KR101203806B1 - Drive unit for a mobile vehicle - Google Patents

Abstract

The present invention relates to a mobile vehicle driver having a first hydraulic motor (9) and a second hydraulic motor (10), which are permanently connected by means of assembly gears (12, 14) and drive an output shaft (17). Let's do it. The first hydraulic motor 9 is adjusted to stroke volume 0 to be hydraulically separated from the high pressure so that the first hydraulic motor 9 can be operated at more than its maximum allowable rotational speed.

Hydraulic motor, stroke volume, high pressure line, reduction gear parts, spur gear

Description

DRIVE UNIT FOR A MOBILE VEHICLE}

The invention relates to a driver for a mobile vehicle according to the type defined in the preamble of claim 1.

Common drivers are especially used for driving mobile vehicles, for example working machines, wheel loaders. The wheel loader requires high tension and a final speed of 40 km / h, preferably at low speeds. Gear shifting is hindered in the first travel area, ie the work area, because the gear shifting takes a long time, resulting in a long operation stroke.

German Patent Publication No. 39 07 633 C2 discloses an endlessly adjustable hydrostatic traveling driver, in which a first hydraulic motor drives a first output shaft through a first gear component and a second hydraulic motor. The output shaft is likewise driven through a second gear component. Since two gear parts are connected to the output shaft in the first travel area, the rotation moment of the two hydraulic motors acts on the output shaft. By changing the stroke volume of the hydraulic motor, the output rotation speed can additionally change with respect to the change of the stroke volume of the pump. However, this is only possible up to the maximum speed of one of the hydraulic motors. For this reason, there is a mechanical disconnect device between the reduction gear parts of the second motor, which separates the hydraulic motor from the output shaft when the maximum speed of the hydraulic motor is reached, so that other hydraulic motors will continue to accelerate up to that maximum speed. Can be. Before the separation device can be opened, the motor can be adjusted to a stroke volume of almost zero to one. However, jerking occurs due to the connection or disconnection of the motor.

It is an object of the present invention to form a drive for a mobile vehicle in which a rotational moment of two hydraulic motors acts on the output shaft in the first travel region and only a rotational moment of one hydraulic motor acts on the output shaft in the other travel region, In this case the switching collision is minimal and the gears must be simple.

The invention is solved by a general, mobile vehicle driver that also includes the features of the independent claims.

According to the invention, the first hydraulic motor is permanently connected to the output shaft via the first reduction gear part and the further hydraulic motor is likewise through the further reduction gear part. The gear ratios of the gear parts may be the same and are preferably different.

In a further embodiment, the first reduction gear component connected to the first hydraulic motor consists of one spur gear, and the output shaft of the hydraulic motor drives the first spur wheel connected to the second spur wheel, and the second The spur wheel is connected to the output shaft in a non-rotating manner. The second hydraulic motor likewise drives a second reduction gear component consisting of one first spur wheel, the first spur wheel being connected to a further spur wheel which is rotatably connected to the output shaft. There is also the possibility that the first hydraulic motor drives the first spur wheel and the second hydraulic motor likewise drives one spur wheel, in which case the two spur wheels are one common spur wheel connected to the output shaft in a rotatable manner. Action is connected. Although the stroke volume of at least one hydraulic motor is embodied adjustable, the stroke volumes of the two hydraulic motors can preferably be adjusted. To start with a high rotational moment, the pressure means supply parts of the two hydraulic motors are connected to the pressure means output of the pump, and the hydraulic motors have a stroke volume greater than zero. As the transfer volume of the pump increases, the motors that drive the output shaft through the reduction gear parts are driven again. Since the output shaft is connected to the vehicle wheel, the vehicle wheel is also driven. When the maximum conveying volume of the pump is reached, the stroke volume of the at least one hydraulic motor is adjusted to further increase the rotation speed of the output shaft. The motor and the reduction gear parts are preferably designed such that the motor reaches its maximum allowable speed while high pressure is supplied to the pressure means supply when the motor reaches its minimum stroke volume. The hydraulic motor is now adjusted to its stroke volume zero and the pressure means supply is separated from the high pressure, pressure means output of the pump. The pressure means supply part and the pressure means return part of the hydraulic motor are connected to the pressure on the suction side of the hydraulic pump, or to the pressure of the supply pump when the circle is closed, or to the return pressure from the cooler to the gear (tank), Connected to lubrication pressure. By the return pressure of the cooler being connected to the motor, the bearing points and seals of the motor are less loaded because the pressure is below the supply pressure. As the stroke volume of the other motor decreases, the rotation speed of the output shaft further increases, so that the rotation speed of the first hydraulic motor also increases above its maximum allowable rotation speed. However, the first hydraulic motor can be operated above its maximum allowable rotation speed, which means that the stroke volume adjusting device sets the stroke volume to zero and the high pressure is no longer applied to the pressure means supply, so that the motor is almost stroked. It does not have a volume. Preferably, since the hydraulic motor is realized as a radial piston motor, the stroke volume is adjusted to zero so that relative motion does not occur between the piston and the cylinder, so that the motor has less friction. In the use of a radial piston motor with a crankshaft, the stroke volume adjustment part is arranged in the crankshaft, for example as in International Publication No. 99/17021, the crankshaft must be completely enclosed, so that the hydraulic motor has a stroke volume of zero. When adjusted, the crankshaft circulates concentrically so that the piston does not perform a stroke movement. The mechanical stroke volume adjustment shown in International Publication No. 99/17021 may be performed hydraulically by adjusting the adjustment piston through hydraulic pressure. Preferably the regulating piston can be connected to a high pressure, so that the adjustment is made by a high pressure. However, there is also the possibility of forming the hydraulic motor as the axial piston motor, the first hydraulic motor as the radial piston motor, and the second hydraulic motor as the axial piston motor. At the maximum rotational speed of the piston shaft, the first motor is separated from the high pressure, but mechanically connected to the output shaft and its stroke volume is zero. The second motor is adjusted to its minimum stroke volume to drive the output shaft. The hydraulic motors and the deceleration are designed such that the working machine reaches the work area when the maximum allowable speed of the first hydraulic motor is reached. In this way, the travel area is executed only by the second hydraulic motor.

It will be apparent to those skilled in the art that the pressure means supply and the pressure means return of the hydraulic motor rotate when the conveying device of the pump is changed, since the pressure means return is now subjected to high pressure and the pressure means supply is subjected to low pressure. However, when the hydraulic motor is switched off, the line always guiding high pressure is always subjected to low or return pressure, lubrication pressure from the cooler to the tank (gear), and is separated from the high pressure.

In a further embodiment, the adjusting device of the stroke volume is connected to the switchoff valve by a valve, so that the adjusting device for the stroke volume of the motor is automatically separated from the high pressure and subjected to low pressure when the pressure means supply is separated from the high pressure. Thus, when in the disconnected state, the adjusting device is prevented from adjusting the hydraulic motor in the direction of the larger stroke volume.

Since the motor is not disposed on the output shaft, it is possible to arrange the pressure means supply on one side of the crankshaft in the crankshaft to connect to high pressure to adjust the stroke volume. This allows the seal to be placed on a small diameter, thus enabling high rotational speeds even at high pressures.

The first and second hydraulic motors are mechanically and permanently actuated to the output shaft, and at the maximum rotational speed of the output shaft, one hydraulic motor is adjusted to stroke volume 0, the pressure means supply and the pressure means return By being connected to the additional low pressure, no switching collision can occur since the drive system does not require a mechanical disconnect device. Since the cylinder remains filled by the motors being provided with the pressure means even in the switched-off state, no switching collision occurs even in the case of the switch-on.

Further features are set forth in the drawing description.

1 is a hydraulic and gear schematic of a driver.

2 is a graph of stroke volume versus output rotational speed or speed.

3 is a graph of rotational speed versus output rotational speed or vehicle speed.

Figure 1:

The hydrostatic pump 1 which is changeable in its stroke volume, preferably with electronic adjustment according to the rotational speed, transfers the pressure means to the common high pressure line 2 and draws in from the common low pressure line 3. The feed pump 4 draws in through the filter 5 from the pressure means reservoir 6, which is preferably a gear housing, on the one hand to a common low pressure line 3 and on the other hand to the supply pressure line 7. Transfer. The common high pressure line 2 is connected to the first hydraulic motor 9 and the second hydraulic motor 10 by a first switchoff valve 8. The common low pressure line 3 is connected to the first hydraulic motor 9 and the second hydraulic motor 10 by a switchoff valve 8. The stroke volume of the first hydraulic motor 9 can be adjusted and the motor drives the first cogwheel 11 of the first reduction gear component 12, and the second hydraulic motor 10 is the second reduction gear component. The first cogwheel 13 of 14 is driven. The first cogwheel 11 drives the second cogwheel 15, the first cogwheel 13 drives the second cogwheel 16, and the second cogwheel 15 and the second cogwheel 16 ) Is rotatably connected to the output shaft 17. The output shaft 17 is connected to the vehicle wheel. The valve 8 has two switching positions, in which the common high pressure line 2 is connected to the pressure means supply 18 and the pressure means supply 19 is connected to the common low pressure line 3 in the first switching position. do. In the second switching position of the valve 8, the common high pressure line 2 is separated from the pressure means supply 18 and the common low pressure line 3 is likewise separated from the pressure means supply 19. The pressure means supply 18 and the pressure means return 19 are connected to the supply pressure line 7. Since the line 20 can also be connected to the output of the flush valve 21, the pressure means supply 18 and the pressure means return 19 are likewise subjected to the pressure of the feed pump 4, but in the switching position the motor is flushed. Hot oil exiting valve 21 is obtained. By connecting the line 20 to the line 7, the motor at this position obtains the cooled oil of the feed pump 4. Since there is a further possibility of connecting the line 20 to the return line 57 from the cooler 56 to the tank 6, the pressure means supply 18 and the pressure means return 19 are subjected to very low pressure. The valve 22 always provides high pressure to the stroke volume-adjusting device 23 by connecting the line 24 to the line 25 or the line 26. Since the valve 22 is disposed between the valve 8 and the first hydraulic motor 9, the valve 8 is switched to the first switching position so that the stroke volume-adjusting device 23 automatically receives a high pressure, and The stroke volume-adjusting device 23 automatically receives a low pressure when the valve 8 is switched to the two switching positions. Thus, the stroke volume of the first hydraulic motor 9 in the second switching position of the valve 8 cannot be adjusted. The valve 27, like the valve 22, provides high pressure to the stroke volume-adjusting device 28. Since the valves 29, 30 are implemented as proportional valves and connected to an electronic control unit, the adjusting devices 28, 23 connected to the valves 29, 30 can be controlled, so that the hydraulic motors 9, 10. The administrative volume of can be adjusted. The valve 31 is likewise connected to the electronic control device and actuates the valve 8 to hydraulically separate the first hydraulic motor 9 from high pressure.

In order to start the actuator, since the valve 8 is in its first switching position, the common high pressure line 2 is connected to the pressure means supply 18 and the stroke volume of the pump 1 is enlarged, so that the first Rotation moments are formed in the hydraulic motor 9 and the second hydraulic motor 10 and the output shaft 17 is driven by the first gear part 12 and the second gear part 14. By continuously increasing the stroke volume of the pump 1, the rotation speed of the output shaft 17 is accelerated, so that the speed of the vehicle is increased. Then, since the stroke volume of at least one motor, the first motor, or the second motor, or the two motors decreases, the rotation speed of the output shaft 17 continues to increase. When the maximum allowable rotational speed of the first motor 9 is reached, the first motor 9 is adjusted to stroke volume 0 and the valve 31 is affected by the electronic control unit, so that the valve 8 is It is switched to two switching positions and the pressure means supply 18 is separated from the common high pressure line 2. At the same time, the adjusting device 23 is also separated from the high pressure by the valve 22. At the rotational speed, since the first hydraulic motor 9 has a stroke volume of 0 and no force acts on the first hydraulic motor 9 from the high pressure, the first hydraulic motor 9 is above the maximum allowable rotational speed. You can continue to accelerate. This occurs by continuously decreasing the stroke volume until the second hydraulic motor 10 reaches its minimum stroke volume. When the maximum feed amount of the pump 1, and also the minimum stroke volume of the second motor 10 and the first hydraulic motor 9 switched off by the valve, to the maximum rotational speed of the output shaft 17 To this. When using a crankshaft and a radial piston-hydraulic motor with a hydraulic adjustment in the crankshaft, the crankshaft rotates coaxially at maximum rotation speed, so the piston does not execute a stroke in the cylinder. The bearing capacity of the hydraulic motor is also significantly reduced because the hydraulic motor is not subjected to high pressure. Thus, it is not necessary to mechanically separate the hydraulic motor from the output shaft 17. Since the valves 31 and 8 are switched over, the first hydraulic motor 9 is disconnected from the common high voltage line 2 in the non-current state. The transmission ratio of the first reduction gear component 12 and the transmission ratio of the second reduction gear component 14 are such that the first hydraulic motor 9 reaches its maximum allowable rotational speed at the end of the work area of one wheel loader and the valve It is designed to be separated by (8).

Figure 2:

The abscissa 32 shows the vehicle speed or the number of revolutions of the output shaft 17 of FIG. 1, and the ordinate 33 shows the pump 1 of the first hydraulic motor 9 and the second hydraulic motor 10 of FIG. 1. The administrative volume of is shown. At origin 34 the vehicle is stationary. The first motor 9 is at its maximum stroke volume, shown by line 35. The second motor 10 is likewise at its maximum stroke volume, shown by line 36. As the stroke volume of the pump 1 is enlarged, the vehicle or output shaft 17 shown by the line 37 is accelerated. At point 38, the pump 1 has its maximum stroke volume, indicated by line 39, with no change in subsequent observation. From point 40, the stroke volume of the first motor is reduced, which is shown by line 41. Thus, the vehicle continues to accelerate. From point 42, the stroke volume of the second hydraulic motor 10 likewise decreases, as shown by line 43, so that the vehicle continues to accelerate. At point 44 the stroke volume of the first motor is adjusted to zero and the motor is separated from the high pressure by the valve 8 of FIG. Preferably the rotational speed at point 44 corresponds to the maximum allowable rotational speed of the first hydraulic motor 9. From point 45, since only the stroke volume of the second hydraulic motor 10 decreases, the vehicle speed continues to increase, which is shown by line 46. At point 47 the maximum speed of the vehicle is reached and the second motor 10 is at its minimum suction volume. The rotational speed of the first motor 9 is above the maximum allowable rotational speed at point 47. However, since the maximum allowable rotation speed is defined when high pressure is provided to the hydraulic motor, the hydraulic motor can be accelerated to zero-suction volume through its hydraulic switchoff, so that the adjustment of the hydraulic motor can be above that maximum allowable rotation speed.

Figure 3:

The abscissa 48 likewise shows the speed or the number of revolutions of the output shaft 17 as in FIG. In the ordinate 49, the rotation speeds of the pump 1 of the first motor 9 and the second motor 10 are shown. The pump 1 is driven at maximum rotational speed, which can be presented by line 50. The rotation speed of the first hydraulic motor 9 is increased through the change of the suction volume as in FIG. 2, which is shown by the line 51. Since the rotation speed of the second hydraulic motor 10 is increased by changing the stroke volume as in FIG. 2, the running speed of the vehicle is increased as shown by the line 52. As the increase in the lines 51 and 52 is different, the speed ratio of the first gear part 12 and the second gear part 14 is different. At point 53, the first motor 9 reaches its maximum rotational speed, which corresponds to point 44 in FIG. 2. Above point 53, the hydraulic motor 9 has a stroke volume of zero and operates at switched off high pressure. However, the rotational speeds of the first hydraulic motor 9 and the second hydraulic motor 10 continue to increase up to the maximum output rotational speed of the output shaft 17, and the points 54 and 55 are the rotational speeds at the maximum output speed. Shows.

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1: pump

2: common high voltage line

3: common low pressure line

4: feed pump

5: filter

6: pressure means reservoir

7: supply pressure line

8: first switchoff valve

9: first hydraulic motor

10: second hydraulic motor

11: first cog wheel

12: first reduction gear parts

13: first cog wheel

14: second reduction gear parts

15: second gear wheel

16: second gear wheel

17: output shaft

18 pressure supply unit

19: pressure means return

20: line

21: flush valve

22: valve

23: stroke volume adjustment device

24: line

25: line

26: line

27: valve

28: stroke volume adjusting device

29: valve

30: valve

31: valve

32: abscissa

33: ordinate

34: origin

35: line

36: line

37: line

38 points

39: line

40 points

41: line

42 points

43: line

44 points

45 points

46: line

47 points

48: abscissa

49: ordinate

50: line

51: line

52: line

53 points

54 points

55 points

56: cooler

57: line

Claims (9)

A mobile vehicle driver having two hydraulic motors 9, 10, the stroke volume of at least one motor being embodied adjustable, the two hydraulic motors being permanently connected to the output shaft 17, In a mobile vehicle driver in which the hydraulic motors 9, 10 are connected to a common high voltage line 2, At least one hydraulic motor 9 is embodied so that the stroke volume is adjustable to zero, the hydraulic motor 9 can be separated from the common high pressure line 2, The valve 8 separates the first hydraulic motor 9 from the common high pressure line 2, and supplies the pressure means supply part 18 and the pressure means return part 19 of the first hydraulic motor 9 with a feed pump ( A driver for a mobile vehicle, characterized in that connected to the line 20 acting on the supply pressure of 4). The output shaft (17) of claim 1, wherein the first hydraulic motor (9) is driven by the first reduction gear component (12) and the second hydraulic motor (10) is driven by the second reduction gear component (14). A mobile vehicle driver, characterized in that for driving. 2. A mobile vehicle driver according to claim 1, characterized in that the first hydraulic motor (9) has a stroke volume of zero above its maximum allowable rotational speed and is separated from a common high pressure line (2). 3. A drive according to claim 2, characterized in that the speed ratio of the first gear component (12) is greater than the speed ratio of the second gear component (14). delete 3. A drive for a mobile vehicle according to claim 2, wherein the first reduction gear component (12) is a spur gear and the second reduction gear component (14) is a spur gear. The second hydraulic motor (10) according to claim 1, wherein when the output shaft (17) is at its maximum output speed, the first hydraulic motor (9) is separated from the common high pressure line (2) and adjusted to its stroke volume of zero. ) Is adjusted to its minimum stroke volume. The driver of claim 1 wherein the driver is used in a work machine. A mobile vehicle driver having two hydraulic motors 9, 10, the stroke volume of at least one motor being embodied adjustable, the two hydraulic motors being permanently connected to the output shaft 17, In a mobile vehicle driver in which the hydraulic motors 9, 10 are connected to a common high voltage line 2, At least one hydraulic motor 9 is embodied so that the stroke volume is adjustable to zero, the hydraulic motor 9 can be separated from the common high pressure line 2, The valve 8 separates the first hydraulic motor 9 from the common high pressure line 2 and cools the pressure means supply 18 and the pressure means return 19 of the first hydraulic motor 9. And a line 20 to which the lubricating pressure of the downstream line 57 acts.

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