JPH0777202A - Oil pressure tank - Google Patents

Abstract

PURPOSE:To improve the maintenance property, and reduce costs in a pressurized type oil pressure tank for use in an aircraft, etc., by interposing an energizing means for energizing the capacity of the tank in the direction in which the capacity is changed to the decreasing side, between a movable partition wall and a piston. CONSTITUTION:When a hydraulic pump 16 is operated, high pressure hydraulic oil is supplied to hydraulic apparatuses, and supplied to a chamber 25 of a pressurizing cylinder 22 through a check valve 26 and a relief valve 27. Another chamber 24 of the pressurizing cylinder 22 is filled with the hydraulic oil in the oil pressure chamber 14 through the passage 17 of a hollow shaft 18, and a pressurizing piston 23 is moved and lowered to the position at which the pressures of the two chambers 24, 25 are in balance. The movement of the pressurizing piston 23 is transmitted to a separation piston 12 through the hollow shaft 18. After a spring 21 is most contracted, the separation piston 12 is moved in the same direction as the pressurizing piston 23 by the same amount of movement as that of the piston to reduce the capacity of the oil pressure chamber 14, and as a result, the hydraulic oil in the oil pressure chamber 14 is pressurized.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hydraulic tank, and more particularly to a technique for improving a pressurizing hydraulic tank used in aircraft and the like.

[0002]

2. Description of the Related Art Generally, a hydraulic tank of an aircraft flying at a high altitude is used by increasing the internal pressure of the tank in order to prevent cavitation when starting a hydraulic pump. FIG. 2 is a configuration diagram of a conventional hydraulic tank. Reference numeral 1 denotes a cylindrical hydraulic tank (hereinafter may be abbreviated as “tank”), and the tank 1 includes two chambers 3 separated by a separating piston 2.
It is divided into four.

One chamber 3 communicates with the atmosphere via an air hole 5a formed in the cap 5 of the tank 1 (hereinafter, this one chamber 3 is referred to as "atmosphere chamber"), and the other chamber 3 4 is
It is connected to the hydraulic pump 6 via a discharge port 1a formed on the bottom surface of the tank 1, and is connected to a hydraulic device (not shown) via a return port 1b also formed on the bottom surface of the tank 1. (Hereinafter, the other chamber 4 is referred to as "hydraulic chamber").

The isolation piston 2 is fixed by a nut 9 to one end of a hollow shaft 8 which has a passage 7 communicating with the hydraulic chamber 4 in its axis, and the other end of the hollow shaft 8 is provided in the lower portion of the tank 1. Pressurizing piston 11 of pressurizing cylinder 10
It is integrally connected to. The pressurizing cylinder 10 is partitioned into two chambers 12 and 13 by a pressurizing piston 11.
One chamber 12 communicates with the hydraulic chamber 4 via the passage 7 of the hollow shaft 8. Further, the other chamber 13 is connected to an accumulator 14 and also to a hydraulic device (not shown) via an electromagnetic opening / closing valve 15 and further, via a check valve (one-way valve) 16 to a discharge port of the hydraulic pump 6. Connected to.

In such a structure, when the hydraulic pump 6 is operated, high-pressure hydraulic oil from the hydraulic pump 6 flows into the chamber 13 of the pressurizing cylinder 10 and moves the pressurizing piston 11 downward. The movement of the pressurizing piston 11 continues until the pressures in the two chambers 13 and 14 of the pressurizing cylinder 10 are balanced, and stops at the balanced position. Here, since the pressurizing piston 11 and the separating piston 2 are integrally connected by the hollow shaft 8, the downward movement of the pressurizing piston 11 is also transmitted to the separating piston 2. Therefore, the isolation piston 2 also moves downward like the pressurizing piston 11, and as a result, the internal pressure of the pressure chamber 4 is increased.

Now, when the hydraulic pump 6 is stopped, the check valve 16 is turned off and the supply of high-pressure hydraulic oil to the chamber 13 of the pressurizing cylinder 10 is cut off, but the high pressure of the chamber 13 is maintained by the pressure of the accumulator 14. Therefore, the position of the pressurizing piston 11 (that is, the isolation piston 2) does not change. Therefore, the internal pressure of the hydraulic chamber 4 does not decrease and the pressurization is maintained, so that cavitation can be avoided when the hydraulic pump 6 is started.

[0007]

However, in such a conventional hydraulic tank, the chamber 1 of the pressurizing cylinder 10 is used.
Since the accumulator 14 is connected to 3 and the gas pressure of the accumulator 14 is used to secure the pressurization immediately after the hydraulic pump 6 is started, there is a problem that the accumulator 14 is expensive and heavy and large. There was a point. Further, the gas pressure of the accumulator 14 needs to be regularly checked and replenished, which causes a problem that maintainability is poor.

Further, when the operation of the hydraulic pump 6 is stopped,
It is necessary to prevent the pressure drop in the chamber 13 by blocking the communication between the chamber 13 of the pressurizing cylinder 10 and the hydraulic equipment.
5 and the controller for controlling the on / off of the solenoid opening / closing valve 15 must be equipped. [Object] Therefore, an object of the present invention is to provide a hydraulic tank that does not require expensive and heavy large parts such as an accumulator and an electromagnetic on-off valve, is excellent in maintainability, and is low in cost.

[0009]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention has two chambers which are partitioned by a piston interlocking with the variable partition, with part of the partition of a tank for filling a fluid being a variable partition. In a hydraulic tank in which the fluid in the tank is introduced into one of the chambers and the discharge pressure of the hydraulic pump is introduced into the other chamber, the volume of the tank is changed according to the pressure difference between the two chambers. An intervening biasing means for exerting a biasing force in a direction of decreasing the volume of the tank between the movable partition wall and the piston, and
Between the other chamber and the hydraulic pump, a check valve that allows only the movement of the fluid from the hydraulic pump to the other chamber is provided, or a relief valve is connected in parallel with the check valve. The opening set pressure of the relief valve is set lower than the discharge pressure of the hydraulic pump.

[0010]

According to the present invention, when the hydraulic pump is deactivated, the pressure of the other chamber is maintained by the action of the check valve.
Even when the pressure in the other chamber is reduced due to the contraction of the hydraulic oil due to the decrease of the oil temperature and the leakage of oil from each part of the system while the hydraulic pump is not operating, the urging force of the urging means causes The pressure is maintained.

Therefore, the pressure (pressurization) in the tank at the time of starting the operation of the hydraulic pump is always properly secured, and cavitation can be avoided without using an accumulator or an electromagnetic opening / closing valve.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing an embodiment of a hydraulic tank according to the present invention. First, the configuration will be described. In FIG. 1, 11
Is a cylinder-shaped hydraulic tank (hereinafter may be abbreviated as “tank”), and the tank 11 is divided into two chambers 13 and 14 by an isolation piston 12 as a movable partition wall.

One chamber 13 is a cap 1 of the tank 11.
5 communicates with the atmosphere through an air hole 15a (hereinafter, the one chamber 13 is referred to as "atmosphere chamber"), and the other chamber 14 is a discharge port formed on the bottom surface of the tank 11. Exit 11
It is connected to the hydraulic pump 16 via a, and is connected to a hydraulic device (not shown) via a return port 11b also formed in the bottom surface of the tank 11 (hereinafter, the other chamber 14 is referred to as "hydraulic pressure"). Room ").

The isolation piston 12 has one end of a hollow shaft 18 having a passage 17 communicating with the hydraulic chamber 14 in its shaft.
It is attached by allowing a predetermined distance L to move in the axial direction, and between this isolation piston 12 and a washer 20 held by a nut 19 at the tip of the hollow shaft 18,
A spring 21 having a predetermined spring force is contracted.

The other end of the hollow shaft 18 is provided with a pressurizing piston 23 of a pressurizing cylinder 22 provided under the tank 11.
Is integrally connected to the pressurizing cylinder 22 and the pressurizing piston 23.
Is divided into two chambers 24 and 25. One chamber 24 communicates with the hydraulic chamber 14 via the passage 17 of the hollow shaft 18, and the other chamber 25 has a check valve 26.
And a relief valve 27 connected in parallel with the check valve 26
Is connected to the discharge port of the hydraulic pump 16 via the, and the discharge port of the hydraulic pump 16 is connected to a hydraulic device (not shown).

Here, the direction of the check valve 26 is such that only the flow of hydraulic oil from the hydraulic pump 16 to the other chamber 25 is allowed. Further, the relief valve 27 is opened when the differential pressure between the discharge pressure of the hydraulic pump 16 and the internal pressure of the other chamber 25 is equal to or higher than the set pressure, so that the flow between the hydraulic pump 16 and the other chamber 25 can be controlled. It is a balance-type relief valve that is allowed in the opposite direction, and the set pressure is set to be lower than the discharge pressure of the hydraulic pump 16. The discharge pressure mentioned here is the discharge pressure when the hydraulic pump 16 is operating normally.

Next, the operation will be described. When the hydraulic pump 16 is operating, the high-pressure hydraulic oil discharged from the hydraulic pump 16 is supplied to a hydraulic device (not shown), and the chamber 25 of the pressurizing cylinder 22 passes through the check valve 26 and the relief valve 27. Is supplied to. The other chamber 24 of the pressurizing cylinder 22 is filled with the hydraulic oil in the hydraulic chamber 14 via the passage 17 of the hollow shaft 18, and the pressurizing piston 23 controls the pressure of these two chambers 24, 25. Moves down to the position where is balanced.

The movement of the pressurizing piston 23 is transmitted to the isolating piston 12 through the hollow shaft 18, and the isolating piston 12 has a spring 21 between the hollow shaft 18 and the isolating piston 12 contracted most (state shown in the drawing). ), The same amount is moved in the same direction as the pressurizing piston 23.
As a result, the volume of the hydraulic chamber 14 is reduced, and as a result, the working oil in the hydraulic chamber 14 is pressurized.

Here, when the hydraulic pump 16 is stopped, both the check valve 26 and the relief valve 27 are turned off, so that the pressure in the chamber 25 of the pressurizing cylinder 22 is not released and the position of the pressurizing piston 23 remains unchanged. Retained. as a result,
Since the position of the isolation piston 12 does not change, the hydraulic chamber 14
Is maintained as it is, and cavitation is avoided when the hydraulic pump 16 is restarted.

By the way, when the time from the stop to the start of the hydraulic pump 16 is long, the amount of contraction of the fluid due to the temperature drop of the hydraulic oil and the oil leakage from each part of the system including the check valve 26 and the relief valve 27 can be ignored. Although the pressure in the chamber 25 of the pressurizing cylinder 22 is reduced, it becomes difficult to maintain proper pressurization. However, in this embodiment, a spring is provided between the isolation piston 12 and the hollow shaft 18 (in other words, the pressurizing piston 23). Since 21 is contracted and the biasing force of the spring 21 is used to compensate for the pressure drop in the chamber 25 of the pressurizing cylinder 22, proper pressurizing can be maintained and the hydraulic pump 16 can be operated after a long stop. Even when activated, cavitation does not occur.

That is, when the pressure in the chamber 25 of the pressurizing cylinder 22 decreases due to contraction of hydraulic oil, oil leakage, etc., the pressurizing piston 23 moves upward and the hollow shaft 18 moves upward accordingly. Since the isolation piston 12 biased by the spring 21 moves in the biasing direction (downward) within the distance L, the volume of the hydraulic chamber 14 remains at least during the downward movement of the isolation piston 12. It is possible to maintain the proper pressurization without changing.

The reason for providing the relief valve 27 is as follows. Balance balance of hydraulic oil Depending on the control method of the hydraulic device, the balance balance between the discharge amount of the hydraulic pump 16 and the amount of return oil from the hydraulic device may be lost. In such a case, the isolation piston 12 uses the balance balance. I try to move only the difference. Therefore,
In order to free the movement of the pressurizing piston 23, the chamber 25
It is necessary to communicate between the hydraulic pump 16 and the hydraulic pump 16.
Since the opening set pressure of the relief valve 27 is set to be lower than the discharge pressure of the hydraulic pump 16, in such a case, the relief valve 27 is in the on (open) state, and this requirement can be satisfied.

Maintaining Pressurization While the Hydraulic Pump is Stopped When the hydraulic pump 16 is stopped, it is necessary to disconnect the chamber 25 from the hydraulic pump 16 in order to keep the position of the pressurizing piston 23. The relief valve 27 is in the off (closed) state when the discharge pressure of the hydraulic pump 16 becomes substantially zero, and thus it is possible to meet such a requirement.

Replenishment of hydraulic oil When the hydraulic oil in the hydraulic chamber 14 decreases, the return oil port 11
The hydraulic oil is replenished from b.
If the discharge pressure is set to about 6, the relief valve 27 is turned on (opened), the movement of the pressurizing piston 23 is made free, and the supply can be performed without any trouble.

In the above embodiment, the hollow shaft 1
8 between the upper end of 8 and the isolation piston 12.
Is provided, but is not limited to this. For example, an elastic body such as rubber may be used instead of the spring, or the shaft of the hollow shaft is divided into two and a spring is provided between them, or a pressurizing piston is slidably attached to the hollow shaft, A spring may be provided between the pressurizing piston and the lower end of the hollow shaft. The point is that an urging means that exerts an urging force in the direction of changing the volume of the tank to the decreasing side may be interposed between the isolation piston and the pressure piston.

[0026]

EFFECTS OF THE INVENTION According to the present invention, since it is configured as described above, it is possible to provide a hydraulic tank which is excellent in maintainability and does not require expensive and heavy large parts such as an accumulator and an electromagnetic on-off valve. .

[Brief description of drawings]

FIG. 1 is a configuration diagram of an embodiment.

FIG. 2 is a configuration diagram of a conventional example.

[Explanation of symbols]

 11: Tank 12: Isolation piston (variable partition) 16: Hydraulic pump 21: Spring (biasing means) 23: Pressurizing piston (piston) 24: One chamber 25: The other chamber 26: Check valve 27: Relief valve

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Akira Ito 1110-1 Miyazaki, Tarui-cho, Fuwa-gun, Gifu Prefecture Tezaki Machinery Co., Ltd. Gifu No. 1 factory

Claims (2)

[Claims] 1. A part of a partition wall of a tank for filling a fluid is a variable partition wall, and the fluid in the tank is introduced into one of two chambers partitioned by a piston interlocking with the variable partition wall. In a hydraulic tank in which the discharge pressure of a hydraulic pump is introduced into the other chamber and the volume of the tank is changed according to the pressure difference between the two chambers, a volume of the tank is set between the movable partition and the piston. A check valve in which an urging means for exerting an urging force in a direction of decreasing is interposed, and which allows only fluid to move from the hydraulic pump to the other chamber between the other chamber and the hydraulic pump. A hydraulic tank characterized by being provided with. 2. The hydraulic tank according to claim 1, wherein a relief valve is connected in parallel with the check valve, and an opening set pressure of the relief valve is set lower than a discharge pressure of the hydraulic pump.