RU2118749C1 - Steam converting valve - Google Patents

Abstract

FIELD: control of steam pressure and temperature; manufacture of fittings. SUBSTANCE: valve has body 4 with perforated sleeve 11 where spool valve 5 is arranged. Perforated sleeve 11 is provided with nozzle pipe 14. Section of pipe 14 located outside the sleeve is connected with cooling water inlet branch pipe 3. Section of pipe 14 located inside sleeve 11 has holes 15 for injection of water. Section of pipe located on the sleeve outside in steam escape branch pipe is fitted with injector 16 for injection of cooling water. Spool valve has two shut-off parts 7 and 8. Part 7 is used for opening and closing holes 15 in nozzle pipe. Part 8 is used for control of amount of passage area of water supply branch pipe 3. Second expansion chamber 10 surrounding perforated sleeve 11 is brought in communication with steam escape branch pipe through bypass holes 17. EFFECT: enhanced reliability of injection of cooling water. 8 cl, 3 dwg

Description

 The invention relates to a steam control valve designed to reduce the pressure and temperature of the steam. Such valves are used in power plants and steam-consuming enterprises (for example, in the finishing industry, in dyeing factories, etc.).

 Such steam converting valves comprise a housing with a steam inlet pipe, a cooling water inlet pipe and a steam outlet pipe. At the same time, an expansion chamber and a control piston regulating the flow of cooling water are located in the housing. To reduce the temperature, cooling water is injected into the hot steam, which then must immediately evaporate. The injected water must completely evaporate in both partial and full load conditions, otherwise water droplets will form, causing significant damage from erosion and thermal shock.

 Among the known steam conversion valves there are those in which pressure reduction and cooling occur separately, and those in which at the same time as the pressure decreases, an adjustable amount of cooling water is injected into the expansion chamber. Steam converting valves with separate pressure reduction and cooling are preferably used where more changes in the amount of steam occur during operation. For small changes in the amount of steam, in most cases steam conversion valves with pressure reduction and simultaneous injection of cooling water are used.

 Known steam conversion valve comprising a housing with steam inlet, steam outlet pipes and a cooling water inlet pipe. A perforated cup is located in the housing, forming an expansion chamber. The spool, located with the possibility of axial movement and regulation of steam and cooling water, contains a hollow cylinder with a perforated wall. The specified hollow cylinder is located in a perforated glass for regulating the entry of steam into the glass and steam exit into the second expansion chamber, which is located around the glass - see the application of Germany N 3 323 990, class. F 22 G 5/12, 1985

 The disadvantage of this valve is not sufficiently reliable injection of cooling water.

 The objective of the invention is the creation of a steam conversion valve, which provides a partial load reliable reliable controlled injection of cooling water into the expansion chamber while reducing steam pressure, and in full load provides a separate decrease in steam pressure in the expansion chamber and injection of cooling water.

 The technical result is achieved by the fact that in the steam conversion valve comprising a housing with steam inlet and steam outlet pipes and a cooling water inlet pipe, a perforated cup located in the housing forming an expansion chamber, a spool placed with axial movement and regulation of the steam and cooling water flow, on the spool made a hollow cylinder with a perforated wall located in a perforated glass with the ability to control the entry of steam into the glass and the exit of steam into the second an expansion chamber located around the glass. According to the invention, the perforated cup is provided with a coaxially installed nozzle pipe, a pipe portion located outside the perforated cup is connected to the cooling water inlet pipe, holes for injection of cooling water are made in the pipe portion located in the perforated cup, and in the pipe portion located outside the cup in steam outlet, nozzle for injection of cooling water, made on the spool made two locking parts located in the nozzle pipe, the first part is placed with possible the opening and closing of the holes in the nozzle pipe, and the second part is placed with the possibility of controlling the passage size of the cooling water supply pipe to the holes or nozzle, while the second expansion chamber surrounding the perforated glass is communicated through the bypass holes with the steam outlet pipe forming the third expansion chamber.

 In addition, the holes for introducing steam into the perforated cup are located on the wall portion of the hollow spool cylinder that receives steam from the steam inlet, and the other portion of the wall that controls the steam outlet into the second expansion chamber is made solid to open and close the holes in the perforated cup.

 Moreover, both parts of the spool included in the nozzle pipe are interconnected by a rod, which forms an annular gap between its outer surface and the surface of the nozzle pipe for the passage of cooling water to the holes for water injection.

 Both parts of the spool are sealed in the nozzle pipe with piston ring seals.

 In addition, the bore of the cooling water inlet has a droplet-shaped section facing its wider part towards the water injection holes.

 In this case, the passage section of the cooling water inlet pipe may be formed by several holes having the same and / or different passage section.

 In addition, the shut-off parts of the spool are located at such an axial distance from each other that, when the injection holes are closed with the first shut-off part, the passage section of the cooling water inlet pipe is completely open by the second shut-off part, shifted to the final position, with the passage of water towards the injection holes and with the water passage blocked to the nozzle, and with partially or completely open water injection holes, the water inlet passage section is opened by a second locking part to ensure water passage to Verstov for injection and to the nozzle, and in the other end position of the second locking portion displaced in the direction of injection holes, the flow cross section of the cooling water inlet pipe is fully open the second locking part to allow passage of water to the nozzle passage and an overlapping water to holes injection.

 In addition, the valve is equipped with a second perforated cup placed on the first perforated cup with the formation of an additional stage of expansion of the steam, in the second cup there is an inner annular protrusion in contact with the first perforated cup and dividing the second perforated cup into two perforated parts.

 In this steam conversion valve, cooling water is injected in the partial load mode both through the injection holes into the expansion chamber at the same time as the pressure decreases, and through the nozzle after reducing the vapor pressure into the area of the steam outlet. In full load mode, all cooling water is injected through the nozzle after reducing the vapor pressure in the area of the steam outlet.

 In partial and full load conditions, cooling water is flawlessly injected and evaporates completely. This means increased operational reliability and longer service life of the steam control valve.

 An embodiment of the invention is described below in more detail with reference to the drawings, in which are presented in FIG. 1 is a section of a steam conversion valve in a closed position; in FIG. 2 - the bore of the pipe for the intake of cooling water; in FIG. 3 is a section through a steam conversion valve in a partially open position.

 The steam conversion valve comprises a housing 4 with a steam inlet pipe 1, a cooling water inlet pipe 3 and a steam outlet pipe 2. A perforated cup 11 is located in the housing 4, forming an expansion chamber, and a spool 5 mounted axially movable to control the flow of steam and cooling water to the expansion valve the camera. The spool 5 is rigidly connected to the cylinder 6 having a perforated wall. The cylinder 6 is axially movable in the perforated cup 11. This perforated cylinder 6 opens the steam inlet D into the perforated cup 11 and the steam exits into the second expansion chamber 10 located around the perforated cup 11, or closes it. A nozzle pipe 14 is directed into the perforated cup 11, which is connected outside the perforated cup 11 to the pipe 3 for the intake of cooling water. Inside the perforated cup 11, the nozzle pipe 14 has openings 15 for injecting cooling water W. A part of the nozzle pipe 14, which is outside the cup 11, is directed into the steam outlet 2 and contains therein an nozzle 16 for injecting cooling water W.

 The first part 7 of the spool 5, which is arranged to move in the nozzle pipe 14, sequentially opens or closes the injection holes 15 made in the nozzle pipe 14. The second part 8 controls the size of the passage section X of the pipe 3, intended for supplying cooling water to the holes 15 for injection into the expansion chamber and / or to the nozzle 16 located in the steam outlet 2.

 The second expansion chamber 10 surrounding the perforated cup 11 is communicated through the passage openings 17 with a steam outlet 2 forming the third expansion chamber.

 The tubular perforated cylinder 6 is placed in two sections having different functions.

 On the wall section of the hollow cylinder 6, which receives steam from the steam inlet pipe, holes 18 are made for steam to enter the perforated glass, and the other wall section 19, which regulates the steam output into the second expansion chamber 10, is made continuous for alternately opening and closing the holes in the perforated glass 11 .

 Both parts 7 and 8 of the spool 5 included in the nozzle pipe are interconnected by a rod 20, which forms an annular gap 13 between its outer surface and the surface of the nozzle pipe for the cooling water to pass to the holes 15 and to inject it through the holes 15 into the nozzle pipe 14.

 Both parts 7 and 8 of the spool are sealed in the nozzle pipe 14 gas- and water-tight by means of a seal 9 made in the form of a piston ring, preferably of metal.

 The flow cross section X of the cooling water inlet 3 has a droplet shape facing its wider part towards the injection holes 15 in the nozzle pipe 14 (see FIG. 2). Instead of a droplet-shaped, the passage section of the cooling water inlet 3 can be formed by several openings having the same and / or different sizes.

 Around the perforated glass 11 is a second (external) perforated glass 12, forming an additional expansion step. The inner annular protrusion 21 of the glass 12 is adjacent to the inner surface of the perforated glass 11 and divides the external perforated glass 12 into two sections.

 The spool 5 is surrounded at the height of the steam inlet 1 by a perforated wall 22. The steam entering through the openings of the specified wall 22 is washed as evenly as possible with the spool 5.

 The axial distance between both parts 7 and 8 of the spool 5 is designed so that in the closed position of the injection holes 15 in the nozzle pipe 14 by the first part 7 (Fig. 1), the second part 8, located in the final position, opens the passage section X of the pipe 3 for cooling water inlet for water passage in the direction of the injection holes 15 and closes the passage in the direction of the nozzle 16.

 To open the steam conversion valve, the perforated cylinder 6 with the spool 5 is partially pulled out of the perforated glass (Fig. 2). Due to this, at the same time, the expansion holes 18 of the perforated cylinder 6 partially open for steam to enter the perforated glass 11 and, which are closed by the shutter wall 19 of the perforated cylinder 6, the expansion holes of the perforated glass 11 for steam exit. In this position, corresponding to the partial load mode, the injection holes 15 with the nozzle pipe 14 are partially or completely open by the first spool part 7. The cross section X of the cooling water inlet 3 is then opened by the second part 8 of the spool both for the passage of water in the direction of the injection holes 15 and in the direction of the nozzle 16.

 In full load mode, the second part 8 of the spool is in its second final position, offset in the direction of the injection holes 15 in the nozzle pipe 14, in which the flow cross section X is fully open, the flow of cooling water to the injection holes 15 in the nozzle pipe 14 is closed, and the flow of cooling water to the nozzle 16 is fully open. In this position, therefore, cooling water W is not injected into the perforated cup 11 forming an expansion chamber.

 The greater the amount of steam to be cooled, the more cooling water is required. For the complete evaporation of cooling water W, the expansion volume of the perforated cup 11 is not enough. In order to avoid the formation of water droplets, as the amount of steam increases, more and more cooling water W is injected through the nozzle 16 into the area of the steam outlet 2. At full load, all cooling water W is injected there.

 When cooling water W is injected through the nozzle 16, it additionally swirls there. The working volume above the spool 5 is communicated through the equalization channel 23 with a pair of part of the cavity of the housing 4 accessible to the couple.

Claims (8)

 1. A steam conversion valve comprising a housing with steam inlet, steam outlet and a cooling water inlet pipe, a perforated cup located in the housing forming an expansion chamber, a spool arranged for axial movement and regulation of steam and cooling water flow, a hollow cylinder with a perforated cylinder is made on the spool a wall located in a perforated glass with the possibility of regulating the entry of steam into the glass and the exit of steam into the second expansion chamber located around cup, characterized in that the perforated cup is provided with a coaxially mounted nozzle pipe, a pipe portion located outside the perforated cup is connected to the cooling water inlet pipe, holes for the injection of cooling water are made in the pipe portion located in the perforated cup, and in the pipe portion, located outside the cup in the steam outlet, a nozzle for injection of cooling water is made, two shut-off parts located in the nozzle pipe are made on the spool, the first part is placed with the possibility of opening and closing the holes in the nozzle pipe, and the second part is placed with the possibility of regulating the size of the passage section of the cooling water supply pipe to the holes and / or nozzle, while the second expansion chamber surrounding the perforated glass is communicated through the bypass openings with the third expansion chamber steam outlet.  2. The valve according to claim 1, characterized in that the holes for steam inlet into the perforated cup are located on the wall portion of the hollow spool cylinder that receives steam from the steam inlet pipe, and the other wall section that regulates the steam outlet into the second expansion chamber is made continuous for opening and closing the holes in the perforated glass.  3. The valve according to claim 2, characterized in that both parts of the spool included in the nozzle pipe are interconnected by a rod, which forms an annular gap between its outer surface and the surface of the nozzle pipe for the passage of cooling water to the holes for water injection.  4. The valve according to claims 1 to 3, characterized in that both parts of the spool are sealed in the nozzle pipe with seals in the form of piston rings.  5. The valve according to claims 1 to 4, characterized in that the orifice of the cooling water inlet pipe has a droplet-shaped section facing its wider part towards the water injection holes.  6. The valve according to one of claims 1 to 4, characterized in that the flow area of the cooling water inlet pipe is formed by several holes having the same and / or different flow area.  7. The valve according to one of claims 1 to 6, characterized in that the shut-off parts of the spool are located at such an axial distance from each other, when the water injection holes are closed by the first shut-off part, the passage section of the cooling water inlet pipe is completely open by the second shut-off part, offset in the final position, with the passage of water in the direction of the injection holes and with the passage of water blocked to the nozzle, and with partially or completely open water injection holes, the passage section of the water inlet pipe is open to the second the pore part to ensure the passage of water to the injection holes and to the nozzle, and in the other end position of the second locking part, biased towards the injection holes, the passage section of the cooling water inlet pipe is completely open by the second locking part to ensure the passage of water to the nozzle and with an overlap water passage to the injection holes.  8. The valve according to one of claims 1 to 7, characterized in that it is provided with a second perforated cup placed on the first perforated cup with the formation of an additional stage of expansion of the steam, in the second cup an internal annular protrusion is made in contact with the first perforated cup and dividing the second perforated glass into two perforated parts.

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