JP3341181B2 - Thermo-responsive steam trap - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steam trap for automatically discharging condensate generated in various steam-using equipment and steam pipes, and more particularly to a temperature trap including a medium which is heated and expanded, cooled and contracted. The present invention relates to a heat-responsive steam trap for discharging a fluid having a temperature lower than a desired temperature out of a system by using a control element.

[0002]

2. Description of the Related Art A thermally responsive steam trap using a temperature control element is disclosed, for example, in Japanese Patent Publication No. 60-46318. As understood from the publication, an inlet, a valve chamber, and an outlet are formed by casing, and two upper and lower wall members,
A temperature control element comprising a diaphragm having an outer peripheral edge fixed between both wall members, an expansion medium sealed between the upper wall member and the diaphragm, and a valve member connected to the diaphragm is fixed in the valve chamber, and expanded. The valve member is driven by the displacement of the diaphragm due to the expansion and contraction of the medium to open and close the valve port formed at the valve chamber side opening end of the outlet.

[0003]

When a high-temperature fluid having a predetermined temperature or more flows into the valve chamber, the expansion medium expands, the diaphragm is displaced in the valve closing direction, and the valve member closes the valve port. This prevents the discharge of steam. When a low-temperature fluid having a predetermined temperature or less flows, the expansion medium contracts, the diaphragm is displaced in the valve opening direction, and the valve member opens the valve port. As a result, condensate and air are discharged out of the system.

[0004] However, in such a thermoresponsive steam trap of this type, there was a problem that the valve could not be completely closed and a steam leak occurred. This is because when the diaphragm is displaced in the valve closing direction due to expansion of the expansion medium, the valve surface of the valve member may approach and seat in a non-parallel inclined state with respect to the valve seat surface of the valve port. This is because if the user sits in an inclined state, the state cannot be shifted to a state parallel to the valve seat surface, and it may not be possible to completely adhere to the valve seat surface. Also, repeated seating in this inclined state causes uneven wear to the valve member.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a heat responsive device which is capable of completely closing a valve even when the valve member is seated in an inclined state and preventing uneven wear, thereby preventing steam leakage. The purpose is to provide a formula steam trap.

[0006]

The technical means of the present invention taken to solve the above technical problem is to form an inlet, a valve chamber and an outlet by casing, to form two upper and lower wall members, A temperature control element comprising a diaphragm having an outer peripheral edge fixed between the two wall members, an expansion medium sealed between the upper wall member and the diaphragm, and a valve member connected to the diaphragm is disposed in the valve chamber, and is expanded. In a thermally responsive steam trap that drives a valve member by displacement of a diaphragm due to expansion and contraction of a medium to open and close a valve port formed at an outlet end on a valve chamber side of an outlet,
A swirler which receives rotational force by the discharged fluid is mounted on the lower surface of the lower wall member, and a temperature control element is inclined and rotatably hung on a spring mounted in the valve chamber.

[0007]

The operation of the above technical means is as follows.
The temperature control element is tilted and rotatably hung by the spring, so that even if the valve surface of the valve member is seated in a non-parallel state with respect to the valve seat surface of the valve port, the temperature control element is not tilted. By tilting the whole, the valve surface can be displaced in a state parallel to the valve seat surface. As a result, the valve surface can be completely adhered to the valve seat surface, and the valve can be completely closed.

[0008] Further, since the swirl vane which receives the rotational force by the discharged fluid is mounted on the lower surface of the lower wall member, the temperature control element rotates when the valve member opens the valve port. Therefore, when the valve is closed, the rotational positional relationship of the valve member with respect to the valve seat surface changes every time the seat is seated, and uneven wear does not occur on the valve member.

[0009]

An embodiment showing a specific example of the above technical means will be described (see FIG. 1). An inlet 2 and an outlet 3 are formed on the same axis on the main body 1, and a valve chamber 4 communicating with the inlet 2 and the outlet 3 is connected to the main body 1 by a bolt (not shown).
Formed by A casing is constituted by the main body 1 and the lid member 5, and the airtightness between the two is formed by an annular gasket 6.
Is kept in. A screen 7 is interposed on a passage extending from the inlet 2 to the valve chamber 4 to supplement foreign substances such as dust. Exit 3
A valve seat member 9 having a valve port 8 communicating the valve chamber 4 and the outlet 3 is screwed to the open end of the valve chamber 4 side.

The temperature control element 10 located above the valve seat member 9 includes an upper wall member 12 having an inlet 11 and an inlet 1.
, A spherical plug member 13 that seals the housing 1, a diaphragm 15 that forms a housing chamber 14 between the upper wall member 12,
4, an expansion medium 16 sealed to the diaphragm 15, a valve member 17 fixed to the diaphragm 15 and detached from the valve seat member 9 to open and close the valve port 8, and an outer peripheral edge of the diaphragm 15 is sandwiched between the upper wall member. It comprises a lower wall member 18 to be fixed and a stopper 19 to be fixed to the upper wall member 12. The expansion medium 16
It is formed of water, a liquid having a lower boiling point than water, or a mixture thereof.

A corrugated plate-shaped spring 20 located on the upper wall member 12 has a hole in the center slightly larger than the diameter of the injection port 11 and slightly smaller than the diameter of the plug member 13, and is welded to the injection port 11. The stopper member 13 is loosely locked so as not to come off. As a result, the temperature control element 10 is tiltably and rotatably connected to the spring 20.

The temperature control element 10 and the spring 20 are accommodated in a bottomed cylindrical mounting member 21 fixed between the main body 1 and the valve seat member 9. Upper and lower two snap rings 2 attached to the member 21
2 and 23 are held. The outer diameter of the temperature control element 10 is formed smaller than the inner diameter of the mounting member 21, and a space is provided below the bottom surface of the mounting member 21 and the upper surface of the valve seat member 9. As a result, the temperature control element 10 is made to hang down freely on the spring 20. Also, the lower wall member 18
A swirler 24 is attached to the lower surface of the, so that the temperature control element 10 becomes rotatable when the valve is opened. Swirl wing 24
Are mounted at equal intervals in this embodiment. A condensate passage window 25 is opened below the mounting member 21. In the present embodiment, three are provided at equal intervals.

The operation of this embodiment is as follows. When the fluid temperature in the valve chamber 4 becomes lower than a predetermined value due to heat radiation, or when a low-temperature fluid flows into the valve chamber 4 from the inlet 2,
The expansion medium 16 is contracted, and the valve member 17 is separated from the valve seat member 9 by the application of the fluid pressure at the inlet 2 to open the valve port 8. Thereby, low-temperature condensate and air are discharged from the outlet 3. At the time of opening the valve, the temperature control element 10 is rotating because the swirl vane 24 receives a rotational force by the discharged fluid flowing down the lower surface of the lower wall member 18.

When the temperature of the fluid flowing into the valve chamber 4 rises due to the discharge of the low-temperature fluid, the expansion medium 16 expands, displacing the valve member 17 downward through the diaphragm 15, and 17 is seated on the valve seat member 9 to close the valve port 8, thereby preventing the leakage of steam. This expansion medium 1
Even if the valve member 17 is inclined when the valve member 17 is seated on the valve seat member 9 due to the expansion of 6, the temperature control element 10 drooped by the spring 20 can be entirely inclined. 8 and close completely. Further, since the temperature control element 10 is rotating when the valve is opened, the rotational positional relationship of the valve member 17 with respect to the valve seat member 9 changes each time the seat is seated, and uneven wear does not occur on the valve member 17.

[0015]

The present invention has the following specific effects. According to the present invention as described above, the valve can be completely closed even if the valve member is seated in an inclined state, and the valve member does not have uneven wear. It is energy saving.

[Brief description of the drawings]

FIG. 1 is a sectional view of a thermally responsive steam trap according to an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Main body 2 Inlet 3 Outlet 4 Valve room 5 Lid member 8 Valve port 9 Valve seat member 10 Temperature control element 11 Injection port 12 Upper wall member 13 Plug member 15 Diaphragm 16 Expansion medium 17 Valve member 18 Lower wall member 20 Spring 21 Mounting Member 22, 23 Snap ring 24 Swirl wing

Claims (1)

(57) [Claims] An inlet, a valve chamber, and an outlet are formed by casing, two upper and lower wall members, a diaphragm having an outer peripheral edge fixed between the two wall members, and enclosed between the upper wall member and the diaphragm. A temperature control element composed of the expanded medium and a valve member connected to the diaphragm is disposed in the valve chamber, and the valve member is driven by displacement of the diaphragm due to expansion and contraction of the expansion medium to form an outlet at the opening end of the outlet on the valve chamber side. Opening and closing the valve port, wherein a swirler blade receiving rotational force by the discharged fluid is attached to the lower surface of the lower wall member, and a temperature control element is tilted and rotatably hung by a spring mounted in the valve chamber. Thermo-responsive steam trap.