JPS5855386B2 - Inertial drive hydraulic closed circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a hydraulic closed circuit for driving an inertial body.

FIG. 1 is a diagram showing a conventional hydraulic closed circuit for driving an inertial body 1.

In the figure, 1 is a prime mover, 2 is a bidirectionally rotatable hydraulic pump driven by the prime mover 1, 3 is a hydraulic motor connected to the hydraulic pump via connecting pipes 4 and 5, and 6 is a hydraulic pump attached to the hydraulic motor 3. 7 is a tank, 8 is a hydraulic pump, 9 is a relief valve connected to the hydraulic pump 8, 10.1
1 is a check valve provided in a pipe connecting the hydraulic pump 8 and connecting pipes 4 and 5, and 12.13 is an IJ valve provided in a pipe connecting the connecting pipes 4 and 5, respectively. It is.

In this hydraulic closed circuit, the lever 2a of the hydraulic pump 2
For example, when tilting in the direction A, the discharge pressure oil of the hydraulic pump 2 is supplied to the hydraulic motor 3 via the connecting pipe 4, and the inertial body 6
starts turning.

Next, when the lever 2a is returned to the neutral position, the inertia body 6 continues to rotate due to inertia force, and the hydraulic motor 3 operates as a pump, so the pressure in the connecting pipe 5 increases and the relief valve 1
3 becomes open.

Therefore, all the energy that the inertial body 6 had is IJ
It is converted into heat by the IJ-F valve 13 and the heat is discarded into the oil, so the energy cannot be used effectively.

This invention was made to solve the above-mentioned problems, and an object thereof is to provide an inertial body-driven hydraulic closed circuit that can effectively utilize energy.

To achieve this objective, the present invention mechanically connects a first hydraulic pump motor to a prime mover that drives a hydraulic pump, and connects a second hydraulic pump motor to the first hydraulic pump motor. Connect the circuit and attach the flywheel to the second hydraulic pump motor.

FIG. 2 is a diagram showing an inertial body drive hydraulic closed circuit according to the present invention.

In the figure, 14 is a hydraulic pump/motor mechanically connected to the prime mover 1, 15 is a hydraulic pump/motor connected to the hydraulic pump/motor 14 in a closed circuit, and 16 is a hydraulic pump/motor.
A flywheel attached to the motor 15, 17.18 are pipes connecting the hydraulic pump/motor 14 and the hydraulic pump/motor 15, and 19.20 are connecting the hydraulic pump 8 and the connecting pipes 4, 5. Conduit, 21'.

22 are pipes 17 and 18 and pipes 1B and 20, respectively.
The pipes 23 and 24 connecting the pipes 21 and 22 are check valves provided in the pipes 21 and 22.

In this hydraulic closed circuit, the lever 2a of the hydraulic pump 2
For example, when the hydraulic pump 2 is tilted in the direction A, the oil discharged from the hydraulic pump 2 is supplied to the hydraulic motor 3 via the connecting pipe 4, and the inertial body 6 starts turning.

In this case, the lever 14 of the hydraulic pump motor 14, 15
a.

15a is set at the neutral position.

Next, when the lever 2a is returned to near the neutral position, the inertial body 6
Since the hydraulic motor 3 continues to rotate due to inertial force, the hydraulic motor 3 operates as a pump and continues to discharge oil to the connecting pipe 5.

Therefore, the pressure in the connecting pipe 5 becomes high, and the hydraulic pump 2 is driven as a motor.

Therefore, when the levers 14a and 15a are tilted in directions C and D, respectively, the hydraulic pump/motor 14 is driven by the hydraulic pump 2 and operates as a pump, and the hydraulic pump/motor 15
If the discharge amount is made smaller than the discharge amount of the hydraulic pump/motor 14, the hydraulic pump/motor 15 is driven by the pressure oil discharged from the hydraulic pump/motor 14 and operates as a motor, so that the flywheel 16 rotates.

Then, when the inertial body 6 stops turning, the lever 2a
, 14a and 15a are returned to their neutral positions.

In this way, the energy possessed by the inertial body 6 is stored in the flywheel 16 as rotational energy.

Next, when starting the rotation of the inertial body 6, the lever 2
a in direction A or B, then levers 14a and 15
a in directions C and D, respectively, to make the discharge amount of the hydraulic pump/motor 14 smaller than the discharge amount of the hydraulic pump/motor 15.

In this case, the hydraulic pump motor 15 is connected to the flywheel 16
The hydraulic pump/motor 14 is driven by the discharge pressure oil of the hydraulic pump/motor 15 and operates as a motor to drive the hydraulic pump 2 .

Then, the hydraulic motor 3 is driven by the pressure oil discharged from the hydraulic pump 2, and the inertial body 6 starts turning.

In this way, the energy stored in the flywheel 16 can be used effectively.

When the rotational speed of the flywheel 16 becomes smaller than a predetermined value, the levers 14a and 15a are returned to the neutral position, so that the hydraulic pump 2 is operated only by the prime mover 1.
Driven.

Note that the pressure oil discharged from the hydraulic pump 8 is checked by the check valves 23 and 24.
Since the hydraulic fluid is supplied to the hydraulic pump motors 14 and 15 via the hydraulic pump motors 14 and 15, cavitation of the hydraulic pump motors 14 and 15 is prevented.

In the above-mentioned embodiment, the case where the actuator is the hydraulic motor 3 has been described, but the present invention can also be applied to the case where the actuator is a hydraulic cylinder.

As explained above, in the inertial body-driven hydraulic closed circuit according to the present invention, the energy of the inertial body can be temporarily stored in the flywheel and used again, so that the energy can be used effectively. , the energy efficiency of the circuit increases.

As described above, the effects of this invention are remarkable.

[Brief explanation of drawings]

FIG. 1 is a diagram showing a conventional inertia body drive hydraulic closed circuit, and FIG. 2 is a diagram showing an inertia body drive hydraulic closed circuit according to the present invention. 1... Prime mover, 2... Hydraulic pump, 3
......Hydraulic motor, 6...Inertia body, 14
, 15... Hydraulic pump motor, 16...
・Fly foil.

Claims (1)

[Claims] 1. In an inertial body driven hydraulic closed circuit having a hydraulic pump and an actuator that drives an inertial body, a first hydraulic pump motor is mechanically connected to a prime mover that drives the hydraulic pump, and the first hydraulic pump motor is mechanically connected to the prime mover that drives the hydraulic pump. An inertial body-driven hydraulic closed circuit characterized in that a second hydraulic pump/motor is connected to the motor in a closed circuit, and a flywheel is attached to the second hydraulic pump/motor.