None.
This invention relates to injection nozzles for piping systems.
Piping systems in a variety of industrial settings are used to transport liquids and gases over a broad range of temperatures. In such piping systems, mixing of fluids of two different fluid streams may be necessary. In one example piping system, a first fluid at a first temperature in a first pipe may be continuously mixed with a second fluid at a second temperature in a second pipe to achieve a prescribed or desired mixing effectiveness. The temperature difference between the first fluid and the second fluid may be relatively large, and in some situations, mixing may actually be an injection of the first fluid in the first pipe into the second fluid in the second pipe. Because of the relatively large temperature differential that may exist between the first fluid and the second fluid, when such mixing or injecting occurs, a large temperature differential may be created within the pipe wall of the pipe receiving the injection of fluid. A relatively large temperature differential may result in unnecessary pipe repairs or replacements due to thermal stressing of the metal from which the pipe is constructed. To prevent the pipe wall of the pipe receiving the fluid injection from experiencing relatively large temperature fluctuations, improvement is needed. What is needed then is a device and method that permits maintaining a relatively small or no temperature differential along pipe wall sections in pipes that receive fluid injections at and near the location of the injections, without compromising mixing effectiveness of an injected fluid into a receiving fluid.
An injection system may include a first hollow pipe for carrying, directing or containing a first fluid, and a second hollow pipe for carrying, directing or containing a second fluid. The second hollow pipe passes through a wall of the first hollow pipe to approximately a centerline of the first hollow pipe. The second hollow pipe may have an end cap that protrudes beyond the centerline of the first hollow pipe. The second hollow pipe may define an outlet in a sidewall to permit the second fluid to flow from the second hollow pipe and into the first fluid. A longitudinal baffle may reside within the second hollow pipe. The longitudinal baffle within the second hollow pipe may extend through the wall of the first hollow pipe to beyond a centerline of the first hollow pipe. The longitudinal baffle may divide the first fluid into a first baffle flow (e.g. a flowing fluid) and a second baffle flow (e.g. a flowing fluid). The injection system may further include a transverse baffle that is attached to the longitudinal baffle. The transverse baffle may be arcuate and may protrude into the outlet. The transverse baffle may have a partial peripheral profile that is the same as a peripheral profile of the first hollow pipe. The transverse baffle may divide the opening (i.e. the outlet) into a first baffle flow outlet for the first baffle flow and a second baffle flow outlet for the second baffle flow. An area of the first baffle flow outlet may be 70 percent of the opening and an area of the second baffle flow outlet may be 30 percent of the opening.
An injection system may include a first hollow pipe through which a first fluid flows, and a second hollow pipe through which a second fluid flows. The second hollow pipe may define an opening proximate an end of the second hollow pipe. The second hollow pipe may reside through a wall of the first hollow pipe with the opening residing proximate a centerline of the first hollow pipe. A longitudinal baffle may reside within the second hollow pipe that defines a first baffle flow path and a second baffle flow path within the second hollow pipe for the second fluid. The injector system may further include a transverse baffle attached to the longitudinal baffle that divides the opening into a first baffle flow outlet and a second baffle flow outlet. An area of the first baffle flow outlet is 70 percent of the opening and an area of the second baffle flow outlet is 30 percent of the opening. The transverse baffle may further define two surfaces that are parallel to each other and that are perpendicular to surfaces of the longitudinal baffle. An end cap may enclose the end of the second hollow pipe. The first baffle flow path may reside between the end cap and the longitudinal baffle.
An injection system may include a first hollow pipe through which a first fluid flows, and a second hollow pipe through which a second fluid flows. The second hollow pipe may define an opening proximate an end of the second hollow pipe. The second hollow pipe may reside through a wall of the first hollow pipe with the opening residing proximate a centerline of the first hollow pipe. A longitudinal baffle residing within the second hollow pipe may define a first baffle flow path and a second baffle flow path within the second hollow pipe for the second fluid. A transverse baffle attached to the longitudinal baffle may divide the opening into a first baffle flow outlet and a second baffle flow outlet. An area of the first baffle flow outlet is greater than 50 percent of an area of the opening and an area of the second baffle flow outlet is less than 50 percent of the area of the opening. A first baffle flow (i.e. a fluid flow path) flows along a first side of the longitudinal baffle and the second baffle flow (i.e. a fluid flow path) flows along a second side of the longitudinal baffle, and the transverse baffle further defines two surfaces that are parallel to each other and that are perpendicular to surfaces of the longitudinal baffle. An end cap may enclose the end of the second hollow pipe. The first baffle flow path resides between the end cap and the longitudinal baffle. The transverse baffle has a partial peripheral profile that is the same as a peripheral profile of the first hollow pipe.
A more complete understanding of the present invention and benefits thereof may be acquired by referring to the follow description taken in conjunction with the accompanying drawings in which:
Turning now to the detailed description of the preferred arrangement or arrangements of the present teachings, inventive features and concepts, although presented in conjunction with
In one example of employing injector pipe 16, fluid 24 that flows downstream of injector pipe 16 will be cooled to a lower temperature than fluid 22, which is upstream of injector pipe 16. However, a challenge of using injector pipe 16 in any injection situation is to ensure that limited cooling or impingement of main pipe 12 occurs during injection. That is, no thermal impingement should occur, such as at interior wall area 28 downstream of injector pipe 16. A constant or nearly constant temperature at interior wall area 28 of main pipe should be maintained to prevent or limit thermal cycling of material of main pipe 12. A desired effect accomplished with the present teachings is to promote gradual mixing of the fluid of injector pipe 16 into main pipe 12 that causes a temperature change axially downstream of injector pipe 16 within main pipe 12 without causing undesired, large temperature differentials in main pipe 12, either axially or radially. Sudden or gross temperature changes in main pipe 12 are avoided with the present teachings.
To eliminate or greatly reduce impingement and its effects on main pipe 12, from injection by injector pipe 16, fluid 26 may be divided into a first baffle flow 30 and a second baffle flow 32 by a longitudinal baffle 34. Within injector pipe 16, longitudinal baffle 34 may extend past an outlet 36, also referred to as an opening, of injector pipe 16. A transverse baffle 38 may be fixed to longitudinal baffle 34 by a weld. When first baffle flow 30 flows along a first side surface 40 of longitudinal baffle 34 and a second baffle flow 32 flows along a second side surface 42 of longitudinal baffle 34, because transverse baffle 38 is fixed to longitudinal baffle 34, first baffle flow 30 is directed out of outlet 36 of injector pipe 16 on a first side 40 of transverse baffle 38 and second baffle flow 32 is directed out of outlet 36 of injector pipe 16 on a second side 42 of transverse baffle 38. Injector pipe 16 may have an end cap 44 to facilitate first baffle flow 30 in being directed completely around a tip end 46 of longitudinal baffle 34 to a first side of transverse baffle 38 to exit via outlet 36. End cap 44 may be arcuate, curved, or contoured on an interior surface to facilitate smooth flow of first baffle flow 30 of fluid 26 around tip end 46 of longitudinal baffle 34 within injector pipe 16. End cap 44 may be attached to injector pipe 16 by welding.
In accordance with the present teachings, dimensions of injection system 10 components as depicted in
In accordance with the present teachings, dimensions of injection system 10 components as depicted in
There are multiple advantages of the teachings of the disclosure. One advantage is that by dividing outlet 36 into first baffle flow outlet 68 and second baffle flow outlet 70, discharges from outlets 48, 50 impinge each other to facilitate mixing of a relatively colder fluid into a relatively hotter fluid without impinging a wall of main pipe 12, Because pipe walls will not be impinged or directly struck with a colder fluid, the service life of metal pipes will be increased, and maintenance downtime and replacement costs may be lowered. Injector pipe 16 may perform best in a horizontal or vertically rising portion of main pipe 12. Fluid 26 of injector pipe 16 may be a single phase or mist to be easily divided and may flow at 75-100 feet per second (23-30 meters per second). 100 feet per second (30 meters per second) may be the maximum flow rate through injector pipe 16.
The metallurgy of the injector pipe 16 may be adjusted according to service conditions such as temperature, fluid use, etc. Injector pipe 16 may be a minimum of schedule 40 pipe, and may be schedule 80 pipe. Outlet 36 may be centered with longitudinal centerline 20 in main pipe 12 in injection system 10. Width of outlet 36 may be 80% of the inside diameter of injector pipe 16, and the length of outlet 36 may be Pi (approximately 3.14) times the width of outlet 36.
Thus, without sacrificing mixing efficiency, the present teachings impart minimal thermal stresses in main pipe 12 due to minimal impingement of a relatively cold fluid 26 from injector pipe 16 into fluid 22 and interior wall of main pipe 12. While there may be many injector arrangement scenarios to prevent impingement of a relatively cold fluid 26 from injector pipe 16 against a wall of main pipe 12, such arrangements have an adverse effect on mixing efficiency when characterized by standard deviation of temperature as a function of downstream distance, as previously explained. In other words, the thermal profiles of other scenarios within main pipe 12 are not advantageous. For example, there are ways to achieve more thorough mixing, but such ways result in direct impingement of a relatively cold fluid within walls of a pipe into which injection is made. The present teachings eliminate or minimize direct thermal impingement without compromising mixing efficiency of a relatively cold fluid 26 from injector pipe 16 into a relatively hotter fluid 22 within main pipe 12. Another advantage of the injector system of the present teachings is its thermal and mixing effectiveness when injector pipe 16 discharges at different quench rates, which have been previously discussed. Moreover, the present teachings are applicable to vapor injection from injector pipe 16 and two-phase liquid-vapor mixture in main pipe 12. During analysis, a two-phase mixture in main pipe 12 contained less than 1% liquid by volume when injector pipe injected a 100% vapor stream. Thus, the present teachings are applicable for a vapor-vapor system, that is, from 99%-100% vapor from injector pipe 16 into a 100% vapor stream within main pipe 12.
Thus, an injection system 10 may include a first hollow pipe 12 for carrying, directing or containing a first fluid, and a second hollow pipe 16 for carrying, directing or containing a second fluid to be injected into first hollow pipe 12. The second hollow pipe 16 passes through a wall (i.e. hole 14 in the wall) of first hollow pipe 12 to approximately a centerline 20 of first hollow pipe 12. Second hollow pipe 16 may have an end cap 44 that protrudes beyond centerline 20 of first hollow pipe 12. Second hollow pipe 16 may reside through a wall of first hollow pipe 12 with outlet 36 residing proximate a centerline 20 of first hollow pipe 12. Second hollow pipe 16 may define an outlet in a sidewall to permit the second fluid to flow from second hollow pipe 16 and into the first fluid of first hollow pipe 12. Longitudinal baffle 34 may reside within second hollow pipe 16. Longitudinal baffle 34 within second hollow pipe 16 may extend through a sidewall of first hollow pipe 12 to beyond or past centerline 20 of first hollow pipe 12. Longitudinal baffle 34 may divide the first fluid into a first baffle flow (e.g. a flowing fluid) 30 and a second baffle flow 32 (e.g. a flowing fluid). That is, a first baffle flow (i.e. a fluid flow path) flows along a first side of the longitudinal baffle and the second baffle flow (i.e. a fluid flow path) flows along a second side of the longitudinal baffle. The injection system 10 may farther include a transverse baffle 38 that is attached to the longitudinal baffle 34. Transverse baffle 38 may be arcuate and may protrude into the outlet. The transverse baffle 38 may have a partial peripheral profile that is the same as a peripheral profile of first hollow pipe 12. Transverse baffle 38 may divide outlet 36 (i.e. the outlet) into a first baffle flow outlet 48 for the first baffle flow and a second baffle flow outlet 50 for the second baffle flow. Transverse baffle 38 may further define two surfaces 52, 53 that are parallel to each other and that are perpendicular to surfaces 40, 42 of longitudinal baffle 34. End cap 44 may enclose a tip end 46 of transverse baffle 38. First baffle flow 30 may occur between end cap 44 and longitudinal baffle 34. An area of the first baffle flow outlet 48 may be greater than 50 percent of an area of outlet 36 and an area of the second baffle flow outlet 50 may be less than 50 percent of the area of outlet 36. Alternatively, an area of the first baffle flow outlet 48 may be 70 percent of the area of outlet 36 and an area of second baffle flow outlet 50 may be 30 percent of the opening. The transverse baffle 38 may have a partial peripheral profile (e.g. an arcuate profile) that may be the same as a peripheral profile (e.g. an arcuate profile) of the first hollow pipe 12.
It should be noted that the discussion of any reference is not an admission that it is prior art to the present invention, especially any reference that may have a publication date after the priority date of this application. At the same time, each and every claim below is hereby incorporated into this detailed description or specification as additional embodiments of the present invention.
Although the systems and processes described herein have been described in detail, it should be understood that various changes, substitutions, and alterations can be made without departing from the spirit and scope of the invention as defined by the following claims. Those skilled in the art may be able to study the preferred embodiments and identify other ways to practice the invention that are not exactly as described herein. It is the intent of the inventors that variations and equivalents of the invention are within the scope of the claims while the description, abstract and drawings are not to be used to limit the scope of the invention. The invention is specifically intended to be as broad as the claims below and their equivalents.
This application is a non-provisional application which claims benefit under 35 USC§119(e) to U.S. Provisional Application Ser. No. 61/692,805 filed Aug. 24, 2012, entitled INJECTOR NOZZLE FOR QUENCHING WITHIN PIPING SYSTEMS, which is incorporated herein in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
1734164 | Faber | Nov 1929 | A |
2392542 | Matuszak | Jan 1946 | A |
3966174 | Deve | Jun 1976 | A |
4812049 | McCall | Mar 1989 | A |
5452955 | Lundstrom | Sep 1995 | A |
6082713 | King | Jul 2000 | A |
6422735 | Lang | Jul 2002 | B1 |
6427671 | Holze | Aug 2002 | B1 |
8033714 | Nishioka | Oct 2011 | B2 |
8342486 | Smith | Jan 2013 | B2 |
20100226198 | Kapila | Sep 2010 | A1 |
Number | Date | Country | |
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20140056098 A1 | Feb 2014 | US |
Number | Date | Country | |
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61692805 | Aug 2012 | US |