JPS6133261A - Apparatus for ejecting viscous fluid - Google Patents

Abstract

PURPOSE:To stop surely the ejection of a viscous agent without degassing by cutting off the supply of a pressurized gas when the ejection of the viscous agent is stopped, and closing an ejection control valve at the port of a cylinder filled with the viscous agent. CONSTITUTION:A valve lever 31 is slid to the left by pulling an operating lever 33 in the direction as shown by the arrow against a compression spring 65. Consequently, a communicating port 29 communicates with a flow passage 27, and a compressed gaseous carbon dioxide flows into a gas chamber 43 to press the bottom surface of a cylinder P filled with a viscous agent. A valve body 55 of an ejection member 47 is simultaneously pushed up through a push-pull cable 67, and a closed elastic tube 54 is opened. Consequently, the viscous agent filled in the cylinder P is ejected from a nozzle 49. Meanwhile, when the ejection of the viscous agent is stopped, the pulled operating lever 33 is released. Consequently, the supply of gas is cut off, and the valve body 55 at the filling port is closed. Accordingly, the ejection of the viscous agent is surely stopped even when there is residual pressure.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a dispensing device for supplying a viscous agent such as a sealant using pressurized gas.

[Prior art]

In this type of dispensing device that supplies the viscous agent using pressurized gas, even if the pressurized gas is shut off to stop the supply of the viscous agent, the viscous agent filling cylinder is pressurized by the residual pressure in the gas chamber. As a result of the pressure, the viscous agent is poured out.

For this reason, in conventional dispensing devices in which pressurized gas is supplied by a compressor, the pressurized gas is removed to prevent such dispensing of the viscous agent.

However, for dispensing devices that use pressurized gas cylinders, if the pressurized gas is removed in this way, the gas is limited, so the amount of gas used increases, and the gas cylinder must be replaced frequently. This caused the inconvenience of not having to do so.

[Purpose of the invention]

This invention was made based on this situation, and its purpose is to improve the viscosity so that the viscous agent does not pour out from the viscous agent filling cylinder even without venting the gas after the pressurized gas is shut off. An object of the present invention is to provide a drug dispensing device.

[Structure of the invention]

This purpose is to provide a gas chamber into which a cylinder filled with a viscous agent is inserted, a pressurized gas source, and a flow path connecting the pressurized gas source and the gas chamber via an on-off valve. In a viscous agent dispensing device, the viscous agent is poured out by opening a valve to send pressurized gas to the gas chamber and pressurize a viscous agent filling cylinder fitted into the gas chamber. A dispensing control valve is installed at the discharge port of the cylinder to control dispensing of the viscous agent.
This was achieved by linking the pouring control valve with the on-off valve and opening it only when the on-off valve opens.

[Description of the first embodiment]

A first embodiment of the present invention will be described below based on FIG.

In the figure, 11 is the base of the viscous agent dispensing device, 13 is a gripping tube screwed to this base 11, and 15 is this gripping tube 1.
This is a screw lid that covers the opening in number 3.

17 is an opening mechanism, and 19 is a pressure reducing valve, which are installed inside the grip cylinder 13. The unsealing mechanism 17 is for opening the carbon dioxide gas cylinder 21 housed in the grip tube 13, and the pressure reducing valve 19 is for gradually reducing the pressure of the pressurized carbon dioxide gas flowing out from the carbon dioxide gas cylinder 21.

23 is a cylindrical valve chamber, and the grip cylinder 13 at the base 11
It is perforated at the top. This valve chamber 23 communicates with a gas chamber 43 (described later) via a flow path 27 passing through a check valve 25, and also communicates with the secondary side of the pressure reducing valve 19 via a communication hole 29. Reference numeral 31 denotes a valve rod, which is fitted into the valve chamber 23 so as to be movable forward and backward. The valve rod 31 is moved forward and backward by the operation of the operating lever 33, thereby communicating with or blocking the passage 27 and the communication hole 29. This valve chamber 23 and valve rod 3
1 constitutes an on-off valve of the present invention, and the check valve 2
Reference numeral 5 is integrated with an exhaust valve 35, and by pushing a knob 39 against a compression spring 37, the pressurized gas in the gas chamber 43 is exhausted.

Next, 41 is a cylindrical fitting recess, which is formed in the upper part of the base 11. This cylinder fitting recess 41 is for fitting and inserting the viscous agent filling cylinder P. The fork 43 is a gas chamber, which is formed at the rear of the cylindrical fitting recess 41. This gas chamber 43
has an opening 43a on the cylindrical fitting recess 41 side, and this opening 4
The inner edge of 3a serves as a fitting seat for the viscous agent filling cylinder P. The viscous agent filling cylinder P fits into this fitting seat without any gap, and the gas chamber 4
3 is a closed space.

On the other hand, 45 is a seat having a notch, and the cylindrical fitting insertion recess 4
1 is integrally formed with the base 11 on the front side. The tip of the viscous agent filling cylinder P fitted into the cylinder fitting recess 41 comes into contact with this seat 45 .

Reference numeral 47 denotes a pouring member, which has a nozzle 49 at its tip and a fitting opening 51 at its rear end. The fitting opening 51 of this pouring member 47 has
The tip of the viscous agent-filled WIP is fitted through the elastic tube 54 made of rubber. This pouring member 47 is a viscous agent filling cylinder P.
In the fitted state, the catch seat 45 is hung. 5
3 is a valve box, which is formed between the nozzle 49 of the spouting member 47 and the fitting opening 51. The valve box 53 has a cylindrical shape and has a rod-shaped valve body 55 that can move forward and backward. 57 is a window, which is formed in the valve body 55. This window 57 has an elastic tube 54 fitted into the viscous agent filling cylinder P.
is inserted. 59 is a moving pin, and the rack is passed through this window 57.

Therefore, this moving pin 59 moves up and down as the valve body 55 moves forward and backward. The fork 61 is a long hole, which is bored in the valve body 55. This elongated hole 61 is connected to a fixing pin 6 mounted on the valve body 53.
It is a rounded one that fits into the number 3. In addition, this fixed bin 6
The elastic tube 54 is fitted between the movable pin 59 and the movable pin 59. A compression spring 65 is installed inside the valve box 53 and presses the valve body 55 downward. For this reason,
Communication between the elastic tube 54 and the fixed bottle 63 and the movable pin 59 is cut off.

The valve box 53 and the valve body 55 correspond to the pouring control valve r in this invention.Next, 67 is a push-pull cable that connects the valve body 55 and the valve rod 31. . Therefore, when the valve rod 31 slides to the left due to the operation of the operating lever 33, the valve body 5
5 is pushed upward against the compression spring 65, and
When the operation lever 33 is deactivated, the valve body 55 is pushed downward by the elastic force of the compression spring 65, so that the valve rod 31 slides to the right.

[Operation of the first embodiment]

Pull the operating lever 33 in the direction of the arrow against the compression spring 65 (
Then, the valve rod 31 slides to the left. Then, the communication hole 29 and the flow path 27 communicate with each other, and the pressurized carbon dioxide gas flows into the gas chamber 43 and presses the bottom surface of the viscous agent filling cylinder P.

At the same time, the spouting member 4 is connected via the bush pull cable 67.
The valve body 55 of No. 7 was pushed up and the elastic tube 5 which had been closed
4 is in communication, the viscous agent in the viscous agent filling cylinder P is connected to nozzle 4.
It is poured from 9.

To stop dispensing the viscous agent, it is sufficient to release the pull on the operating lever 33. Then, the valve body 55 is compressed by the compression spring 6
Since the elastic tube 54 is pushed downward by the elastic force of the elastic tube 54, communication with the elastic tube 54 is again interrupted by the movable pin 59 and the fixed pin 63. At the same time, the valve rod 31 slides to the right via the push-pull cable 67 to connect the communication hole 29 and the flow path 2.
7, a pressurized carbon dioxide gas chamber 43 is installed.
supply will be stopped.

[Description of second embodiment]

FIG. 2 shows a second embodiment of the present invention, in which the pouring control valve is also opened by pressurized carbon dioxide gas.

In the figure, 71 is a support member, which is fixed to the base 11. This support member 71 has a cylinder portion 73. A piston 75 is fitted into the cylinder portion 73 to move the valve body 55 up and down.

77 is a deep hole having a return spring 78, and a support member 71
It is drilled in. This deep hole 77 communicates with the cylinder portion 73 through a flow path 79, and has a through hole 8 at the bottom.
1. Reference numeral 83 denotes a pipe valve, and both ends thereof are fitted into the deep hole 77 and the valve chamber 23 so as to be movable forward and backward. This pipe valve 83 has openings 87 and 89 at both ends, and the opening 87 is for connecting to the secondary side of the pressure reducing valve 19 through the communication hole 91, and the opening 89 is for connecting to the flow path 79. It's about connecting. Note that 93 is a return spring for the pipe valve 83 and is installed in the deep hole 77. Moreover, in this embodiment, the elastic tube 54 is not used as in the first embodiment.

Therefore, when the operating lever 33 is pulled in the direction of the arrow against the return spring 78, the valve pipe 83 slides to the left.

Then, the communication hole 29 and the flow path 27 communicate with each other, the communication hole 91 communicates with the opening 87 of the pipe valve 83, and the flow path 79 communicates with the opening 89, so pressurized carbon dioxide gas flows into the gas chamber 43. While pressing the bottom of the viscous agent filling cylinder P, the piston 7
5 pushes up the valve body 55 of the pouring member 47 against the compression spring 65, and opens the closed valve body 55. As a result, the viscous agent in the viscous agent filling cylinder P is poured out from the nozzle 49.

To stop dispensing the viscous agent, it is sufficient to release the pull on the operating lever 33. Then, the pipe valve 83 returns to the spring 78.
Because it slides in the right direction due to the elastic force of At the same time, the inside of the cylinder portion 73 communicates with the atmosphere via a flow path 79, a deep hole 77, and a through hole 81. As a result,
Thereafter, the viscous agent filling cylinder is not pressurized again, and the valve body 55 is closed by the compression spring 65.

〔Effect of the invention〕

A viscous agent dispensing device according to the present invention includes a gas chamber into which a viscous agent filling cylinder is inserted, a pressurized gas source, and a flow path that connects the pressurized gas source and the gas chamber via an on-off valve. A viscous agent dispensing device comprising: opening the on-off valve to send pressurized gas to the gas chamber and pressurizing a viscous agent filling tube fitted into the gas chamber to pour out the viscous agent; A dispensing control valve for controlling dispensing of the viscous agent is provided at the discharge port of the viscous agent filling cylinder, and the dispensing control valve is linked to the on-off valve to open only when the on-off valve opens. It is.

That is, in this viscous agent dispensing device, when stopping the viscous agent dispensing, the supply of pressurized gas is cut off and the dispensing control valve installed at the filling port of the viscous agent filling cylinder is closed. In order to
Even if the viscosity agent filling cylinder is pressurized by residual pressure, the viscosity agent will not be poured out from the filling port of the viscosity agent filling cylinder.

Therefore, there is no need to vent gas as in conventional pouring devices, so there is no waste in the amount of gas used.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a first embodiment of a viscous agent dispensing device according to the present invention, and FIG. 2 is a sectional view of a second embodiment of the same. P... Viscous agent filling cylinder 43... Gas chamber 21... Pressurized gas source (carbon dioxide cylinder) 23.
31...Opening/closing valve (23...valve chamber, 31...valve rod)
27... Flow path 53, 55... Output control valve (53... valve box, 55... valve body) Patent applicant Asahi Malleable Iron Co., Ltd. 1-- ・

Claims (2)

[Claims] (1) A gas chamber into which a viscous agent filling cylinder is inserted, a pressurized gas source, and a flow path connecting the pressurized gas source and the gas chamber via an on-off valve, and the on-off valve is opened. In a viscous agent dispensing device that dispenses a viscous agent by sending pressurized gas to the gas chamber and pressurizing a viscous agent-filled cylinder fitted into the gas chamber, the discharge port of the viscous agent-filled cylinder is provided. A viscous agent dispensing device is provided with a dispensing control valve for controlling dispensing of the viscous agent, and the dispensing control valve is linked to the opening/closing valve to open only when the opening/closing valve is opened. (2) The viscous agent dispensing device according to claim 1, wherein the pressurized gas is pressurized carbon dioxide gas.