hydraulic steering device 5 through the diverter valve 55, and the remaining hydraulic oil is sent to the hydraulic valve 51. The discharged oil path 65 of the hydraulic valve 51 is adjusted in the amount of discharged oil. The adjustment tool 102 is provided so that when the hydraulic valve 51 is operated to the lower side, the hydraulic oil in the hydraulic cylinder 64 passes through the adjustment tool 102 provided in the discharge oil passage 65 and reaches the transmission case 27. Together with the above Connect the hydraulic oil of a hydraulic steering system 5 of the back side to the charge circuit 60 of the HST 26, the hydraulic fluid before being discharged from the hydraulic stepless transmission 26 in the transmission case 27 and the hydraulic valve An oil cooler 24 for cooling a hydraulic vehicle is provided on the vehicle body 28 so that an oil cooler 24 for cooling the hydraulic oil discharged from the engine 51 is provided on one side of the left and right sides of the machine body and its cooling surface is along the front-rear direction. The configuration is as follows.
[0005]
【Example】
Embodiments of the present invention will be described below based on the embodiments shown in the drawings. First, in terms of configuration, reference numeral 1 denotes a front-wheel drive type power vehicle that has large-diameter front wheels 2 and 2 and small-diameter rear wheels 3 and 3 and usually travels by driving only the front wheels 2 and 2. .
[0006]
The rear wheels 3 and 3 are steering wheels, and when the steering handle 4 is turned, hydraulic oil flows into and out of the cylinder chamber 6a of the hydraulic cylinder 6 by a fully hydraulic steering device 5 described later. 3 is steered. 7 is a steering post provided at the front part of the body, 8 is a seat, and 9 is a step, which are formed integrally with a fender 10 that covers the front wheels 2 and 2.
[0007]
An engine 12, a fan 13, a radiator 14, a fuel tank 15 and the like are provided at the rear of the fuselage, and a muffler 20 is attached to the right side of the engine 12 in the traveling direction, and an air cleaner is provided on the left side. NA 23 is provided. 21 is a tail pipe. An oil cooler 24 cools oil discharged from a hydrostatic continuously variable transmission 26, which will be described later, into a hydraulic oil tank (mission case 27). As shown in FIG. 1, the oil cooler 24 is on the right side of the machine body and is mounted on the vehicle body 28 so that its cooling surface is along the front-rear direction.
[0008]
The engine 12, the radiator 14, the fuel tank 15, the oil cooler 24, etc. are covered with a box-type bonnet 16, and a ventilation portion that allows ventilation is provided at the front, rear, and left and right sides of the bonnet 16. 16a, 16b,... Are provided. The outside air flowing in from the front vent 16a and the right vent cools the fuel tank 15 and the oil cooler 24. In addition, although a ventilation part may be comprised with a hollow iron plate, it is good also as a form which stretches a net-like body.
[0009]
A clutch housing 17 that houses a clutch is attached to the front of the engine 12, and a hydrostatic continuously variable transmission 26 (HST) is provided at the rear of the transmission. The hydrostatic continuously variable transmission 26 is housed in a mission case 27, and the output shaft of the hydrostatic continuously variable transmission 26 is connected to a mechanical transmission (not shown) so that the reduced rotational power can be transmitted. It is configured to be transmitted to the front wheels 2 and 2.
[0010]
Reference numeral 30 denotes a travel pedal for the continuously variable transmission 26, and reference numeral 32 denotes a master brake pedal. When the master brake pedal 32 is depressed, the left and right front wheels 2, 2 are braked simultaneously. Although not shown, a left and right independent turning pedal (not shown) and a clutch pedal (not shown) are provided on the left side of the steering post 7. Reference numeral 34 denotes a hydraulic operation lever, and 35 denotes an operation lever for auxiliary transmission.
[0011]
Next, the hydraulic circuit of FIGS. 3 and 4 will be described. A hydraulic pump 40 is driven by the rotational power of the engine 12 and feeds hydraulic oil toward the hydraulic valve 51 for raising and lowering the work implement and the rotary valve 52 of the all-hydraulic steering device 5. The hydraulic valve 51 for raising and lowering the work implement has three positions of “neutral”, “raised”, and “lowered”, and the oil passage is switched appropriately by the hydraulic operation lever 34. The rotary valve 52 of the all-hydraulic steering device 5 is incorporated in a steering unit 53 below the steering post 7. When the steering handle 4 is turned, the oil path is switched and the rear wheels 3 and 3 are steered. 55 is a diversion valve that sends part of the hydraulic oil discharged from the hydraulic pump 40 to the fully hydraulic steering device 5 via the oil passage 54 and sends the rest to the hydraulic valve 51 via the oil passage 57.
[0012]
In this embodiment, the diversion valve 55 sends 7 liters / minute to the fully hydraulic steering device 5 and 13 liters / minute to the hydraulic valve 51. Accordingly, when the hydraulic operation lever 34 is operated to the “raised” side, the hydraulic oil flows into the single-acting hydraulic cylinder 64 through the oil passages 57 and 62 sequentially, and lifts the mower deck 82 described later. On the contrary, when the hydraulic operation lever 34 is operated to the “down” side, the hydraulic oil discharged from the hydraulic cylinder 64 returns to the mission case 27 through the oil passage 65.
A check valve 66 is interposed in the middle of the discharge oil passage 65. When a predetermined pressure is reached, the check valve 66 is opened so that hydraulic oil is discharged from the hydraulic cylinder 64 to the mission case 27. It is composed. In this embodiment, the pressure is adjusted so as to open at a pressure of 5 kg / cm @ 2.
[0013]
During lawn mowing, the hydraulic valve 51 is switched to the lower side and used in a so-called free-float state. In this case, back pressure by the check valve 66 is always applied to the hydraulic cylinder 64. For this reason, the force of the direction which raises a working machine generate | occur | produces, the mower deck is lifted, and the load applied to the front wheel 2 is increased. That is, weight transfer for the front wheel 2 is performed here.
[0014]
58 and 59 are input / output shafts of the hydrostatic continuously variable transmission 26, and power is transmitted from the output shaft 59 to a mechanical transmission (not shown). Reference numeral 68 denotes an oil passage for supplying oil to the charge circuit 60 of the continuously variable transmission 26 and is connected to the discharge-side oil passage 69 of the fully hydraulic steering device 5. Reference numerals 70 and 71 denote filters. The oil cooler 24 is provided in the middle of the discharge-side oil passage of the hydrostatic continuously variable transmission 26, as shown in FIGS.
[0015]
In the drawing, reference numeral 74 denotes an external hydraulic pressure take-out unit. In this embodiment, two series of hydraulic pressure take-out portions are provided. After connecting pipes (not shown) to the respective connection ports 75 and 75, the operation levers 76 and 76 are connected. The external device can be controlled by operating the. Next, a mower as a mowing device mounted on the front of the machine body and its suspension mechanism will be briefly described.
[0016]
First links 78 and 78 that move left and right simultaneously are pivotally supported at the front portion of the mission case 27, and second links 80 and 80 are detachably inserted into the distal ends of the first links 78 and 78, respectively. Each of the links 80 and 80 is pivotally supported by a pin 79 so that it can swing up and down within a certain range. A mower deck 82 that covers the outer periphery of the three cutting blades 81 is attached to the tips of the second links 80, 80, and the rear portion of the mower deck 82 is a hanging tool 87 including a rod 84, a retaining pin 85, and a collar 86. It is suspended by. The suspending tool 87 restricts the descent of the mower deck 82 beyond a certain level, and allows the mower deck 82 to move upward. Therefore, when the mower deck 82 receives an upward force during the operation, the mower deck 82 can be retracted upward.
[0017]
88 is a gage wheel, 89 is a tail wheel attached to the rear part of the mower deck 82, and 90 is a gear case. The input shaft 92 of the gear case 90 and the PTO shaft 95 projecting forward from the front of the mission case 27 are interlocked and connected via a universal joint 98. When the PTO shaft 95 rotates, the mower deck is rotated. The three cutting blades 81 that are pivotally supported in the left and right lateral directions in the left and right directions are configured to be driven to rotate clockwise as viewed from the plane.
[0018]
The mower deck 82 is provided with a grass outlet 100 for discharging grass and turf that is cut out in the left and right lateral direction (right side in the embodiment), and this grass outlet 100 is used for collector work other than mowing work. A shutter (not shown) is connected to the hood 16 so that the grass and grass cut by the collector placed above the hood 16 are collected.
[0019]
Next, the operation of the above example will be described. When the rotational power of the engine 12 is transmitted to each rotating part and the aircraft is advanced, the turf and grass are cut by the rotating cutting blade 81, and the grass in the mower deck 82 passes through the grass discharge passage 101 to the right side of the mower deck 82. Are discharged from the outlet 100.
[0020]
During the operation, the front portion of the mower deck 82 is supported by a gage wheel 88, the rear side of the mower deck 82 is supported in a state slightly separated from the ground, and the lower surface of the mower deck 82 is substantially parallel to the ground. It is supported. When working, when the force that the one side in the left-right direction of the mower deck 82 moves upward from the ground due to the unevenness of the ground is received from the ground, the rod 84 of the hanging tool 87 moves upward, and the mower deck 82 is retracted upward. During lawn mowing, the hydraulic valve 51 is switched to the lower side and used in a free-floating state. A check valve 66 is provided in the middle of the discharge-side oil passage 65 of the hydraulic valve 51. Therefore, back pressure is always applied to the hydraulic cylinder-64. For this reason, a force in the direction of lifting the mower deck 82 acts on the mower deck 82, and the heavy mower deck 82 does not act strongly on the turf or the ground. There is no danger of hurting the lawn.
[0021]
In the above-described embodiment, the back pressure is applied to the hydraulic cylinder 64 by the check valve 66. However, instead of the check valve 66, a variable orifice 102 may be provided as shown in FIG. That is, when the weight of the mower deck 82 connected to the front portion of the power vehicle 1 is heavy, the back pressure is increased by narrowing the variable orifice 102, and conversely, when a work machine with a light weight is attached, the back pressure is increased. Set it to a small one so that the work equipment can easily descend. In any case, it is possible to reduce the lifting load of the work machine to enable weight transfer with respect to the front wheel 2, and to reduce the slip of the front wheel 2 on an inclined ground or the like.
[0022]
Next, the configuration of FIG. 6 will be described. The oil cooler 24 described in the previous embodiment is provided on the discharge oil path side of the hydraulic continuously variable transmission 26 to cool only a part of the return oil. That is, of the 20 liters / minute of operating pressure oil discharged from the hydraulic pump 40, 7 liters / minute of operating pressure oil divided by the diverter valve 55 is sent to the fully hydraulic steering device 5, and the return oil is hydraulically supplied. The hydraulic oil sent to the charge circuit 60 of the hydraulic continuously variable transmission 26 and discharged from the hydraulic continuously variable transmission 26 is cooled by the oil cooler 24.
[0023]
In such a conventional apparatus, only the hydraulic oil of 7 liters / minute is cooled, so that the heat balance of the hydraulic system is bad and various problems occur. Therefore, the improved device shown in FIG. 6 is intended to cool the hydraulic oil discharged from the hydraulic valve 51 of the hydraulic lifting system in order to improve the heat balance.
[0024]
Specifically, the hydraulic oil immediately before being discharged from the hydraulic valve 51 into the mission case 27 is merged with the hydraulic oil discharged from the hydrostatic continuously variable transmission 26 side and flows into the oil cooler 24. I am doing so. At this time, a check valve 104 is interposed in order to prevent a large back pressure from being applied to the hydrostatic continuously variable transmission 26 side.
[0025]
FIG. 7 shows a modification of a part of the hydraulic circuit in order to prevent the lowering speed of the work implement from being lowered due to an increase in the charge pressure of the hydrostatic continuously variable transmission 26. The device shown in this figure is such that the return oil of the hydraulic valve 51 and the return oil of the fully hydraulic steering device 5 are merged and fed into the charge circuit 60 of the hydrostatic continuously variable transmission 26. However, in such a device, when the rotational speed of the engine 12 is increased and the discharge amount of the hydraulic pump 40 is increased, the charge pressure is increased. As a result, the pressure is increased by the hydraulic valve 51 or the all hydraulic type. There is a problem in that the descent speed of the work implement becomes slow due to the steering device 5. In particular, when the weight of the work machine is light, there also arises a problem that the work machine is not lowered at all. In view of this, in this apparatus, a bypass circuit 105 connected to the oil cooler 24 by branching in the middle of the oil passage that enters the hydrostatic continuously variable transmission 26 is provided. A bypass valve 106 whose pressure is set slightly higher than the set pressure of the check valve 103 is provided. By providing such a bypass circuit 105 and bypass valve 106, it is possible to suppress the occurrence of excessive charge pressure and maintain the charge pressure substantially constant to maintain the stability of the lifting operation of the work implement. It can be done.
[0026]
Finally, the layout of the oil cooler 24 shown in FIG. 8 will be described. All of the oil coolers 24 described so far are provided on the hydraulic oil discharge side of the hydrostatic continuously variable transmission 26. However, the above-described devices have no hydrostatic pressure due to the pressure loss of the oil cooler 24. A slight pressure is generated on the hydraulic oil discharge side of the step transmission 26, which may damage the seal in the hydrostatic continuously variable transmission 26 and damage the equipment.
[0027]
The oil cooler 24 of the apparatus described here is provided not on the hydraulic oil discharge side of the hydrostatic continuously variable transmission 26 but on the hydraulic oil discharge side of the hydraulic valve 51. If the oil cooler 24 is formed in the discharge side oil passage of the hydraulic valve 51, the hydrostatic continuously variable transmission 26 is not affected by the back pressure on the oil cooler 24 side, and the hydraulic continuously variable transmission 26 There is no risk of damaging the seal member.
[0028]
【The invention's effect】
The present invention includes small-diameter rear wheels 3 and 3 that are steering wheels, large-diameter front wheels 2 and 2 that are drive wheels, an all-hydraulic steering device 5 that steers the rear wheels 3 and 3, In a power vehicle equipped with a hydraulic lifting device having a hydraulic cylinder 64 that lifts and lowers the working machine and a hydraulic continuously variable transmission 26 that drives the machine body, the hydraulic pump 40 driven by the rotational power of the engine 12 is sent out. The hydraulic fluid is partly sent to the fully hydraulic steering device 5 through the diverter valve 55, and the remaining hydraulic fluid is sent to the hydraulic valve 51. The discharged oil passage 65 of the hydraulic valve 51 has an amount of discharged oil. Is provided so that when the hydraulic valve 51 is operated to the lower side, the hydraulic oil in the hydraulic cylinder 64 passes through the adjustment tool 102 provided in the discharge oil passage 65 and reaches the transmission case 27. With composition Connect the hydraulic oil of the whole hydraulic steering system 5 of the back side to the charge circuit 60 of the HST 26, the hydraulic oil before being discharged from the hydraulic stepless transmission 26 in the transmission case 27 Since the oil cooler 24 that cools together the hydraulic oil discharged from the hydraulic valve 51 is provided on the vehicle body 28 on the left and right sides of the fuselage and the cooling surface thereof is along the front-rear direction, the hydraulic oil is supplied to the oil cooler 24. It will cool well and will not cause device malfunction or malfunction. In particular, in the present invention, the hydraulic valve 51 is switched to the lower side when performing lawn mowing work. However, since back pressure is applied to the lifting hydraulic cylinder 64, the temperature of the hydraulic oil tends to increase. However, since the hydraulic oil is appropriately cooled by the oil cooler 24, it does not hinder long-time work. In addition, a back pressure of a predetermined pressure applied to the hydraulic cylinder 64 is applied to the hydraulic cylinder 64 at the time of work, and a force in a direction to lift the work machine works. Thus, the conventionally used spring such as a balance spring may be eliminated. As a result, the structure is simplified, and the operability is improved by eliminating the troublesome operation of attaching / detaching the balance spring when the mower deck is attached / detached. Moreover, since the oil cooler 24 has a cooling surface along the front-rear direction on the left and right sides of the machine body, maintenance and inspection are easy.
[Brief description of the drawings]
FIG. 1 is an overall side view of a riding lawn mower.
FIG. 2 is a perspective view of a main part.
FIG. 3 is a hydraulic circuit diagram.
FIG. 4 is a hydraulic circuit diagram.
FIG. 5 is a hydraulic circuit diagram of a main part.
FIG. 6 is a hydraulic circuit diagram.
FIG. 7 is a hydraulic circuit diagram.
FIG. 8 is a hydraulic circuit diagram.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Power vehicle 2 Front wheel 3 Rear wheel 4 Steering handle 5 Full hydraulic steering device 12 Engine 14 Radiator 15 Fuel tank 16 Bonnet 24 Oil cooler 26 Hydraulic continuously variable transmission 27 Mission case 34 Hydraulic operation lever
35 Operation lever for sub-shift
51 Hydraulic valve 60 Charge circuit 64 Hydraulic cylinder
66 Check valve

Claims (1)

Small-diameter rear wheels 3 and 3 that are steering wheels, large-diameter front wheels 2 and 2 that are driving wheels, an all-hydraulic steering device 5 that steers the rear wheels 3 and 3, and a work machine at the front of the fuselage In a powered vehicle having a hydraulic lifting device having a hydraulic cylinder 64 that moves up and down and a hydraulic continuously variable transmission 26 that travels the machine body, hydraulic fluid fed from a hydraulic pump 40 driven by the rotational power of the engine 12 is supplied. A part is sent to the fully hydraulic steering device 5 via the diverter valve 55, and the remaining hydraulic oil is sent to the hydraulic valve 51, and an adjustment is made to adjust the amount of oil discharged to the oil discharge passage 65 of the hydraulic valve 51. The tool 102 is provided, and when the hydraulic valve 51 is operated to the lower side, the hydraulic oil in the hydraulic cylinder 64 passes through the adjuster 102 provided in the discharge oil passage 65 and reaches the mission case 27. Total hydraulic pressure Connect the hydraulic oil of the steering device 5 of the back side to the charge circuit 60 of the HST 26, the hydraulic oil and the hydraulic valve 51 before being discharged from the hydraulic stepless transmission 26 in the transmission case 27 1. A hydraulic apparatus for a power vehicle, wherein an oil cooler 24 for cooling the discharged hydraulic oil is provided on a vehicle body 28 on one side of the left and right sides of the machine body so that a cooling surface thereof is along the front-rear direction .

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