The present invention relates to desuperheaters, which are commonly used on fluid and gas lines (e.g., steam lines) in the power and process industries, and further relates to spray nozzles for use with desuperheaters.
Desuperheaters are used in many industrial fluid and gas lines to reduce the temperature of superheated process fluid and gas to a desired set point temperature. For example, desuperheaters are used in power process industries to cool superheated steam. The desuperheater injects a fine spray of atomized cooling water or other fluid, referred to herein as a spraywater cloud, into the steam pipe through which the process steam is flowing. Evaporation of the water droplets in the spraywater cloud reduces the temperature of the process steam. The resulting temperature drop can be controlled by adjusting one or more control variables, such as the volume rate of injecting the cooling water and/or the temperature of the cooling water. The size of the individual droplets in the spraywater cloud and/or the pattern of the spraywater cloud can also be adjusted to control the time required for the temperature drop.
Steam assisted spray atomization is regarded as the most effective way of atomizing spray water in a desuperheating system. It produces the finest droplets, allowing for the quickest evaporation and cooling of the process fluid (typically steam).
Typically, a spraywater cloud requires some minimum length or run of straight pipe downstream from the injection point to ensure substantially complete evaporation of the individual atomized water droplets. Otherwise, the spraywater cloud may condense or not completely evaporate when a bend or split in the steam pipe is encountered. This length or run of straight pipe is typically referred to as a “downstream pipe length.” A temperature sensor is also usually located at the end of the downstream pipe length to sense the resulting temperature drop of the steam.
A steam assisted desuperheater includes an atomizing head that combines a high velocity stream of steam, which is called atomizing steam, with a stream of cooling water to atomize the cooling water and produce the spraywater cloud. In steam assisted desuperheaters, the individual droplets in the spraywater cloud are typically smaller in size than in mechanically atomized desuperheaters and, therefore, evaporate more rapidly inside the steam pipe. Therefore, steam assisted desuperheaters may be used in applications where a shorter downstream pipe length is available.
However, typical nozzle sleeves for steam assisted desuperheaters require machining and welding of multiple components in order to create nozzle sleeves with separate steam and water passages. This can raise issues in certain applications where welds can fatigue and crack. In addition, the machining and welding steps required for typical nozzle sleeves are very time intensive and expensive.
In addition, in high temperature applications, such as those often found in power process industries, there are also thermal expansion concerns in the nozzle sleeves. In a typical nozzle sleeve, hot steam passes around an annulus and water passes through the center flow passage. Therefore, the outer wall of the nozzle sleeve is at the steam temperature and the inner wall of the nozzle sleeve, between the steam and water passages, is at or near the water temperature. Since the steam and water temperature may be several hundred degrees Fahrenheit different from each other, the differential thermal expansion is enough to cause excessive compressive and tensile stress on the nozzle sleeves. Therefore, the different expansion of the parts needs to be addressed.
In accordance with one exemplary aspect of the present invention, a spray nozzle assembly for a desuperheater includes a housing that has a body and a cap flange secured to the body to define a bore within the housing. A first aperture is formed through the body and intersects the bore and a second aperture is formed through the cap flange and intersects the bore. A nozzle sleeve is disposed within the bore and has a solid, unitary sleeve body. A first fluid passage is formed through the sleeve body in fluid communication with the first aperture and with a first exit aperture in an end of the sleeve body. A second fluid passage is formed through the sleeve body in fluid communication with the second aperture, with a second exit aperture formed in the end of the sleeve body, and with a third exit aperture formed in the end of the sleeve body. A portion of the second fluid passage surrounds the first fluid passage and the second and third exit apertures are positioned on opposite sides of the first exit aperture.
In further accordance with any one or more of the foregoing exemplary aspect of the present invention, the spray nozzle assembly may further include, in any combination, any one or more of the following preferred forms.
In one preferred form, the first fluid passage comprises a first section that extends radially across the sleeve body and a second section that intersects the first section and extends longitudinally along the sleeve body.
In another preferred form, the end of the sleeve body comprises a planar first surface that extends perpendicular to a longitudinal axis of the nozzle sleeve and a planar second surface that extends from the first surface and at an acute angle to the longitudinal axis of the nozzle sleeve, the second exit aperture is formed through the first surface, and the first and third exit apertures are formed through the second surface.
In another preferred form, the end of the sleeve body comprises a planar first surface that extends perpendicular to a longitudinal axis of the nozzle sleeve, a planar second surface that extends from the first surface and at an acute angle to the longitudinal axis of the nozzle sleeve, and a planar third surface that extends from the second surface and parallel to the longitudinal axis of the nozzle sleeve, the second exit aperture is formed through the first surface, the first exit aperture is formed through the second surface, and the third exit aperture is formed through the third surface.
In another preferred form, the first, second, and third exit apertures are linearly extending slots.
In another preferred form, the first exit aperture is elliptical and the second and third exit apertures are arcuately extending slots.
In another preferred form, a desuperheater includes the spray nozzle assembly and has a ring body defining an axial flow path, a plurality of the spray nozzle assemblies disposed around the ring body, a water manifold connected to each of the spray nozzle assemblies for providing cooling water to each of the spray nozzle assemblies, and a steam manifold connected to each of the spray nozzle assemblies for providing atomizing steam to each of the spray nozzle assemblies, separately from the cooling water.
In accordance with another exemplary aspect of the present invention, a spray nozzle assembly for a desuperheater comprises a housing that has a body and a cap flange secured to the body to define a bore within the housing. A first aperture formed through the body and intersects the bore and a second aperture is formed through the cap flange and intersects the bore. A nozzle sleeve is disposed within the bore and has a solid, unitary sleeve body. A first fluid passage is formed through the sleeve body in fluid communication with the first aperture and a second fluid passage is formed through the sleeve body in fluid communication with the second aperture, with a portion of the second fluid passage surrounding the first fluid passage. A generally cylindrical inner wall is formed between the first fluid passage and the portion of the second fluid passage, a generally cylindrical outer wall surrounds the portion of the second fluid passage, and a plurality of support arms extend between the inner wall and the outer wall along a length of the portion of the second fluid passage.
In further accordance with any one or more of the foregoing exemplary aspect of the present invention, the spray nozzle assembly may further include, in any combination, any one or more of the following preferred forms.
In one preferred form, the plurality of support arms extend radially from the inner wall to the outer wall.
In another preferred form, the plurality of support arms extend tangentially from the inner wall.
In another preferred form, the plurality of walls are arcuate.
In another preferred form, the first fluid passage comprises a first section that extends radially across the sleeve body and a second section that intersects the first section and extends longitudinally along the sleeve body.
In another preferred form, the first fluid passage is in fluid communication with a first exit aperture formed in an end of the sleeve body and the second fluid passage is in fluid communication with a second exit aperture formed in the end of the sleeve body and with a third exit aperture formed in the end of the sleeve body. The second and third exit apertures are positioned on opposite sides of the first exit aperture and the end of the sleeve body comprises a planar first surface that extends perpendicular to a longitudinal axis of the nozzle sleeve and a planar second surface that extends from the first surface and at an acute angle to the longitudinal axis of the nozzle sleeve. The second exit aperture is formed through the first surface and the first and third exit apertures are formed through the second surface.
In another preferred form, the first fluid passage is in fluid communication with a first exit aperture formed in an end of the sleeve body and the second fluid passage is in fluid communication with a second exit aperture formed in the end of the sleeve body and with a third exit aperture formed in the end of the sleeve body. The second and third exit apertures are positioned on opposite sides of the first exit aperture and the end of the sleeve body comprises a planar first surface that extends perpendicular to a longitudinal axis of the nozzle sleeve, a planar second surface that extends from the first surface and at an acute angle to the longitudinal axis of the nozzle sleeve, and a planar third surface that extends from the second surface and parallel to the longitudinal axis of the nozzle sleeve. The second exit aperture is formed through the first surface, the first exit aperture is formed through the second surface, and the third exit aperture is formed through the third surface.
In another preferred form, a desuperheater includes the spray nozzle assembly and includes a ring body defining an axial flow path, a plurality of the spray nozzle assemblies disposed around the ring body, a water manifold connected to each of the spray nozzle assemblies for providing cooling water to each of the spray nozzle assemblies, and a steam manifold connected to each of the spray nozzle assemblies for providing atomizing steam to each of the spray nozzle assemblies, separately from the cooling water.
In accordance with another exemplary aspect of the present invention, a spray nozzle assembly for a desuperheater comprises a housing having a body and a cap flange secured to the body to define a bore within the housing. A first aperture is formed through the body and intersects the bore and a second aperture is formed through the cap flange and intersects the bore. A nozzle sleeve is disposed within the bore and has a solid, unitary sleeve body. A first fluid passage is formed through the sleeve body and is in fluid communication with the first aperture and a second fluid passage is formed through the sleeve body and is in fluid communication with the second aperture, with a portion of the second fluid passage surrounding the first fluid passage. An inner wall is formed between the first fluid passage and the portion of the second fluid passage and is corrugated along a length of the portion of the second fluid passage.
In further accordance with any one or more of the foregoing exemplary aspect of the present invention, the spray nozzle assembly may further include, in any combination, any one or more of the following preferred forms.
In one preferred form, the first fluid passage comprises a first section that extends radially across the sleeve body and a second section that intersects the first section and extends longitudinally along the sleeve body.
In another preferred form, the first fluid passage is in fluid communication with a first exit aperture formed in an end of the sleeve body and the second fluid passage is in fluid communication with a second exit aperture formed in the end of the sleeve body and with a third exit aperture formed in the end of the sleeve body. The second and third exit apertures are positioned on opposite sides of the first exit aperture and the end of the sleeve body comprises a planar first surface that extends perpendicular to a longitudinal axis of the nozzle sleeve and a planar second surface that extends from the first surface and at an acute angle to the longitudinal axis of the nozzle sleeve. The second exit aperture is formed through the first surface and the first and third exit apertures are formed through the second surface.
In another preferred form, the first fluid passage is in fluid communication with a first exit aperture formed in an end of the sleeve body and the second fluid passage is in fluid communication with a second exit aperture formed in the end of the sleeve body and with a third exit aperture formed in the end of the sleeve body. The second and third exit apertures are positioned on opposite sides of the first exit aperture and the end of the sleeve body comprises a planar first surface that extends perpendicular to a longitudinal axis of the nozzle sleeve, a planar second surface that extends from the first surface and at an acute angle to the longitudinal axis of the nozzle sleeve, and a planar third surface that extends from the second surface and parallel to the longitudinal axis of the nozzle sleeve. The second exit aperture is formed through the first surface, the first exit aperture is formed through the second surface, and the third exit aperture is formed through the third surface.
In another preferred form, a desuperheater includes the spray nozzle assembly and includes a ring body defining an axial flow path, a plurality of the spray nozzle assemblies disposed around the ring body, a water manifold connected to each of the spray nozzle assemblies for providing cooling water to each of the spray nozzle assemblies, and a steam manifold connected to each of the spray nozzle assemblies for providing atomizing steam to each of the spray nozzle assemblies, separately from the cooling water.
The desuperheater disclosed herein includes spray nozzle assemblies with nozzle sleeves having a solid, unitary bodies. The solid, unitary bodies have both water and steam passages formed within, which allows for jacketed steam atomization.
The use of nozzle sleeves having solid, unitary bodies increases the robustness of the design, as there are no welds or other connections to fatigue or crack and the bodies better resist thermal fatigue. These nozzle sleeves are also less expensive to manufacture.
The nozzle sleeves disclosed herein also provide an effective way of creating steam flow on both sides of the water injection location to “jacket” the water between two jets of steam. The bodies of the nozzle sleeve allow internal splitting of atomizing steam into upper and lower channels to surround the water, which ensures that all of the water is effectively atomized and no water is “bounced away” and escapes the steam jets.
The nozzle sleeves can be used in place of multi-piece nozzle sleeves, can be retrofitted into current spay nozzle assemblies having multi-piece nozzle sleeves, or could be used as the spray nozzle assembly in other forms of desuperheaters.
Turning now to the drawings,
Ring body 32 defines an axial flow path “A”, parallel to longitudinal axis 33 of ring body 32, for the passage of a process fluid, such as steam, therethrough and is preferably in the form of an elongate pipe section having a ring shaped cross-section with radius R extending axially from a first end 32a to a second end 32b. First and second ends 32a, 32b are arranged for connection and/or insertion between two opposing ends of pipe along a process steam pipeline and may be connected to opposing ends of pipe by, for example, welding, couplings, or fasteners. Ring body 32 optionally may include connection flanges (not shown) at each of the first and second ends 32a, 32b for bolted connection to opposing pipe sections in a manner well understood in the art.
Water manifold 36a includes connector 38a for connecting to a source of cooling water and one or more conduits 40a that operatively connect the connector 38a with each of the spray nozzle assemblies 34 to provide cooling water to the spray nozzle assemblies 34. Conduits 40a may be connected with one or more of the spray nozzle assemblies 34 in series, as shown in the present example, and/or in parallel. Steam manifold 36b includes connector 38b for connecting to a source of atomizing steam and one or more conduits 40b that operatively connect connector 38b with each of the spray nozzle assemblies 34. Conduits 40b may be connected with one or more of the spray nozzle assemblies 34 in parallel, as shown in the present example, and/or in series. Connectors 38a, 38b may be connector flanges or other well-known piping connections, such as butt-welds, socket weld ends, etc. Conduits 40a, 40b may be pipes, hoses, or other similar fluid conduits. In this arrangement, water manifold 36a provides cooling water to each of the spray nozzle assemblies 34 and steam manifold 36b supplies atomizing steam to each of the spray nozzle assemblies 34. The cooling water and the atomizing steam are provided separately and independently of each other to each of the spray nozzle assembly 34.
Housing 50 includes body 52 and a neck 60 extending from body 52. Neck 60 is narrower than body 52 and, preferably, each of body 52 and neck 60 has a circular cross-section, although other shapes are possible. Body 52 is disposed on the exterior side of ring body 32 and neck 60 fits into an aperture 62 through the wall of ring body 32 and is secured to the wall of ring body 32, such as with one or more welds. Preferably, the weld also seals aperture 62. Stepped bore 54 extends axially from a first open end at a distal end of neck 60, through body 52, to a second open end opposite the first open end. Annular step 56 divides stepped bore 54 into first bore portion 54a and second bore portion 54b. First bore portion 54a extends from the first end of stepped bore 54 at the distal end of neck 60 to annular step 56 and second bore portion 54b extends from annular step 56 to the second end of stepped bore 54 at the upper surface of body 52. First bore portion 54a is narrower than second bore portion 54b and, preferably, each of the first and second bore portions 54a, 54b is in the form a straight cylindrical bore portion, wherein first bore portion 54a has a first diameter and second bore portion 54b has a second diameter larger than first bore portion 54a. First and second bore portions 54a, 54b are coaxially aligned along a longitudinal single axis of stepped bore 54.
At least one aperture 58, preferably two apertures 58 as shown in the example of
Cap flange 70 covers the second end of stepped bore 54 and retains nozzle sleeve 100 operatively disposed within stepped bore 54. Cap flange 70 is connected to the top surface of body 52, for example, with fasteners or welds. Cap flange 70 preferably forms a fluid tight seal against body 52 to prevent cooling water and/or atomizing steam from escaping through the second end of stepped bore 54. Thus, a seal 72, such as a gasket or O-ring, is sealingly disposed between cap flange 70 and the top surface of body 52. Seal 72 is disposed in an annular groove 64 formed in the top surface of body 52 adjacent second bore portion 54c.
At least one aperture 74 extends radially through cap flange 70 and is in fluid communication with inlets 110 of nozzle sleeve 100, as discussed in more detail below. Aperture 74 in cap flange 70 is angularly offset from apertures 58 in body 52, preferably orthogonally. Aperture 74 is arranged to operatively connect to conduit 40b to direct a flow of steam into stepped bore 54 and into nozzle sleeve 100, as discussed below. Aperture 74 may, for example, receive the end of conduit 40b therein.
Nozzle sleeve 100 is received within stepped bore 54 of body 52 and is secured within stepped bore 54 by cap flange 70. Nozzle sleeve 100 can be manufactured using Additive Manufacturing Technology, such as direct metal laser sintering, full melt powder bed fusion, laser powder bed fusion, etc., which allows nozzle sleeve 100 to be manufactured as a single, solid, unitary piece, which reduces the manufacturing lead time, complexity, and cost. Using an Additive Manufacturing Technology process, the 3-dimensional CAD file of nozzle sleeve 100 is sliced/divided into multiple layers. For example layers approximately 20-60 microns thick. A powder bed, such as a powder based metal, is then laid down representing the first layer of the design and a laser or electron beam sinters together the design of the first layer. A second layer of powder, representing the second layer of the design, is then laid down over the first sintered layer. The second layer of powder is then sintered/fused together with the first layer. This continues layer after layer to form the completed nozzle sleeve 100. Using an Additive Manufacturing Technology process to manufacture nozzle sleeves for spray nozzle assemblies allows the freedom to produce passages having various shapes and geometries, and other feature described below, that are not possible using current standard casting or drilling techniques. As discussed above, the solid, unitary body of the nozzle sleeve also increases the thermal fatigue resistance.
As shown in
A first fluid passage 130, which in the example shown allows the flow of cooling water through nozzle sleeve 100, is formed through body 102 and includes a first section 132 and a second section 134. First section 132 extends radially across middle section 112 of body such that first section 132 is in fluid communication with annular groove 116. Second section 134 extends axially along body 102, preferably coaxial with the longitudinal axis of nozzle sleeve 100, and has a first end 136 that is in fluid communication with first section 132 and is spaced apart from first end 104 of body 102. A second end 138 of second section 134, opposite first end 136, is in fluid communication with exit aperture 140, which is formed through second surface 124 of second end 106 to discharge the cooling water into ring body 32. In the example shown, exit aperture 140 is an elongated slot that is generally linear and extends across second surface 124.
Second and third fluid passages 150, 160, which in the example shown allow the flow of atomizing steam through nozzle sleeve 100, are also formed through body 102 and each include first, second, and third sections 152, 154, 156 and 162, 164, 166, respectively. First sections 152, 154 of second and third fluid passages 150, 160 are in fluid communication with inlets 110 to allow the delivery of atomizing steam from conduits 40b into second and third fluid passages 150, 160 and first sections 152, 154 extend generally parallel to the longitudinal axis of nozzle sleeve 100. In the example shown, first sections 152, 154 have a generally semi-circular cross-section and extend longitudinally on opposite sides of first fluid passage 130. Third sections 156, 166 of second and third fluid passages 150, 160 extend generally parallel to the longitudinal axis of nozzle sleeve 100 and, in the example shown, also have a generally semi-circular cross-section. Third sections 156, 166 are in fluid communication with first sections 152, 162 through second sections 154, 164, extend longitudinally on opposite sides of first fluid passage 130, and are orthogonally radially offset from first sections 152, 162. Third section 156 of second fluid passage 150 is in fluid communication with exit aperture 158, which is formed through first surface 122 of second end 106 to discharge atomizing steam into ring body 32 on one side of exit aperture 140. Third section 166 of third fluid passage 160 is in fluid communication with exit aperture 158, which is formed through second surface 124 of second end 106 to discharge atomizing steam into ring body 32 on a second side of exit aperture 158, opposite exit aperture 158. By discharging atomizing steam through exit apertures 158, 168 on opposite sides of the cooling water discharge at exit aperture 140, the cooling water is “jacketed” between two jets of atomizing steam, which ensures that all of the water is effectively atomized and no water is “bounced away” and escapes the steam jets.
As can best be seen in
Referring to
Referring to
A first fluid passage 230, which in the example shown allows the flow of cooling water through nozzle sleeve 200, is formed through body 202. First fluid passage 230 includes a first section 232 that extends radially across middle section 212 of body 202, like first section 132 of first fluid passage 130, such that first section 232 is in fluid communication with annular groove 216. A second section 234 of first fluid passage 230 extends axially along body 202, preferably coaxial with the longitudinal axis of nozzle sleeve 200. Second section 234 extends from a first end 236 (not shown), that is in fluid communication with first section 232 and is spaced apart from first end 204 of body 202, to a second end 238, opposite first end 236, which is in fluid communication with an annular section 242. Annular section 242 is a generally ring shaped passage that extends annularly within body 202 and is in fluid communication with a plurality of exit apertures 240B, which are formed through planar surface 229 of second end 206 and are positioned in a generally circular pattern to discharge the cooling water into ring body 32.
Second and third fluid passages 250, 260, which in the example shown allow the flow of atomizing steam through nozzle sleeve 200, are also formed through body 202. First sections 252, 262 of each of the second and third fluid passages 250, 260, respectively, are in fluid communication with inlets 210 (not shown) (same as inlets 110) to allow the delivery of atomizing steam from conduits 40b into second and third fluid passages 250, 260. In the example shown, first sections 252, 262 are generally semi-circular in shape and extend generally parallel to the longitudinal axis of nozzle sleeve 200 on opposite sides of second section 234 of first fluid passage 130. Second sections 254, 264 of second and third fluid passages 250, 260 extend radially inward from respective first sections 252, 262, turn approximately 90 degrees to run axially along nozzle sleeve 200, and merge together to pass through the center of annular section 242. Once merged, the merged portions of sections 254, 264 are both in fluid communication with exit aperture 258, which is formed through planar surface 229 of second end 206 to discharge atomizing steam into ring body 32 in the center of the circular pattern formed by exit apertures 240B. Third sections 256, 266 of second and third fluid passages 250, 260 extend longitudinally from respective first sections 252, 262 and are each in fluid communication with exit aperture 268B to discharge atomizing steam into ring body 32. In the example shown, exit aperture 268B is an annular, ring-shaped aperture that surrounds the circular pattern formed by exit apertures 240. By discharging atomizing steam through exit apertures 258B, 268B on opposite sides of the cooling water discharge at exit apertures 240B, the cooling water is “jacketed” between two jets of atomizing steam, which ensures that all of the water is effectively atomized and no water is “bounced away” and escapes the steam jets.
The example nozzle sleeve 200 shown in
Referring to
A first fluid passage 330, which in the example shown allows the flow of atomizing steam through nozzle sleeve 300, is formed through body 302. First fluid passage 330 includes a first section 332 that is in fluid communication with an inlet 310 in first end 304 of body 302 and extends axially along body 302, preferably coaxial with the longitudinal axis of nozzle sleeve 300. First section 332 is in fluid communication with a first disk shaped cavity 344, which is offset from the longitudinal axis of nozzle sleeve 300 to provide space for second disk shaped cavity 372, discussed in more detail below. Cavity 344 is in fluid communication with a plurality of exit apertures 340B, which are formed through planar surface 329 of second end 306 and are positioned in a generally circular pattern.
Second and third fluid passages 350, 360, which in the example shown allow the flow of cooling water through nozzle sleeve 300, are also formed through body 302. Second and third fluid passages 350, 360 each have a first section 352, 362 that extends radially into middle section 312 of body 302 and are in fluid communication with annular groove 316. Second sections 354, 364 of second and third fluid passage 350, 360 extend parallel to longitudinal axis of nozzle sleeve 300 and are in fluid communication with first sections 352, 362. Second sections 354, 364 of second and third fluid passages 350, 360 are in fluid communication with and flow into annular cavity 370, which is formed in body 302 around first section 332 of first fluid passage 330. Annular cavity 370 is also in fluid communication with a second disk shaped cavity 372, for example through a cylindrical fluid passage section 374. Cavity 372 is in fluid communication with a plurality of exit apertures 358C, which are also positioned in a generally circular pattern such that each exit aperture 358C intersects a corresponding exit aperture 340B within body 302 to mix the cooling water and atomizing steam within body 302 of nozzle sleeve 300.
Nozzle sleeve 300, shown in
Referring to
A first fluid passage 430, which in the example shown allows the flow of cooling water through nozzle sleeve 400, is formed through body 402 and includes a first section 432 and a second section 434. First section 432 extends radially across middle section 412 of body 402 such that first section 432 is in fluid communication with annular groove 416. Second section 434 extends axially along body 402, preferably coaxial with the longitudinal axis of nozzle sleeve 400, and has a first end 436 that is in fluid communication with first section 432 and is spaced apart from first end 404 of body 402. A second end 438 of second section 434, opposite first end 436, is in fluid communication with exit aperture 440, which is formed through second surface 424 of second end 406 to discharge the cooling water into ring body 32. In the example shown, exit aperture 440 is an elongated slot that is generally linear and extends across second surface 424. Alternatively, exit aperture 440 could also be an elliptical aperture, similar to exit aperture 140A in
Second fluid passage 450, which in the example shown allows the flow of atomizing steam through nozzle sleeve 400, is also formed through body 402 and includes first and second sections 452, 454. First section 452 of second fluid passage 450 is in fluid communication with inlet 410 to allow the delivery of atomizing steam from conduits 40b into second fluid passage 450 and first section 452 extends generally parallel to the longitudinal axis of nozzle sleeve 400. Although a single first section 452 and a single inlet 410 are shown, any number of inlets can be used and any corresponding number of section to provide communication between the inlets and second section 454 can be used. In the example shown, first section 452 has a generally semi-circular cross-section and extend longitudinally along the side of first fluid passage 430. Second section 454 of second fluid passage 450 is generally cylindrical, extends generally parallel to the longitudinal axis of nozzle sleeve 400, and is in fluid communication with first section 452. Second section 454 of second fluid passage 450 surrounds second section 434 of first fluid passage 430 and is in fluid communication with exit aperture 458, which is formed through first surface 422 of second end 406 to discharge atomizing steam into ring body 32 on one side of exit aperture 440, and with exit aperture 468, which is formed through second surface 424 to discharge atomizing steam into ring body 32 on an opposite side of exit aperture 440. In the example shown, exit apertures 458, 468 are elongated slots that are generally linear and extend across first and second surfaces 422, 424. However, exit apertures 458, 468 could also be arcuately extending slots, similar to exit apertures 158A, 168A in
In addition to the benefits described above, the example nozzles sleeves shown in
Referring to
Referring to
Referring to
A desuperheater assembly, desuperheater, spray nozzle assemblies, nozzle sleeves, and/or components thereof according the teachings of the present disclosure in some applications are useful for reducing the temperature of superheated steam or other fluids or gases in a fluid pipe to a predefined set point temperature. However, the desuperheater assembly, desuperheater, spray nozzle assemblies, nozzle sleeves, and/or components thereof are not limited to the uses described herein and may be used in other types of arrangements.
The examples described and shown in detail herein are only exemplary of one or more aspects of the teachings of the present disclosure for the purpose of teaching a person of ordinary skill to make and use the invention or inventions recited in the appended claims. Additional aspects, arrangements, and forms of the invention or inventions within the scope of the appended claims are contemplated, the rights to which are expressly reserved.
This application is a continuation-in-part of U.S. patent application Ser. No. 16/133,298, entitled “Desuperheater and Spray Nozzles Therefor” and filed Sep. 17, 2018, which claims priority to U.S. Provisional Patent Application No. 62/681,981, entitled “Desuperheater and Spray Nozzles Therefor” and filed Jun. 7, 2018, the entire disclosures of which are hereby incorporated by reference herein.
Number | Date | Country | |
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62681981 | Jun 2018 | US |
Number | Date | Country | |
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Parent | 16133298 | Sep 2018 | US |
Child | 16386663 | US |