JPH09100810A - Oil pressure tester - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily double the power of a conventional oil pressure tester at a low cost and to suppress a running cost low without any replacement to another large power oil pressure tester for operating an oil pressure test for a large construction machine. SOLUTION: An oil pressure circuit in a power up kit 2 provided with an electric motor and a high pressure variable displacement pump is connected to an oil pressure circuit in a conventional oil pressure tester 1 in compliance with necessity, and oil discharged from the high pressure variable displacement pump in the power up kit 2 is fed into the system line in the conventional oil pressure tester 1 so as to be used as an auxiliary for the conventional oil pressure tester 1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a hydraulic tester in a hydraulic machine.

[0002]

2. Description of the Related Art A hydraulic universal tester called a hydraulic universal tester for construction machinery is used in maintenance factories and the like, and measures the characteristics of hydraulic equipment such as hydraulic pumps, hydraulic motors, hydraulic valves, etc. after repair or regeneration. It has a similar mechanism in order to apply the same load to the hydraulic equipment that is actually operating as a simulator.

[0003]

Conventionally, the hydraulic tester has conventionally been 100 to 200 horsepower, and in a hydraulic test of a large construction machine which exceeds the capacity, it is replaced with another hydraulic tester having a large horsepower and tested. It had to be done, and it was extremely uneconomical and troublesome.

It is an object of the present invention to provide a hydraulic tester which eliminates the disadvantages of the conventional example, can double the power of the existing hydraulic tester easily and at low cost, and can keep the running cost low. It is in.

[0005]

In order to achieve the above-mentioned object, the present invention firstly provides a hydraulic circuit of a power-up kit having an electric motor and a high-pressure variable displacement pump to the hydraulic circuit of an existing hydraulic tester, if necessary. Connect and transfer the oil discharged from the high-pressure variable displacement pump of the power-up kit to the system line of the existing hydraulic tester to use as an auxiliary to the existing hydraulic tester. Second, the high-pressure variable capacity of the power-up kit The pump has a higher pressure than the high pressure variable displacement pump of the existing hydraulic tester, and the power-up kit sends the oil discharged from the discharge port to the system line of the existing hydraulic tester or the high pressure from the flow out port as a single use. The gist of the present invention is to incorporate a direction switching valve that switches between discharging as oil.

According to the first aspect of the present invention, the power of the existing hydraulic tester can be doubled by a simple and quick operation of simply attaching the power-up kit to the existing hydraulic tester. Since the hydraulic tester can be used as it is, its performance can be obtained at a low price that is not comparable to large existing hydraulic testers.

Further, when high output is not required, the existing hydraulic tester or power-up kit can be operated independently, which makes it possible to extend the service life of the existing hydraulic tester and the main body of the existing hydraulic tester. It is also possible to operate the hydraulic pump during the disassembly and repair.

[0008] The running cost can be significantly reduced as compared with the case where a large motor is operated by itself by reducing the mobile current and operating independently.

According to the second aspect of the present invention, the high-pressure variable displacement pump of the power-up kit has a higher pressure than that of the existing high-pressure variable displacement pump of the hydraulic tester, and the power-up kit is changed by switching the direction switching valve. It is possible to obtain the pressure that cannot be obtained by the existing hydraulic tester by discharging the oil discharged from the discharge port as the high pressure oil from the flow-out port as a single use.

[0010]

Embodiments of the present invention will be described below in detail with reference to the drawings. 1 is a front view showing one embodiment of a hydraulic tester of the present invention, FIG. 2 is a rear view of the same, FIG. 3 is a side view of the same, and FIG. 7 is a hydraulic circuit diagram.

In the figure, 1 is an existing hydraulic tester, 2 is a power-up kit which is connected to the existing hydraulic tester 1 as required, 3 is a hydraulic hose for this connection, and the existing hydraulic tester 1 is well known. , An oil tank 4, a main electric motor 5, a high pressure variable displacement pump 6 driven by the main electric motor 5, various valves and an auxiliary pump. As an example, the high-pressure variable displacement pump 6 has a discharge pressure of up to 350 kg / cm ² .

Further, the existing hydraulic tester 1 incorporates a high torque motor unit 13 and a power-up cylinder 14 which are composed of a high torque motor, a connecting flange, a universal joint, an adapter plate and the like.
The high torque motor unit 13 and the power-up cylinder 14 are connected and connected to a hydraulic pump, a hydraulic motor, or the like, which is a device under test, and a load for testing is applied to them.

On the other hand, the power-up kit 2 has an electric motor 7,
It is composed of a high-pressure variable displacement pump 8, a suction filter 9, a control panel 10, etc., and its hydraulic circuit is connected to the hydraulic circuit of an existing hydraulic tester via a direction switching valve 11. This high-pressure variable displacement pump 8 has a maximum discharge pressure of 42 as an example.
It is of 0 kg / cm ² .

In the figure, reference numeral 12 is a check valve unit provided on the hydraulic circuit side of the existing hydraulic tester 1. When connecting the power up kit 2 and the existing hydraulic tester 1, the check valve unit is connected via this. Then, the backflow of the discharge oil from the existing hydraulic tester 1 and the power-up kit 2 is prevented.

In the oil tank 4 of the existing hydraulic tester 1, the high pressure variable displacement pump 8 of the power up kit 2 is installed.
Is connected to the check valve unit 12 of the existing hydraulic tester 1 via the high-pressure variable displacement pump 8 and the direction switching valve 11 to form a circuit, which is an existing circuit. Hydraulic tester 1
Oil tank 4-High pressure variable displacement pump 6-High torque
The motor unit 13 and the oil tank 4 are arranged in parallel to a closed circuit (closed type).

In this way, the power-up kit 2 discharges the oil sucked from the suction line of the high-pressure variable displacement pump 8 from the discharge port, and transfers it to the system line of the existing hydraulic tester 2 so that the existing hydraulic tester 2 can be operated. Will be used as an aid to.

Further, when the discharge oil from the power-up kit 2 is used as an auxiliary to the drive motor line of the existing hydraulic tester 1 in the hydraulic circuit of the existing hydraulic tester 1, this auxiliary oil tank 4 is used. A low-pressure relief valve unit 15 used to adjust the return pressure to is installed.

Directional switching valve 11 of the power-up kit 2
Existing hydraulic tester 1 check valve unit
In the switching direction that is not on the 12 side, a high-pressure oil measurement unit 16 that consists of a hydraulic gauge, a flow-out port, and a flow meter turbine block for measurement, and that measures the pressure and discharge rate of the flow-out line of the power-up kit 2 is installed. Connecting.

In the figure, reference numeral 18 is a high-pressure load valve unit, which is connected to the discharge side of the high-pressure variable displacement pump 8 and has a capacity of 0 to 420 k.
It is a device that raises the pressure to g / cm ² and applies a load.

In the figure, 17 is a flow chart of the power-up kit 2.
A hydraulic remote controller installed in the outline, which is composed of a high pressure relief valve and a low pressure relief valve, and regulates the flow outline pressure and discharges the high pressure variable displacement pump 8 of the power up kit 2. Remote control of quantity adjustment and rotation adjustment of drive motor.

Reference numeral 19 in FIG. 1 indicates an electric remote
A controller, which comprises an ammeter, various switches, a lamp, a flow meter, etc., and remotely controls the control panel 10 of the power-up kit 2.

Next, the usage will be described. The hydraulic oil sent from the high pressure variable displacement pump 8 of the power up kit 2 is powered by the direction switching valve 11 to power up the hydraulic system of the existing hydraulic tester 1 or to add an additional high pressure. Use the discharge port to switch whether to discharge a maximum of 420 kg / cm ² of high pressure hydraulic oil.

As for usability, the power-up kit 2
The hydraulic pressure of the existing hydraulic tester 1 can be increased by approximately 100 to 150 by adding, and when such high pressure is not required, the existing hydraulic tester 1 can be used.
Alternatively, the power-up kit 2 can be used alone.

FIG. 8 is a graph showing the relationship between the discharge pressure and the flow rate, where A is the conventional product or the existing hydraulic tester 1 alone, and B is the power up kit 2 alone.
C is the case of using the hydraulic tester 1 that has been powered up by adding the power up kit 2.

FIG. 9 is a comparison of torque curves of drive motors, where A is the conventional or existing hydraulic tester 1 used alone, and C is the hydraulic tester 1 powered up by adding the power-up kit 2. When to use. By adding the power-up kit 2 as described above, the drop in torque in the high rotation range, which is the fate of the hydraulic transmission, is significantly reduced.

FIG. 10 shows another embodiment in which the hydraulic circuit of the existing hydraulic tester 1 is an open circuit, in which the oil tank 4, the main electric motor 5, the high pressure variable displacement pump 6 driven by the main electric motor 5, and The power-up kit 2 includes a high-pressure variable displacement pump 8 driven by an electric motor 7 of the high-pressure variable displacement pump 6 although it includes various valves and auxiliary pumps.
Will be connected in series.

As described above, in the case of the existing hydraulic tester 1 having an open circuit, the power up kit 2 can be added relatively easily, and the low pressure relief valve unit 15 can be added.
The adjustment function such as is not required.

[0028]

INDUSTRIAL APPLICABILITY As described above, the hydraulic tester of the present invention can be used for the hydraulic test of a large construction machine without changing the power of the existing hydraulic tester without replacing the hydraulic tester with another large horsepower. The cost can be easily and cheaply doubled, and the running cost can be kept low.

[Brief description of the drawings]

FIG. 1 is a front view showing an embodiment of a hydraulic tester of the present invention.

FIG. 2 is a rear view showing an embodiment of the hydraulic tester of the present invention.

FIG. 3 is a side view showing an embodiment of the hydraulic tester of the present invention.

FIG. 4 is a front view of a power-up kit portion.

FIG. 5 is a side view of a power-up kit portion.

FIG. 6 is a plan view of a power-up kit portion.

FIG. 7 is a hydraulic circuit diagram.

FIG. 8 is a graph showing the relationship between discharge pressure and flow rate.

FIG. 9 is a comparison of torque curves of drive motors.

FIG. 10 is a circuit diagram showing an embodiment of a hydraulic tester of the present invention.

[Explanation of symbols]

1 ... Hydraulic tester 2 ... Power up kit 3 ... Hydraulic hose 4 ... Oil tank 5 ... Main electric motor 6 ... High pressure variable displacement pump 7 ... Electric motor 8 ... High pressure variable displacement pump 9 ... Suction filter 10 ... Control panel 11 ... Direction switching valve 12 ... Check valve unit 13 ... High torque motor unit 14 ... Power up cylinder 15 ... Low pressure relief valve unit 16 ... High pressure oil measuring unit 17 ... Hydraulic remote controller 18 ... High pressure load valve unit 19 ... Electric・ Remote controller

Claims (2)

[Claims] 1. A hydraulic circuit of a power-up kit having an electric motor and a high-pressure variable displacement pump is connected to a hydraulic circuit of an existing hydraulic tester, if necessary, so that oil discharged from the high-pressure variable displacement pump of the power-up kit is existing. A hydraulic tester characterized by being rolled into the hydraulic tester system line and used as an auxiliary to the existing hydraulic tester. 2. The high-pressure variable displacement pump of the power-up kit has a higher pressure than the high-pressure variable displacement pump of the existing hydraulic tester, and the power-up kit transfers the oil discharged from the discharge port to the system line of the existing hydraulic tester. The hydraulic tester according to claim 1, which incorporates a direction switching valve for switching between sending and discharging as high pressure oil from a flow-out port as a single use.