JPH0244066Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a pressure increase device that increases and outputs fluid pressure.

[Prior Art] Conventionally, pistons in a pair of cylinders connected through a partition wall are connected by a rod passing through the partition wall, and pressurized air is supplied to each drive chamber formed on the outside of each piston through a switching valve. By alternately supplying and discharging these pistons,
A pressure increase device that increases the pressure of air in a pressure increase chamber formed inside a piston and outputs it, and also switches a switching valve by the reciprocating movement of the piston, is disclosed in, for example, Japanese Utility Model Application Publication No. 144203/1983. It is well known.

The above-mentioned known pressure increase device relies on the biasing force of a spring provided in the push rod to maintain the switching valve mechanism in the switching position against the secondary pressure in the pressure increase chamber, so it is used at high pressure. In a pressure increase device that does this, it is necessary to increase the biasing force of the spring in accordance with the pressure. However, a strong spring requires a large installation space, resulting in an increase in the size of the switching valve mechanism and problems such as unreasonable durability.

[Problems to be Solved by the Invention] The present invention uses fluid pressure to maintain the switching valve mechanism in the switching position without relying on the biasing force of the spring. The problem to be solved is to reduce the size of the switching valve mechanism by eliminating the need for the switching valve mechanism, and at the same time improve its durability.

[Means for Solving the Problems] As a means for solving the above problems, the present invention includes a partition wall having an inlet port and an exit port, and a pair of cylinders sandwiching the partition wall,
The pistons reciprocating within these cylinders are connected to each other by rods that penetrate the partition wall in an airtight manner, and the partition wall only allows fluid to flow from the inlet port into each pressure increasing chamber inside both pistons. An inlet check valve, an outlet check valve that only allows fluid to flow from each of the pressure increase chambers to the outlet port, and a switching valve that switches each drive chamber on the outside of both pistons to the inlet port and the exhaust port for communication. The push rod for switching the switching valve is configured as an integral piece with an end protruding into each pressure intensifying chamber, and a push rod between the switching valve and the pressure intensifying chamber is provided at the end of the push rod. A detent piston is slidably inserted into the detent piston, which airtightly penetrates the detent piston and supports the pushrod by fluid pressure acting on an enlarged diameter portion formed on the pressure intensifying chamber side.

[Function] A pushing force due to the pressure difference between the secondary pressure and the primary pressure acts on the push rod protruding into each pressure intensifying chamber, but the pressure acting on the enlarged diameter portion of the detent piston in the primary pressure intensifying chamber is Since the force supports the push rod against the pressing force due to the differential pressure, the push rod and switching valve maintain the switching position. In this case, since the detent piston in the pressure boosting chamber on the secondary pressure side is pressed by the push rod guide, no pressing force is generated to press the push rod into the pressure boosting chamber on the primary side.

Therefore, the switching valve mechanism self-maintains the switching position without using a spring.

When the piston presses the push rod and the detent piston in the primary pressure boosting chamber near the end of the stroke, the switching valve switches and the supply and discharge of air to the drive chamber is reversed, so the piston slides in the opposite direction.

When the piston reverses, the detent piston returns to its original position where it is pressed against the push rod guide due to the fluid pressure acting on the pressure increase chamber, but the push rod and switching valve maintain their positions. .

[Example] First, the outline of the pressure increasing device of the present invention will be explained with reference to FIG.

In the pressure booster schematically shown in FIG. 3, the pressure booster main body 1 includes an inlet port 2 and an outlet port 3, and when factory line air, etc. is supplied to the inlet port 2, the line air is pressurized. and output from exit port 3.

The pressure booster main body 1 includes a pair of cylinders 5a and 5b that are connected to each other via a partition wall 4. Pistons 6a and 6b in each cylinder 5a and 5b are connected by a rod 7, and the rod 7 is connected to the partition wall 4. It is slidably installed in the axial direction in an airtight manner.

Each cylinder 5a, 5b has a piston 6a, 6b
The inlet port 2 is increased via a pair of inlet check valves 11a, 11b disposed in the partition wall 4. Pressure chamber 9a,
9b to allow line air to flow into the pressure intensification chambers 9a, 9b from the inlet port 2 and prevent its reverse flow, and also to connect the pressure intensification chambers 9a, 9b to
A pair of outlet check valves 12 disposed within the bulkhead 4
a, 12b to communicate with the outlet port 3, allowing the compressed and pressurized air in the pressure increase chambers 9a, 9b to flow out to the outlet port 3, and preventing its backflow.

A switching valve 13 for reciprocating the piston is provided within the partition wall 4 of the pressure booster main body. In order to provide this switching valve 13, a through hole 20 with an enlarged diameter at both ends is formed in the partition wall 4, as shown in FIG. Back pressure sleeves 22a, 22b
It is fixed by being sandwiched between a pair of side plates 24a, 24b via push rod guides 23a, 23b fitted into the enlarged diameter portion.

The hollow flow path switching spool 25, which is slidably inserted into the sleeve 21, has a through hole 27 therein whose diameter is enlarged at both ends by engagement steps 26a and 26b. Pushrod 28
is slidably inserted.

The sleeve 21 has a pressure regulating valve 15 in the center.
A valve input port 30 that communicates with the inlet port 2 via a drive chamber 10 is provided on each side of the valve input port 30 (see FIG. 3).
It has valve output ports 31a, 31b that communicate with valve output ports 31a, 10b, and push rod guides 23a, 31b on both sides thereof.
Valve exhaust ports 32a and 32b are provided in 23b.

Note that in FIG. 3, the pressure regulating valve 15 and the like are shown separately from the pressure intensifier main body 1 in order to facilitate understanding of the flow path, but the pressure regulating valve 15 and ports 2 and 3 are in communication with each other. flow path and switching valve 13 and drive chamber 1
All of them can be provided in the pressure booster main body 1, including the flow path that communicates them.

The spool 25 has lands 33a and 33b that switch and communicate the valve output ports 31a and 31b with the valve input port 30 and the valve exhaust ports 32a and 32b, and the exhaust gas is temporarily disposed between the lands and the back pressure sleeves 22a and 22b. It is configured to form back pressure chambers 34a and 34b in which back pressure is stored.

The push rod 28 has engaging protrusions 36a, 36b that engage with the engaging step portions 26a, 26b by opposing enlarged portions provided in the middle, and abutting portions 37a, 36b by small diameter portions at both ends. 37b, respectively, and the detent pistons 40a and 40b, which are slidably fitted into the small diameter portions, pass through the push rod guides 23a and 23b airtightly to form an enlarged diameter portion 41a at the tip. , 41b into the pressure intensifying chamber 9
The enlarged diameter portions 41a, 41b are guided by bushes 42a, 42b fitted to the push rod guides 23a, 23b, and are closed to the pressure intensifying chamber 9a by retaining rings 43a, 43b. , 9b is prevented, and the tip end face on the switching valve side faces the contact portions 37a, 37b of the push rod 28.

The axial cross-sectional area _A1 of the detent pistons 40a, 40b is larger than the axial cross-sectional area A of the small diameter portion of the push rod 28, which is higher than the secondary pressure _P2 and the primary pressure _P1.
The pressure increase ratio n is at least (n-1) times larger than the pressure increase ratio n.

Next, the operation of the above embodiment will be explained.

In FIG. 1, the spool 25 has a valve input port 30, a valve output port 31a, a valve output port 31b, and a valve exhaust port 32.
The valve output port 31 is located at a switching position that communicates with
The figure shows a state in which primary air is supplied from the drive chamber 10a to the drive chamber 10a, the drive chamber 10b is communicated with the atmosphere, and the piston 6a is moving to the left in the figure.

In this case, the acting force P ₂ A ₁ due to the secondary pressure P ₂ acts on the detent piston 40a on the pressure intensification chamber 9a side, and the detent piston 4 on the pressure intensification chamber 9b side acts on the detent piston 40a.
Since the acting force P ₁ A ₁ due to the primary pressure P ₁ is acting on the detent piston 0b, both the detent pistons 40a and 40b are pressed against the push rod guides 23a and 23b, while the push rod 28 is The contact portion 37b moves to the left in the figure due to the differential pressure between the pressure and the primary pressure, and is supported by contacting the detent piston 40b.

In this state, there is a force acting on the pressure boosting chamber 9a side.
Although P ₂ A acts on the pressure intensifying chamber 9b side, the acting force P ₁ (A+A ₁ ) is in the relationship of P ₂ = nP ₁ , A ₁ ≧ A (n-1), so the pressure rod 28 and The spool 25 that is switched thereby maintains the state shown.

In this case, the acting force of the detent piston 40a does not act on the push rod 28 because it presses the push rod guide 23a.

When the piston 6a presses the push rod 28 near the end of its stroke, the push rod and the detent piston 40b on the pressure increasing chamber 9b side move to the left in the figure, and the engagement protrusion 36a and the engagement step 2 move to the left.
6a causes the spool 25 to move to the left and switch to a position where the valve output port 31a and the valve exhaust port 32a are slightly in communication, and the pressurized air in the drive chamber 10a passes through the valve output port 31a. It flows into the back pressure chamber 34a. As a result, the fluid pressure in the back pressure chamber 34a increases, and the hollow and lightweight spool 25 is suddenly slid to the left by this fluid pressure, causing the valve input port 30 and the valve output port 31b to and switches to the switching position where the valve output port 31a and the valve exhaust port 32a communicate with each other (second position).
(see figure). Therefore, even when the piston is moving at a low speed, such as immediately after startup, the switching valve 13 is reliably switched.

By switching the switching valve 13, the piston is reversed to increase the pressure of the air in the pressure intensification chamber 9b and primary air is supplied to the pressure intensification chamber 9a, so that the detent piston 40b returns to its original position and the push rod 2
8 return to the neutral position shown in FIG. 1, but the spool 25 maintains the switching position.

The movements of the push rod 28, the detent pistons 40a, 40b, and the spool 25 during the rightward stroke of the piston and at the end of the stroke are the same as described above, and detailed explanations thereof will be omitted.

[Effects of the invention] According to the invention, the switching valve is held at the switching position by supporting the acting force due to the fluid pressure acting on the push rod with the detent piston slidably inserted into the push rod. Since no spring is required to maintain the switching position, the installation space for the spring is no longer required, and the switching valve mechanism can be downsized.

Further, since the position of the switching valve is held by the detent piston, the durability of the switching valve mechanism can be improved compared to the case where the switching valve is held by the biasing force of a spring.

[Brief explanation of the drawing]

1 and 2 are longitudinal sectional front views of essential parts of an embodiment of the present invention, and FIG. 3 is a schematic explanatory diagram showing an outline of the embodiment of the present invention. 2...Inlet port, 3...Outlet port, 4...
Partition wall, 5a, 5b... Cylinder, 6a, 6b...
Piston, 7... Rod, 9a, 9b... Pressure increase chamber, 10a, 10b... Drive chamber, 11a, 11b
...Inlet check valve, 12a, 12b...Outlet check valve, 13...Switching valve, 25...Spool,
28... Push rod, 40a, 40b... Detent piston, 41a, 41b... Expanded diameter portion.

Claims (1)

[Claims for Utility Model Registration] A partition wall having an inlet port and an outlet port, and a pair of cylinders sandwiching the partition wall, and pistons reciprocating within the cylinders are connected to each other by a rod that penetrates the partition wall in an airtight manner. An inlet check valve is connected to the partition wall and allows fluid to flow only from the inlet port to each pressure increasing chamber inside both pistons, and an inlet check valve that only allows fluid to flow from each pressure increasing chamber to the outlet port. In a device equipped with an outlet check valve and a switching valve that switches each drive chamber on the outside of both pistons to an inlet port and an exhaust port for communication, a push rod for switching is attached to the switching valve, and the end is connected to each pressure increasing chamber. At the end of the push rod, the push rod guide airtightly passes through the switching valve and the pressure intensifying chamber, and acts on an enlarged diameter portion formed on the pressure intensifying chamber side. 1. A pressure increase device comprising: a detent piston slidably inserted therein to support the push rod with fluid pressure.