As a hobby, I've been working on valve designs for airguns, and I wanted to get some feedback on it. My idea is very similar to a striker activated blow open valve (a rough drawing of a blow open striker valve that I found online can be seen here.)
The striker is the C-shaped component, and whit it is set it pushes the valve closed. The valve has a slightly larger diameter than the rod, so the air pressure helps keep the valve shut. To open it, the striker is released, The striker hits the collar at the end of the piston, and that forces the valve to open. Once the valve is opened, the air pressure assists the valve to open further.
My idea is to eliminate the striker by making the rod with a slightly larger diameter than the valve. I have a very rough drawing of my idea here.
The cylinder that seals the valve by nesting in the exhaust port (1) has a smaller radius (small) than the cylinder (large) that is nested in the return guide (3). The pressure below the piston inside the return guide could be adjusted to help control the opening and closing of the valve. When the piston is closed, the net force attempting to open the valve is small because it is equal to the pressure multiplied by 3.14(r large^2 - r small^2). The fluid in the container (4) can not escape through the exhaust port (1) or the return guide (3) by adjusting the ratios between the large piston and the small piston, you can control how much net force is acting on the piston prior to opening it. Since the force acting on the valve can be controlled, a mechanical lock or a solenoid could keep the piston closed even at extremely high pressures.
Once the piston is release, the gas will be able to flow through the exhaust port (11). the force acting to open the valve will also increase because the area that the pressure acts on will change from 3.14 (r large^2 - r small^2) to 3.14 (r large ^2). This increase in force will allow the piston (12) to open rapidly and remain open until the pressure has dropped. The piston can be pressed down against an elastic force that will return the piston to the closed position once the pressure inside the gun has dropped. Here's another rough drawing.
I believe there are three advantages to this design compared to a striker activated blow open valve. The first advantage is it requires fewer pieces. My idea still has the valve, the piston, and it requires a locking mechanism to keep the valve shut when there is a high air pressure, but it does not need the striker or the collar. The second advantage is this should be more compact since it eliminates the need for a striker. the final advantage is that once the pressure has dropped, the valve will return to the closed position.
Thank you so much for taking the time to look at my idea.
JA
MOD EDIT: EMBEDDED PICTURES
The striker is the C-shaped component, and whit it is set it pushes the valve closed. The valve has a slightly larger diameter than the rod, so the air pressure helps keep the valve shut. To open it, the striker is released, The striker hits the collar at the end of the piston, and that forces the valve to open. Once the valve is opened, the air pressure assists the valve to open further.
My idea is to eliminate the striker by making the rod with a slightly larger diameter than the valve. I have a very rough drawing of my idea here.
The cylinder that seals the valve by nesting in the exhaust port (1) has a smaller radius (small) than the cylinder (large) that is nested in the return guide (3). The pressure below the piston inside the return guide could be adjusted to help control the opening and closing of the valve. When the piston is closed, the net force attempting to open the valve is small because it is equal to the pressure multiplied by 3.14(r large^2 - r small^2). The fluid in the container (4) can not escape through the exhaust port (1) or the return guide (3) by adjusting the ratios between the large piston and the small piston, you can control how much net force is acting on the piston prior to opening it. Since the force acting on the valve can be controlled, a mechanical lock or a solenoid could keep the piston closed even at extremely high pressures.
Once the piston is release, the gas will be able to flow through the exhaust port (11). the force acting to open the valve will also increase because the area that the pressure acts on will change from 3.14 (r large^2 - r small^2) to 3.14 (r large ^2). This increase in force will allow the piston (12) to open rapidly and remain open until the pressure has dropped. The piston can be pressed down against an elastic force that will return the piston to the closed position once the pressure inside the gun has dropped. Here's another rough drawing.
I believe there are three advantages to this design compared to a striker activated blow open valve. The first advantage is it requires fewer pieces. My idea still has the valve, the piston, and it requires a locking mechanism to keep the valve shut when there is a high air pressure, but it does not need the striker or the collar. The second advantage is this should be more compact since it eliminates the need for a striker. the final advantage is that once the pressure has dropped, the valve will return to the closed position.
Thank you so much for taking the time to look at my idea.
JA
MOD EDIT: EMBEDDED PICTURES
