JPS59126104A - Double piston cylinder apparatus - Google Patents

Abstract

PURPOSE:To permit a piston rod to be set at three point positions by accommodating a double piston into a cylinder, permitting relative displacement, and providing with four fluid ports. CONSTITUTION:When fluid flows into the fourth fluid port P4, an outside piston 3 shifts to the left end position and stops, and when fluid flows from the third fluid port P3, fluid flows into a hollow part 3a, passing through a groove 3g and a communication hole 3h, and an inside piston 4 shifts leftward, and the outside piston 3 and the inside piston 4 shift to the left edge and stop. When fluid flows into the fourth fluid port P4, fluid is introduced into the hollow part 3a, passing through a groove 3e and a communication hole 3f, and the outside pistons shifts rightward and stops. When fluid is introduced into the first piston P1, the outside piston 3 shifts rightward and stops at the right edge position, and when fluid is supplied from the second fluid port P2, fluid flows into the hollow part 3a passing through the groove 3e and the communication hole 3f, and the inside piston 4 shifts rightward and stops. A piston rod 9 can be set at three point positions L, M, and R only by controlling the inflow of fluid.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a double piston cylinder device, and more particularly to a cylinder device in which a piston rod can be set at three desired positions with a simple configuration.

In a conventional single piston cylinder device, the piston rod fixed to the piston can be reliably set at two points, but it is not possible to reliably set it at three points including the intermediate pupil between the two points. There was a drawback that it could not be done.

The invention was made in order to eliminate the above-mentioned drawbacks of the prior art, and its purpose is to accommodate a double piston in a cylinder so that it can be relatively displaced. To provide a cylinder device that can reliably set the piston rod at three positions.

Briefly, the present invention provides a cylinder, a hollow outer piston slidably housed within the cylinder, and a hollow outer piston slidably housed within the outer piston that slides one end of each of the outer piston and the cylinder. an inner piston having a piston rod fixed thereto, the cylinder penetrating the cylinder in a freely movable manner;
A first fluid boat for displacing the outer piston by a total maximum amount toward the piston rod side; and a first fluid boat communicating with the hollow portion of the outer 1u11 piston to displace the inner piston by the maximum amount toward the piston rod within the outer piston. The external port of the second body is connected to the central part of the outer piston.
a third fluid boat for displacing the fML front histoon by the maximum amount to the side opposite the piston rod within the outer II piston; and a fourth fluid boat for large-scale displacement, and the piston rod is configured to be able to be set at three predetermined positions by relative displacement between the outer piston and the inner screw. It is characterized by this.

The present invention will be explained below based on embodiments shown in the drawings. The double piston cylinder device 1 according to the present invention has a cylinder 2
, an outer piston 3, and an inner piston 4.

The cylinder 2 is made of a sakaki structure, and the left end 2a of the mouth is sealed with a lid 5 and a thin bamboo is fixed with a bolt 8 through a sealing member 6, and the right end 2b of the figure is a one-piece structure. A boss portion 2C is formed through which the piston rod 9 fixed to the piston 4 on the same side slides through the seal wing 10. The cylinder 2 also includes a first flow holder P for displacing the outer piston 4 toward the most variola histone rod 9 side, and a hollow portion 3 of the outer piston 3.
a, to displace the inner ring piston 4 by the maximum amount toward the piston rod 9 within the outer piston 3; The fluid boat P of suit 3 is for maximally positioning the outer piston 3 on the opposite side of the piston rod 9, and the outer piston 3 is maximally positioned on the opposite side of the piston rod 9! It is equipped with a north 4 fluid boat 1'4 for displacement. Each of these fluid boats is connected to a fluid supply source (not shown) such as air or oil through a spool control valve (not shown).

The outer piston 3 is slidably housed in the cylinder 2 via a seal member 11, is formed hollow, and is attached to a stopper 13 screwed to the left end in the figure via a seal member 12. The left end 3b is sealed, and the right end 3C is formed with a boss portion 3d through which the piston rod 9 is slidably inserted via a seal member 14. Also, in the upper part of the figure, there is a $3e that connects the second fluid boat P and the hollow part 3a.
A diagram of a communication hole 3f that communicates with the groove and the hollow portion 3a on the left side of the inner piston 4 in the figure, a 1113g that communicates the third fluid boat P3 with the hollow portion 3a, and the groove and the inner piston 4. A communication hole 3h communicating with the hollow part 3a on the right side of the center is provided. It can slide left and right within the cylinder 2 within the range of stroke t.

The inner piston 4 can slide left and right in the hollow portion 3a of the outer piston 3 within a stroke 4 via a seal member 15, and a piston rod 9 is fixed to the right side.

The piston rod 9 can be set at three predetermined positions by relative displacement between the outer piston 3 and the inner piston 4.

The present invention is constructed as described above, and its operation will be explained below. The case where the tin piston rod 9 is set to the leftmost position will be explained with reference to FIG. When the fluid flows into the fourth fluid boat P4 as shown by arrow A3, the outer piston 3 is displaced to the leftmost position and stops.
When fluid is introduced from the third fluid boat P3 as shown in FIG.
Since the driftwood drifts in a, the inner piston 4 is displaced to the left until it hits the stopper 13, and as a result, both the outer piston 3 and the inner piston 4 are displaced to the leftmost end and stop, and the piston rod 9 is Set to the leftmost position.

Next, the case where the piston rod 9 is set at the intermediate position [M] will be explained with reference to FIG. When fluid is caused to flow into the fourth fluid port P4 as shown by the arrow mark A2 to displace the outer piston 3 to the leftmost position, and when fluid is caused to flow into the second fluid port P2 as shown by the arrow A2, the fluid is g3e, and flows into the hollow portion 3a through the communication hole 3f, so the inner piston 4 is displaced to the right within the stroke t2 and stops. As a result, the piston rod 9 moves to the right by the stroke t from the state shown in FIG. 1 and is set at the intermediate position M.

Next, the case where the piston rod 9 is set to the rightmost position R will be explained with reference to FIG. As shown by arrow A1,
When fluid is allowed to flow into the first fluid port P1, the outer piston 3 is displaced to the right within the range of stroke ← t, stops at the rightmost position, and the second fluid flows as shown by arrow A2. When fluid flows in from port P2,
The fluid passes through the groove 3e and the steam communication hole 3f into the hollow.

It flows into the portion 3a, and the inner piston 4 is displaced to the right within a stroke t2 and stops. As a result, the piston rod 9 is further displaced to the right by the stroke tI from the state shown in FIG. 2, and is set at the rightmost position R.

As described above, according to the present invention, the piston rod 9 is moved to the three-point position fL only by controlling the inflow of fluid.

M and RK are definitely set.

Since the present invention is constructed and operated as described above, by accommodating the double piston in the cylinder so that it can be relatively displaced, the piston rod can be reliably set at the three-point position with a simple construction. This cylinder device can be applied to, for example, shift Φ selection of a power shift transmission and a wide range of other uses, and extremely excellent effects can be obtained.

[Brief explanation of the drawing]

The drawings relate to embodiments of the present invention; FIG. 1 is a longitudinal sectional view of a double piston cylinder device with the piston rod set at the leftmost position, and FIG. 2 is a longitudinal sectional view of the double piston cylinder device with the piston rod set at the intermediate position. Fig. 3 is a longitudinal sectional view showing the case where the piston rod is set at the rightmost position. l is a double piston cylinder device, 2 is a cylinder, 2C
is the right end of one end of the cylinder, 3 is the outer piston, 3a
is the hollow part, 3d is the right end which is one end of the outer piston, 4 is the inner piston, 9 is the piston rod, L is the leftmost position,
M is the middle position, R is the rightmost position, Pl is the first fluid port, P2 is the second fluid port, P3 is the third fluid port, and P4 is the fourth fluid port. Patent applicant Hino Motors Co., Ltd. Agent Patent attorney 1) Kazuo

Claims (1)

[Claims] a cylinder, a hollow outer piston slidably housed within the cylinder, and a piston rod slidably housed within the outer piston and slidably extending through one end of each of the outer piston and the cylinder; an inner piston to which the outer piston 1t is fixed;
A first fluid boat for displacing the piston to the piston rod side communicates with the hollow part of the outer piston to displace the (c) side piston by the maximum amount to the piston rod side within the outer piston. a second fluid boat for displacing the inner piston by a maximum amount within the outer piston opposite the piston rod; a fourth fluid boat for displacing the piston by a maximum amount to a side opposite to the piston rod, and the piston rod can be set at a predetermined three-point position by relative displacement between the outer piston and the inner piston. A double piston cylinder device characterized in that it is configured as follows.