JPH0637271Y2 - Pilot steam trap - Google Patents

Description

[Detailed Description of the Invention] Industrial field of application The present invention relates to a steam trap for automatically discharging condensate generated in a steam piping system, and particularly to a pressure detected by detecting the liquid level on the inlet side by a pilot float valve. The present invention relates to a pilot-type steam trap that drives a response valve.

2. Description of the Related Art A pilot-type steam trap of this type has a pressure chamber partially formed by a pressure receiving displacement wall of a pressure responsive valve, a first orifice for communicating the pressure chamber with an inlet side, and a pressure chamber for communicating with the outlet side. And a pilot float valve that opens and closes the first orifice according to the liquid level on the inlet side to introduce condensed water into the pressure chamber to control the pressure and drive the pressure responsive valve. An example of this is shown in JP-A-55-112490.

Problems to be Solved by the Invention In this case, the pressure responsive valve opens abruptly due to the pressure increase in the pressure chamber due to the opening of the pilot float valve, which causes a problem of water hammer.

Therefore, the technical problem of the present invention is to prevent the pressure responsive valve from opening suddenly.

Means for Solving the Problems The technical means of the present invention taken to solve the above technical problems include a pressure chamber partially formed by a pressure receiving displacement wall of a pressure responsive valve, and a pressure chamber on the inlet side. A first orifice communicating with the first orifice, a second orifice communicating the pressure chamber with the outlet side, and a first orifice
In the one equipped with a pilot float valve that opens and closes the orifice according to the liquid level on the inlet side and introduces condensate into the pressure chamber to control the pressure and drive the pressure response valve, It is connected so that the buoyancy of the float acts on the pressure responsive valve as a force in the valve closing direction.

Action The action of the above technical means is as follows.

When the amount of condensed water flowing from the inlet is very small or not present, the pilot float valve closes the first orifice and the pressure in the pressure chamber is equalized through the second orifice, so the pressure responsive valve is closed. The pilot float valve opens the first orifice when a large amount of condensate flows in from the inlet.
The pressure in the pressure chamber rises and the pressure responsive valve opens. When this pressure-responsive valve opens, the buoyancy acting on the float arranged in the pressure chamber gradually increases due to the condensate introduced into the pressure chamber from the first orifice, so the buoyancy of the float closes in the pressure-responsive valve. Acts in the direction. Due to the buoyancy of the float, the pressure responsive valve can descend gently, and the water hammer will not occur.

Example An example showing a specific example of the above technical means will be described (see FIG. 1).

The lid members 2 and 3 are fastened to the main body 1 with bolts to form a trap casing. The interior of the trap casing is a partition wall 4, which is separated into a condensate reservoir chamber 6 communicating with an inlet 5 and a pressure response valve accommodating chamber 8 communicating with an outlet 7. The inlet 5 opens at the upper part of the condensate pool chamber 6 and communicates with it via a screen 9. An outlet 7 is formed on the same axis as the inlet 5.

A spherical pilot float 10 is accommodated in the condensate chamber 6 in a free state, and the pilot float 10 is contained in the condensate chamber 6.
It floats and descends according to the liquid level, and is separated from and seated on the valve seat member 11 screwed to the partition wall 4 at the bottom of the condensate reservoir chamber 6. The valve seat member 11 forms an opening on the condensate reservoir chamber side of the first orifice 13 that connects the condensate reservoir chamber 6 to the pressure chamber 12 described below.

The cylinder member 14 and the cylinder member in the pressure response valve accommodation chamber 8
A piston member 15 slidably arranged in 14 is arranged. The space between the upper surface of the piston member 15 and the lid 3 is the pressure chamber 12
To make. A second orifice 16 is formed in the piston member 15 to connect the pressure chamber 12 to the outlet 7.

The main valve body 18 is fixed to the lower end of the piston member 15 with a nut 19. The main valve body 18 is interlocked with the piston member 15 and the condensed water chamber 6
The valve port 20 communicating with the outlet 7 is opened and closed. The valve port 20 is formed at the lower end of the cylinder member 14. The main valve body 18 is biased by a spring 21 toward the valve opening 20. The cylinder member 14 has an opening 22 for allowing the liquid flowing out from the valve port 20 to flow to the outlet 7.
Has been opened. The piston member 15 and the main valve body 18 form a pressure responsive valve.

A float 23 is arranged in the pressure chamber 12. The float 23 is fixed to the piston member 15 via a connecting rod 24.

The operation of the above embodiment is as follows.

When the amount of condensed water flowing from the inlet 5 is very small or not, the pilot float 10 descends to block the first orifice 13,
Since the pressure in the pressure chamber 12 is equalized through the second orifice 16, the piston member 15 closes the valve port 20 by the inlet side pressure acting on the main valve body 18 and the elastic force of the spring 21. Next, when a large amount of condensate flows in from the inlet 5, the pilot float 10 floats as the liquid level in the condensate reservoir chamber 6 rises and opens the first orifice 13. The pressure in the pressure chamber 12 rises to push down the piston member 15, the main valve body 18 opens the valve opening 20, and the condensed water from the inlet 5 is discharged to the outlet 7. At the time of this valve opening, that is, when the piston member 15 is pushed down, the buoyancy acting on the float 23 arranged in the pressure chamber 12 gradually increases due to the condensed water introduced into the pressure chamber 12 from the first orifice 13, so that the piston member The buoyancy of the float 23 acts on 15 in the direction of lifting the piston member 15. Due to the buoyant force acting on the float 23, the piston member 15 can gently descend, and the water hammer will not occur.

Effect of the Invention The present invention has the following unique effects. As described above, according to the present invention, since the float is connected to the pressure responsive valve so that the pressure responsive valve does not open suddenly, water hammer does not occur. Therefore, the trap, the piping before and after the trap, and the equipment using steam are not damaged or disabled.

[Brief description of drawings]

FIG. 1 is a sectional view of a pilot type steam trap according to an embodiment of the present invention. 1: Main body 5: Inlet 6: Condensate chamber 7: Outlet 10: Pilot float 12: Pressure chamber 13: First orifice 15: Piston member 16: Second orifice 23: Float

Claims (1)

[Scope of utility model registration request] 1. A pressure chamber, a part of which is formed by a pressure receiving displacement wall of a pressure responsive valve, a first orifice for communicating the pressure chamber with an inlet side, a second orifice for communicating the pressure chamber with an outlet side, 1
In the one equipped with a pilot float valve that opens and closes the orifice according to the liquid level on the inlet side and introduces condensate into the pressure chamber to control the pressure and drive the pressure response valve, Pilot type steam trap that is connected so that the buoyancy of the float acts on the pressure-responsive valve as a force in the valve closing direction.