JPH0121332B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an engine-driven hydraulic power source device installed in a working machine such as a construction machine, and more particularly to an engine-driven hydraulic power source equipped with a variable displacement hydraulic pump having a regulator for constant horsepower control. Regarding equipment.

Conventionally, when a variable displacement hydraulic pump is driven by an engine, constant horsepower control is performed to prevent engine stalling. is the maximum, and the loss cannot be ignored.

FIG. 1 is an explanatory diagram showing an example of a conventional engine drive hydraulic power source device proposed to reduce losses during no-load conditions. In the figure, 1 is an engine, 2 is a variable displacement hydraulic pump driven by this engine 1, 3 is a hydraulic circuit that sends pressure oil from the hydraulic pump 2 to an actuator (not shown), and 4 is a system that controls the rotational speed of the engine 1. The fuel lever to be controlled, 5 is a displacement transmitting means for transmitting the displacement of the fuel lever 4 to the governor of the engine 1, for example a control cable, and 6 is a lever holding means for holding the fuel lever 4 at a predetermined angular position, for example a friction plate. 1
Reference numeral 7 denotes a regulator for constant horsepower control, which includes a servo valve 18 for constant horsepower control and a servo valve 19 for controlling the maximum flow rate.
20 is a hydraulic power source that supplies pressure oil to the regulator 17.

In the hydraulic power source device configured in this manner, for example, when all the operation levers of the actuator are in the neutral position, a signal indicating the minimum discharge is outputted, thereby reducing loss during no-load conditions.

However, this conventional engine-driven hydraulic power source device
Although it is possible to reduce loss during no-load conditions, the structure of the regulator 17 is complicated, and in addition to the variable displacement hydraulic pump 2 to be controlled, it is necessary to provide a hydraulic power source as a power source for the regulator. There is a problem that causes the cost to rise. In addition, the regulator 17 has a servo valve 18,
19, there is a risk that the servo valves 18 and 19 may malfunction due to dust, and it cannot be said that they have sufficient reliability.

The present invention has been made in view of the actual situation in the prior art, and its purpose is to provide an engine-driven hydraulic power source device that can simplify the structure of the regulator.

Hereinafter, the present invention will be explained in detail based on the drawings. FIG. 2 is an explanatory diagram showing an embodiment of the engine-driven hydraulic power source device of the present invention. In this figure, the same members as those shown in FIG. 1 described above are designated by the same reference numerals. In FIG. 2, a cylinder 7 is located between the fuel lever 4 and the engine 1. 5a
is a control cable, for example, which is connected to the cylinder 7 at one end and to the governor of the engine 1 at the other end. A piston 8a is slidably housed inside the cylinder 7. This piston 8a is adapted to be locked at a stepped portion 7a formed inside the cylinder 7, and when the maximum displacement of the fuel lever 4 is l, the piston 8a is latched at a stepped portion 7a formed inside the cylinder 7.
It is set to have a stroke of 2. 8
b is a piston rod, one end of which is connected to a displacement transmission means such as a control cable 5b, and the other end connected to a piston 8a.
It is connected to. In addition, the control cable 5b
The other end is connected to a fuel lever 4. A spring 9, for example, a compression spring, is housed in a chamber 15 formed on the right inside the cylinder 7, and is connected to the piston 8a.
and applies a biasing force to the inner wall of the cylinder 7.
A holder 10 holds the cylinder 7 and the piston rod 8b, and includes a base 10a fixed to the floor;
It consists of a bracket 10b which is erected on the base 10a and slidably holds the cylinder 7, and a bracket 10c which is also erected on the base 10a and holds the cylinder 7 slidably. The bracket 10c also serves as a stopper for restricting the movement of the cylinder 7 toward the governor of the engine 1. Reference numeral 11 denotes a pipe line for guiding the discharge pressure of the pump 2 to the cylinder 7, that is, a pilot line.
Reference numeral 21 denotes a regulator for constant horsepower control, which includes a cylinder 22, a piston 23 housed in the cylinder 22, and a piston rod 24 connected to the piston 23 and to the discharge amount variable means of the variable displacement hydraulic pump 2. and a spring accommodated in a chamber 25 on the left side in the figure among the chambers formed between the inner wall of the cylinder 22 and the piston 23. Reference numeral 27 is a conduit or pilot line, which has one end connected to the hydraulic circuit 3 and the other end connected to a right chamber 28 formed between the inner wall of the cylinder 22 and the piston 23.

The operation of the engine drive hydraulic power source device configured as described above is as follows. The relationship between the displacement, that is, the amount of operation of the fuel lever 4 and the engine speed is determined by the relationship between the displacement of the fuel lever 4, that is, the amount of operation, and the engine speed.
A is set so that when the compression spring 9 is in the most compressed state, the relationship is similar to the conventional one. In such a set state, when the fuel lever 4 is placed at the position where the manipulated variable x=0, that is, when the fuel lever 4 is placed at the position 12 shown by the broken line in FIG. 2, the situation will be as follows. When the engine 1 is stopped or the pump 2 is under no load, the piston 8a is engaged with the stepped portion 7a of the cylinder 7, that is, located at the rightmost position in the cylinder 7, and the compression spring 9 is This is the most compressed state, and the cylinder 7 is in contact with the bracket 10c. In this case, the position of the cylinder 7 is the control cable 5a.
The engine speed is transmitted to the governor of the engine 1 through the engine 1, and the engine speed is maintained at the idling speed, that is, the minimum engine speed _Nio . On the other hand, when the engine 1 rotates and a load is applied to the pump 2, pressure is supplied to the chamber 16 of the cylinder 7 through the pilot line 11, and this pressure pressurizes the piston 8a and the inner wall of the cylinder 7, causing the compression spring 9 to It acts to retract and move the cylinder 7 to the right, but as mentioned above, the piston 8a is already located at the rightmost position in the cylinder 7, and the cylinder 7 is in contact with the bracket 10c. Therefore, the cylinder 7 does not move at all, and therefore the engine 1 rotates at the minimum engine speed _Nio as described above.

Next, when the fuel lever 4 is moved to a position where 0<x<l/2, for example, when it is placed at position 13 in FIG. 2, the following will occur. When the pump 2 is under no load, the piston 8a moves to the left via the control cable 5b, and the compression spring 9 is expanded. Since the position of the fuel lever 4 is fixed here, the compression spring 9 continues to push the cylinder 7 to the right, and therefore the cylinder 7 is kept in contact with the bracket 10c. Therefore, the engine 1 rotates at the minimum engine speed N _nio in the same manner as above. On the other hand, when a load is applied to the pump 2, pressure is supplied to the chamber 16 of the cylinder 7 via the pilot line 11, and this pressure pressurizes the piston 8a and the inner wall of the cylinder 7. Only when this pressure overcomes the biasing force of the compression spring 9 will the cylinder 7
is on the left, that is, its stepped portion 7a is on the piston 8.
Move until you hit point a. As a result, the control cable 5a is displaced to the left, and the rotational speed of the engine 1 becomes a rotational speed corresponding to the displacement of the fuel lever 4.

When the fuel lever 4 is moved to a position where l/2≦x≦l, for example, when it is placed at the position 14 shown by the broken line in FIG. 2, the following will occur. When the pump 2 is under no load, the piston 8a moves to the left via the control cable 5b.
Cylinder 7 is also moved to the left by being pulled by a. Since the stroke of the piston 8a with respect to the cylinder 7 is set to 1/2 as described above, the moving distance of the cylinder 7 to the left is x-1/2. At this time, engine 1 has a maximum engine speed of
When N _nax , it rotates at a rotation speed of (N _nax −N _nio )・(x−l/2)/l+N _nio . On the other hand, when a load is applied to the pump 2, it is passed through the pilot line 11 to the cylinder 7.
Pressure is supplied to the chamber 16, and this pressure pressurizes the piston 8a and the inner wall of the cylinder 7 as described above. Only when this pressure overcomes the biasing force of the compression spring 9 does the cylinder 7 move further by 1/2, since the position of the piston 8a is fixed.
2 Move. As a result, the control cable 5a is displaced to the left, and the rotational speed of the engine 1 becomes a rotational speed corresponding to the displacement of the fuel lever 4.

The above relationship can be summarized as follows.
In the following, n _nio is the operation amount x of the fuel lever 4
indicates the minimum number of rotations in the range, and n _nax also indicates the maximum number of rotations in the range. When the displacement of the _fuel lever _{4 , that is ,} the operating amount At the time, n _nio = (N _nax - _{N nio} ) · (x - l/2) / l + N _nio n _nax = (N _nax - N _nio ) · x/l + N _nio . Figure 3 illustrates the above relationship.
The vertical axis shows the engine speed, and the horizontal axis shows the operating amount x of the fuel lever. As is clear from the figure, when the load is applied to pump 2, the engine speed is
It varies along line AB, and when no load is applied, it varies along line ACD.

In the engine drive hydraulic power source device of the present invention,
In this way, the engine speed can be kept low when there is no load, and this operation can be performed completely automatically.

When a load is applied to the pump 2, pressure is supplied to the chamber 28 of the cylinder 22 constituting the regulator 21 via the pilot line 27, and the discharge amount variable means of the hydraulic pump 2 is controlled by the pressure supplied to this chamber 28 and the chamber 28. 25 is controlled in accordance with the force relationship with the spring 26.

Although the control cables 5a and 5b are mentioned above as the displacement transmitting means, the present invention is not limited thereto, and may be formed of a rod, for example. In addition, the compression spring 9 was mentioned as a spring and was described as being housed in the right chamber 15 formed inside the cylinder 7, but this spring is used as a tension spring and the left room 1
It is also possible to configure it so that it accommodates 6.
In addition, in the above, the stroke of the piston 8a is 1/2
However, it is of course not limited to this.

As described above, the engine-driven hydraulic power source device of the present invention has a cylinder and a piston that are slidably disposed between the fuel lever and the engine, and a spring is disposed inside the cylinder, so that the engine-driven hydraulic power source device is driven by the engine. The discharge pressure of the variable displacement hydraulic pump is guided to the cylinder, and only when this discharge pressure overcomes the biasing force of the spring, the cylinder is displaced by a distance corresponding to the displacement of the fuel lever, and the engine is transmitted through the displacement transmission means. Since the regulator is configured to operate the governor of This can bring about the effects listed below.

Since there is no need to provide a servo valve and there is no need to provide a power source for the regulator, manufacturing costs can be reduced.

The risk of malfunction due to dust can be suppressed to a lower level than in the past.

Since the engine speed automatically decreases when there is no load, this has a positive effect on engine life compared to conventional systems, and consumes less engine oil.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram illustrating a conventional engine drive hydraulic power source device, FIG. 2 is an explanatory diagram illustrating an embodiment of the engine drive hydraulic power source device of the present invention, and FIG. 3 is an explanatory diagram illustrating an example of the engine drive hydraulic power source device of the present invention. 3 is a graph showing the relationship between the engine speed and the amount of operation of the fuel lever in the power supply device. DESCRIPTION OF SYMBOLS 1... Engine, 2... Variable displacement hydraulic pump, 4... Fuel lever, 5a, 5b... Control cable, 6... Friction plate, 7, 22... Cylinder, 8a, 23... Piston, 8b, 24...
Piston rod, 9... compression spring, 10... holding body,
11, 27...pilot line, 21...regulator, 26...spring.

Claims (1)

[Claims] 1. A variable displacement hydraulic pump having a regulator for constant horsepower control, an engine that drives the variable displacement hydraulic pump, a fuel lever that controls the rotational speed of the engine, and a fuel lever that holds the fuel lever at a predetermined angular position. An engine-driven hydraulic power source device comprising a lever holding means, a cylinder having one end connected to the governor of the engine via a displacement transmission means, a piston housed inside the cylinder, and one end connected to the governor of the engine via a displacement transmission means. a piston rod connected to the fuel lever and having its other end connected to the piston; a spring housed in the cylinder and applying a predetermined biasing force to the piston and the inner wall of the cylinder; and the variable displacement hydraulic pump. and a holder having a stopper that slidably holds the piston rod and the cylinder and appropriately restricts movement of the cylinder in the direction of the governor, The engine-driven hydraulic power source device is characterized in that the cylinder is displaced by a distance corresponding to the displacement of the fuel lever only when the discharge pressure of the variable displacement hydraulic pump overcomes the biasing force of the spring.