DE4304972A1 - Steam conversion valve - Google Patents

Abstract

The steam desuperheating valve has a housing (4) with a steam inlet (1), a cooling water inlet (3) and a steam outlet (2). In the housing (4) there are a perforated basket (11) forming a depressurising chamber and an axially movable control piston (5) controlling the flow of steam and cooling water to the depressurising chamber. The control piston (5) is rigidly coupled to a perforated cylinder (6) axially movable in the perforated basket (11). This perforated cylinder (6) releases or blocks the steam inlet (D) into the perforated basket (11) and the steam outlet into a second depressurising chamber (10) arranged around the perforated basket (11). Into the perforated basket (11) projects a coaxial nozzle pipe (14) which is connected outside the perforated basket (11) to the cooling water inlet (3). Inside the perforated basket (11) the nozzle pipe (14) has injection apertures (15) for the cooling water (W). Outside the perforated basket (11) the nozzle pipe (14) projects into the steam outlet (2) and has an injection nozzle (16) at that point for the cooling water (W). A first piston section (7) movable with the control piston (5) in the nozzle pipe (14) alternately opens and closes the injection apertures (15) in the nozzle pipe (14). A second piston section (8) regulates the cooling water inlet (3) in the size of the through-flow cross-section (X) for the flow of cooling water into the injection apertures (15) in the depressurising chamber and/or into the injection nozzle (16) in the steam outlet (2). The second depressurising chamber (10) surrounding the perforated basket (11) is connected via through-flow apertures (17) to the steam outlet (2) forming a third depressurising chamber.

Description

The invention relates to a steam conversion valve for Reduction of steam pressure and temperature. Such valves are used in power plant technology and in production steam consuming companies (e.g. textile finishing companies, Dyeing, etc.) used.

Such steam conversion valves have a housing with a Steam inlet, a cooling water inlet and a steam outlet. There is a relaxation room in the housing and a steam and control water flow regulating control piston arranged. For Temperature reduction is used in the hot steam cooling water injected, which should then evaporate immediately. The The amount of cooling water injected must correspond to the amount of steam (Partial load or full load). The injected Cooling water must be in both partial and full load operation evaporate completely. Otherwise water drops which lead to considerable erosion and thermal shock damage.

In the known steam conversion valves, there are some at where pressure reduction and cooling are separate and which ones where at the same time as the pressure reduction in cooling water the relaxation room is injected in a controlled manner. The Steam converting valves with a separation of pressure reduction and Cooling is preferred wherever large in operation Changes in the amount of steam occur. For minor changes steam conversion valves are usually included in the amount of steam  Pressure reduction and simultaneous cooling water injection used.

The object of the invention is to provide a steam conversion valve create that in a safe and flawless manner in the partial load Operation the regulated cooling water injection in the Relaxation room with simultaneous steam pressure reduction enables and in full load operation a separation between Vapor pressure reduction in the relaxation room and Cooling water injection provides.

This object is achieved by the characterizing Features of claim 1 solved. The ones at it subsequent sub-claims contain design features, which beneficial and advantageous further training of the Represent invention.

The steam converter valve has a housing with a steam inlet, a cooling water inlet and a steam outlet. By doing Housings are a perforated basket and a relaxation space a steam and cooling water flow to the relaxation room regulating, axially displaceable control piston arranged. Of the The control piston is axially displaceable in the perforated cage tubular perforated cylinder rigidly connected. With this Perforated cylinder is the steam entry into the perforated basket and the Steam escapes into a second one arranged around the perforated basket Relaxation room released or blocked off. In the punch basket A coaxial nozzle tube protrudes into it Perforated basket is connected to the cooling water inlet. The Nozzle tube points inside the one that forms the relaxation space Perforated basket injection openings for the cooling water. Outside the perforated cage, the nozzle tube has one Injection nozzle that protrudes into the steam outlet area. Of the Control piston is slidable in the nozzle tube and gives with one Piston part the injection openings in the nozzle pipe for cooling water free or cordon them off. Controls with a second piston part  the control piston the cooling water inlet in the size of Flow cross section for the cooling water flow to the Injection openings and / or to the injection nozzle.

The cooling water is thus in partial load operation via both Injection openings in the relaxation room at the same time the pressure reduction injected, as well as over the Injector after reducing the steam pressure in the Steam outlet area injected. In full-load operation it will total cooling water through the injector after the Vapor pressure reduction injected into the steam outlet area.

The cooling water is in part-load and full-load operation perfectly injected and completely evaporated. This means greater operational reliability and longer Life of the steam converter valve.

An exemplary embodiment is shown in the drawings, which is explained in more detail below. It shows:

Fig. 1 is a sectional view of the steam conditioning valve in the closed position,

Fig. 1a the flow area of the cooling water inlet,

Fig. 2 shows a section through the steam converter valve in the partially open state.

The steam conversion valve has a housing ( 4 ) with a steam inlet ( 1 ), a cooling water inlet ( 3 ) and a steam outlet ( 2 ). Arranged in the housing ( 4 ) are a perforated basket ( 11 ) forming a relaxation space and an axially displaceable control piston ( 5 ) which regulates the steam and cooling water flow to the relaxation space. The control piston ( 5 ) is rigidly connected to a perforated cylinder ( 6 ) which is axially displaceable in the perforated basket ( 11 ). This perforated cylinder ( 6 ) releases or blocks the steam inlet (D) into the perforated basket ( 11 ) and the steam outlet into a second relaxation space ( 10 ) arranged around the perforated basket ( 11 ). In the perforated basket (11) a coaxial nozzle tube (14) protrudes, which is connected outside of the perforated basket (11) with the cooling water inlet (3). Inside the perforated basket ( 11 ), the nozzle tube ( 14 ) has injection openings ( 15 ) for the cooling water (W). Outside the perforated basket ( 11 ), the nozzle tube ( 14 ) projects into the steam outlet ( 2 ) and has an injection nozzle ( 16 ) there for the cooling water (W).

A first piston part ( 7 ) which can be displaced in the nozzle tube ( 14 ) with the control piston ( 5 ) opens the injection openings ( 15 ) in the nozzle tube ( 14 ) one after the other or blocks them. A second piston part ( 8 ) controls the cooling water inlet ( 3 ) in the size of the flow cross-section (X) for the cooling water flow to the injection openings ( 15 ) in the expansion chamber and / or to the injection nozzle ( 16 ) in the steam outlet ( 2 ).

The second relaxation space ( 10 ) surrounding the perforated basket ( 11 ) is connected via flow openings ( 17 ) to the steam outlet ( 2 ) forming a third relaxation space.

The tubular perforated cylinder ( 6 ) is divided into two areas with different functions. On its axial length range assigned to the steam inlet ( 1 ), the perforated cylinder ( 6 ) has expansion holes ( 6 a) for steam entry into the perforated basket ( 11 ), while the axial length range assigned to the second expansion space ( 10 ) as a closed shut-off wall ( 6 b) is designed to alternately release and block the relaxation holes in the perforated basket ( 11 ).

The control piston (5) is formed in one piece with its two piston parts (7, 8), wherein between the two piston parts (7, 8) extends a piston rod (20) which between itself and the nozzle tube (14) an annular space (13) for the Cooling water flow to the injection openings ( 15 ) of the nozzle tube ( 14 ) forms. The two piston parts ( 7 , 8 ) are guided in the nozzle tube ( 14 ) in a gas and water-tight manner by means of a piston ring seal ( 9 ), preferably made of metal.

The flow cross section (X) of the cooling water inlet ( 3 ) has a drop-shaped pilot control cross section, which points with its large drop cross section in the direction of injection openings ( 15 ) of the nozzle pipe ( 14 ). Instead of the drop-shaped pilot control cross section, the flow cross section of the cooling water inlet ( 3 ) can be formed from several pilot control holes of the same and / or different sizes.

A second (outer) perforated basket ( 12 ) is arranged around the perforated basket ( 11 ) as a further relaxation stage, which bears against the inner perforated basket ( 11 ) with a partition ( 12 a) and divides the outer perforated basket ( 12 ) into two perforated sections.

The control piston ( 5 ) is surrounded by a perforated basket ( 18 ) at the level of the steam inlet ( 1 ), through the openings of which the steam flows in for the most uniform possible flow around the control piston ( 5 ).

The axial distance between the two piston parts ( 7 , 8 ) of the control piston ( 5 ) is dimensioned such that in the shut-off position (see. Fig. 1) of the injection openings ( 15 ) of the nozzle tube ( 14 ) through the first piston part ( 7 ) Entire flow cross-section (X) of the cooling water inlet ( 3 ) is released from the second piston part ( 8 ) which is in an end position in the direction of the injection openings ( 15 ) and is blocked off in the direction of the injection nozzle ( 16 ).

To open the steam conversion valve, the perforated cylinder ( 6 ) with the control piston ( 5 ) is partially pulled out of the perforated basket ( 11 ) (cf. FIG. 2). So that the relaxation holes ( 6 a) of the perforated cylinder ( 6 ) for steam entry into the perforated basket ( 11 ) and the relaxation holes of the perforated cylinder ( 6 ) closed by the shut-off wall ( 6 b) of the perforated basket ( 11 ) for the steam outlet are partially released. In this part-load operating position, the injection openings ( 15 ) of the nozzle tube ( 14 ) are partially or completely cleared through the first piston part ( 7 ). The flow cross section (X) of the cooling water inlet ( 3 ) is then released by the second piston part ( 8 ) both in the direction of the injection openings ( 15 ) and in the direction of the injection nozzle ( 16 ).

When operating at full load, the second piston part ( 8 ) is in its second end position, which is moved in the direction of the injection openings ( 15 ) of the nozzle tube ( 14 ), in which the flow cross-section (X) is completely released, and the cooling water flow to the injection openings ( 15 ) of the nozzle tube ( 14 ) shut off and the cooling water flow to the injection nozzle ( 16 ) is completely open. In this position, no cooling water (W) is injected into the perforated basket ( 11 ) forming the relaxation space.

The greater the amount of steam to be cooled, the more cooling water is required. The relaxation volume of the perforated basket ( 11 ) is then no longer sufficient to completely evaporate the cooling water (W). In order to avoid the formation of harmful water drops, more and more cooling water (W) is injected into the area of the steam outlet ( 2 ) via the injection nozzle ( 16 ) as the amount of steam increases. At full load operation, the entire cooling water (W) is injected there.

To inject the cooling water (w) via the injection nozzle ( 16 ), it is also swirled there. The displacement above the control piston ( 5 ) is connected to the part of the housing ( 4 ) accessible to the steam via a compensating channel ( 19 ).

Claims (8)

1. Steam conversion valve with a housing having a steam inlet, a cooling water inlet and a steam outlet, in which a perforated basket forming a relaxation space and an axially displaceable control piston which regulates the steam and cooling water flow to the relaxation space are arranged, characterized in that

• a control piston (5) displaceable) having a perforated basket (11) axially, the steam inlet (D)-releasing in the perforated basket (11) and the steam outlet in a second, arranged around the perforated basket (11) expansion space (10) and shut-off tubular Perforated cylinder ( 6 ) is rigidly connected,
• b) in the perforated basket ( 11 ) protrudes a coaxial nozzle tube ( 14 ) which is connected outside the perforated basket ( 11 ) with the cooling water inlet ( 3 ), inside the perforated basket ( 11 ) injection openings ( 15 ) for the cooling water (W) and outside the perforated basket ( 11 ) has an injection nozzle ( 16 ) for cooling water (W),
• c) the control piston ( 5 ) in the nozzle tube ( 14 ) is displaceable and a first, the injection openings ( 15 ) in the nozzle tube ( 14 ) releasing and blocking piston part ( 7 ) and a second, the cooling water inlet ( 3 ) in the size of the flow cross-section (X) for the cooling water flow to the injection openings ( 15 ) and / or to the injection nozzle ( 16 ) regulating piston part ( 8 ),
• d) the relaxation space ( 10 ) surrounding the perforated basket ( 11 ) is connected via flow openings ( 17 ) to the steam outlet ( 2 ) forming a third relaxation space, into which the injection nozzle ( 16 ) protrudes.

2. Steam-converting valve according to claim 1, characterized in that the perforated cylinder ( 6 ) on the steam inlet ( 1 ) associated axial length area has relaxation holes ( 6 a) for the steam inlet and on the second relaxation space ( 10 ) assigned axial length area as a closed shut-off wall ( 6 b) is designed to alternately release and shut off the relaxation holes in the perforated basket ( 11 ). 3. steam-forming valve according to claim 1 and 2, characterized in that the control piston ( 5 ) with its two piston parts ( 7 , 8 ) is integrally formed and a piston rod ( 20 ) which runs between them between the two piston parts ( 7, 8 ) and the nozzle tube ( 14 ) forms an annular space ( 13 ) for the cooling water flow to the injection openings ( 15 ) of the nozzle tube ( 14 ). 4. Steam-converting valve according to one of claims 1 to 3, characterized in that both piston parts ( 7 , 8 ) of the control piston ( 5 ) by means of piston ring seals ( 9 ) are guided gas and water-tight in the nozzle tube ( 14 ). 5. Steam-converting valve according to one of claims 1 to 4, characterized in that the flow cross-section (X) of the cooling water inlet ( 3 ) has a drop-shaped pilot control cross-section which, with its large drop cross-section area, points in the direction of injection openings ( 15 ) of the nozzle tube ( 14 ). 6. Steam-converting valve according to one of claims 1 to 4, characterized in that the flow cross section (X) of the cooling water inlet ( 3 ) is formed from several pilot holes of the same and / or different sizes. 7. steam conversion valve according to one of claims 1 to 6, characterized in that the axial distance between the two piston parts ( 7 , 8 ) of the control piston ( 5 ) is dimensioned such that in the shut-off position of the injection openings ( 15 ) of the nozzle tube ( 14 ) through the first piston part ( 7 ) the entire flow cross-section (X) of the cooling water inlet ( 3 ) is released from the second piston part ( 8 ), which is in an end position, in the direction of the injection openings ( 15 ) and blocked in the direction of the injection nozzle ( 16 ), in which the injection openings ( 15 ) of the nozzle tube ( 14 ) partially or completely releasing the first piston part ( 7 ) the flow cross-section (X) of the cooling water inlet ( 3 ) from the second piston part ( 8 ) in the direction of the injection openings ( 15 ) and in the direction of the injection nozzle ( 16 ) is released and in the second end position of the second piston, which is moved in the direction of the injection openings ( 15 ) of the nozzle tube ( 14 ) Hurry ( 8 ) the flow cross-section (X) of the cooling water inlet ( 3 ) completely released, the water flow to the injection openings ( 15 ) of the nozzle tube ( 14 ) shut off and the cooling water flow to the injection nozzle ( 16 ) is completely open. 8. steam-forming valve according to one of claims 1 to 7, characterized in that around the perforated basket ( 11 ) a second (outer) perforated basket ( 12 ) is arranged as a further relaxation stage, which rests with a partition on the inner perforated basket ( 11 ) and the outer Perforated basket ( 12 ) divided into two perforated sections.