The invention relates to a solid cone spray nozzle, particularly for atomizing or spraying low viscosity liquids for cooling purposes in billet or bloom continuous casting installations, having a mouthpiece, an outlet chamber and an outlet opening emanating from the outlet chamber and having a smaller cross-section than the latter.
European patent EP 1243343 B1 discloses a two-fluid solid cone spray nozzle for cooling in continuous casting installations. A mouthpiece of said nozzle has an outlet chamber with an outlet opening emanating from the outlet chamber and having a smaller cross-section of the latter. In the outlet chamber formed by a bore in the mouthpiece is placed a swirl insert with which the gas-liquid mixture is rotated before reaching the outlet opening, so that it can then pass under pressure and in conical form out of the mouthpiece. The swirl insert has several bores or circumferentially positioned milled slots uniformly distributed around the circumference. Upstream of the swirl insert and optionally separated from the mouthpiece by an extension tube is provided a mixing chamber in which a gas flow and a liquid flow vertically strike against one another and are consequently mixed. As a result of the characteristic rotation of the gas-liquid mixture before reaching the outlet opening, it is not possible to obtain in a satisfactory manner shapes other than circular spray cone shapes.
International patent specification WO 99/25481 discloses a slot nozzle for cooling in continuous casting installations. This slot nozzle is intended to give an oval spray cone shape. For this purpose a mouthpiece has an outlet chamber with an outlet opening, which has a smaller cross-section than the outlet chamber, the outlet opening having an oval cross-section. Upstream of the outlet opening the outlet chamber contains a crossbar, which on either side leaves a circular segmental outlet opening, which is symmetrical to the centre of the outlet chamber. Thus, liquid flows only pass through the crossbar on the sides of the outlet chamber. The outlet chamber wall is so shaped in the vicinity of the outlet opening that the liquid flows meet at or directly upstream of the outlet opening in a range between 60 and 130ø. This creates the prerequisites for the impacting of the two liquid flows to give rise to the formation of liquid droplets leaving the outlet opening with a particularly high kinetic energy.
In general, in continuous casting installations and in particular in billet or bloom casting installations there is a need to produce a solid cone spray jet for cooling the continuously cast products, whose shape need not be circular in the case of a uniform liquid distribution because, in the case of billet or bloom continuous casting installations, unlike in the case of slabs with a very flat rectangular cross-section, the continuously cast products have an aspect ratio of 1:1 to approximately 2.5:1. Thus, even shortly after leaving the ingot mould, the continuously cast products are much more stable than slabs which are 0.8 to 3.5 m wide. Thus, in billet or bloom continuous casting installations, the spacing of the guide rollers after leaving the ingot mould can be made larger than in slab continuous casting installations. Due to the larger roller spacing in part more cooling nozzles must be used in order to cool the entire space between two mutually spaced guide rollers. In the case of a given water quantity to be applied, this leads to smaller nozzle cross-sections and therefore to an increased clogging risk. If the gap between two guide rollers is not completely covered by a spray jet, it is possible in the area not covered by said jet for there to be a reheating of the casting shell of the continuously cast product, so that cracks can arise in the said shell. Due to the larger roller spacing it would therefore be desirable to have spray nozzles with an oval spray cone, so that it would be possible to completely cover the surface of the continuously cast product in the gap between two guide rollers with a single spray nozzle and simultaneously to essentially only spray the continuously cast product in the transverse direction of the latter.
The invention aims at providing a solid cone spray nozzle, particularly for spraying or atomizing low viscosity liquids for cooling purposes in billet or bloom continuous casting installations, where there is a homogeneous liquid distribution and low clogging or blockage sensitivity.
For this purpose the invention provides a solid cone spray nozzle, particularly for atomizing low viscosity liquids for cooling bloom or billet continuous casting installations, having a mouthpiece with an outlet chamber and an outlet opening emanating from said outlet chamber and having a smaller cross-section than the latter, in which an inlet opening into the outlet chamber has a smaller cross-section than the latter and in which upstream of the inlet opening in the outlet chamber is provided a web-like preatomizer element which is at least partly struck by the fluid jet after entering the outlet chamber.
With such a nozzle it is possible to produce a solid cone spray jet with a cross-section diverging from a circular shape and in particular having an oval shape, accompanied by a uniform distribution, the web-like preatomizer element on the one hand preventing an entering fluid flow from penetrating through to the outlet opening and on the other ensures a fundamental tearing open of the fluid jet. As there is no longer a characteristic rotation of the fluid jets in the outlet chamber, non-circular cross-sectional shapes of a solid cone jet can be produced with a uniform distribution. This leads to a uniform fluid distribution in the spray cone in the case of a shapable cross-section of said spray cone and at the same time large passage cross-sections are obtained in the spray nozzle so as to ensure a limited clogging risk.
According to a further development of the invention at the transition of the inlet opening into the outlet chamber there is a sudden cross-sectional widening of a flow channel.
Due to such a sudden cross-sectional widening the flow rate is reduced, so that a pressure drop occurs and as a result the boundary conditions are created for tearing open the fluid jet entering the outlet chamber. For example, the inlet opening is provided in a panel and has a radius of 2.5 mm. The outlet chamber can then e.g. have a radius of about 6mm and even with a more limited cross-sectional widening, e.g. a double widening an adequate effect can occur.
According to a further development of the invention a determination of the discharged fluid volume flow takes place by means of the inlet opening cross-section. Thus, a discharged fluid volume flow can be adapted easily by modifying the inlet opening without significantly impairing the spray pattern of the spray nozzle. Advantageously the inlet opening is provided in a panel, so that by replacing the panel a different fluid volume flow can be obtained.
According to a further development of the invention the spray cone is shaped by the outlet opening and optionally by means of an outlet cone connecting onto the outlet opening.
Through the differing shaping of the outlet opening and optionally an outlet cone in the nozzle housing, this makes it possible to obtain the spray cone shapes necessary for a special application. The outlet cone or frustum in the mouthpiece housing can have a random cross-sectional shape which is not circular. Since in the case of the nozzle according to the invention the tearing open and atomizing of an entering fluid jet takes place in the preatomizer and the outlet chamber, the outlet opening shape can be changed without fundamentally modifying a liquid distribution within the spray cone by modifying the outlet opening shape.
According to a further development of the invention the outlet opening has an oval cross-sectional shape and advantageously a widening outlet cone with an oval cross-section is connected to the outlet opening in the outlet direction.
In this way it is possible to obtain a solid cone jet with an oval cross-section particularly advantageous for cooling purposes in billet or bloom continuous casting installations. Unlike in known spray nozzles with an oval spray cone a very regular spray cone shape can be obtained, because also in the marginal areas of the oval spray cone there are no distortions as a result of a significant rotational energy of the spray droplets about a central axis of the nozzle. The term oval or oval shape is understood to mean an elliptical shape, but also an oval shape in the strict sense, i.e. two semicircles linked by straight lines.
According to a further development of the invention the web-like preatomizer element with its longitudinal direction extends substantially perpendicular to an entering fluid jet through the outlet chamber, the longitudinal direction relative to a longer axis of the oval outlet opening being at an angle between 0 and 360ø, particularly 90ø.
It has surprisingly been found that also when providing an oval outlet opening the preatomizer element can be placed at different angular positions with respect to a longitudinal axis of the outlet opening. It has surprisingly been found that it is particularly advantageous to place the web-like preatomizer element at an angle of 90ø to the longer axis of the oval outlet opening.
In a plane perpendicular to the outlet direction, the outlet chamber has an oval cross-section in a further development of the invention.
Such an oval shaping of the outlet chamber can e.g. serve to permit the insertion of the preatomizer element in a single, previously defined position. A longitudinal axis of such an oval outlet chamber can be parallel or also perpendicular to the longitudinal axis of an oval outlet opening.
According to a further development of the invention the inlet opening is located in a panel which is inserted in a mouthpiece housing.
This makes it possible to change the size of the inlet opening by replacing the panel, e.g. in order to match the spray nozzle to the intended use.
According to a further development of the invention the web-like preatomizer element is provided on a U-clip or stirrup, which is inserted in a mouthpiece housing.
In this way, by replacing the stirrup, it is e.g. possible to vary a distance between the preatomizer element and inlet opening, as well as the outlet opening, so as to adapt the nozzle to an intended use.
According to a further development of the invention the panel and stirrup are provided on an integral insert.
In this way the nozzle can be constructed from a few and in particular only two parts, namely the mouthpiece housing with the outlet chamber and the outlet opening and the insert with the panel with the inlet opening and the stirrup with the preatomizer element. It is also possible to ensure a precise spacing between the preatomizer element and the inlet opening.
According to a further development of the invention the preatomizer element is constructed as a web having a rectangular cross-section, a narrow side of the rectangle facing the inlet opening.
The narrow side of the rectangle consequently forms an impact surface for at least part of the fluid jet entering through the inlet opening. If the narrow side is narrower than the inlet opening an entering fluid jet is split into three partial flows. A first partial flow impacts on the preatomizer element and two other partial flows pass through the preatomizer element on the right/left side. The preatomizer element can be of the same width as the inlet opening, so that then there is no subdivision into partial jets and instead the entire entering fluid jet impacts on the preatomizer element.
According to a further development of the invention the web-like preatomizer element is constructed as a round bar or rod extending transversely through the outlet chamber.
This leads to a very simple, but effective construction. By the provision of a bore in the mouthpiece housing, a rod can be inserted and fixed in the same.
According to a further development of the invention an impact surface of the web-like preatomizer element facing the inlet opening is curved outwards towards the latter, planar or constructed in the form of an inner face of a depression in the preatomizer element.
This makes it possible to influence the tearing open of the entering fluid jet at the preatomizer element. The depression can have a conical or spherical shape.
According to a further development of the invention the outlet opening is located in an outlet chamber bottom, the inner walls of the outlet chamber meeting in an imaginary centre of the outlet opening at an angle between 140 and 180ø, particularly between 170 and 180ø.
Such a chamber bottom construction contributes to a uniform fluid distribution in the spray jet and to a shapability of the spray jet cross-section by modifying the outlet opening shape.
The chamber bottom can be spherical or planar and the outlet chamber side walls can be perpendicular to the planar chamber bottom or at an angle of less than 90ø on said planar chamber bottom. The side walls can in a sectional view be curved or straight.
According to a further development of the invention the chamber bottom is formed by a displacement of a milling or drilling tool, particularly a ball end drill in at least one lateral direction.
This e.g. makes it possible to obtain an oval outlet chamber cross-section.
According to a further development of the invention a mixing chamber for liquid and gas is provided upstream of the inlet chamber.
In this way the solid cone spray nozzle according to the invention can be used as a two-fluid nozzle, e.g. for spraying an air/water mixture. For an entry of a liquid flow, the mixing chamber can be constructed perpendicular to a gas flow the flow direction from the mixing chamber to the mouthpiece being substantially perpendicular to the liquid flow entry direction into the mixing chamber.
This leads to a uniform mixing of the gas flow and the liquid flow.
According to a further development of the invention an extension tube is located between the mixing chamber and mouthpiece.
Thus, the mouthpiece of the solid cone spray nozzle according to the invention can be moved close to the location to be subject to the action of the spray jet even with constricted space conditions, e.g. in continuous casting installations.
Further features and advantages of the invention can be gathered from the following description in conjunction with the drawings. The drawings show different embodiments of the invention with in each case different individual features. Within the scope of the invention individual features from different embodiments can be combined without leaving the scope of the invention. In the drawings show:
The perspective view of
Mouthpiece housing 12 has a generally cylindrical shape and is provided at its rear end for connection to a fluid supply line with a circumferential flange 18. Flange 18 is laterally provided with flattenings 20, but in the view of
The sectional view of
Insert 28 has a circular panel 30 in which is provided the inlet opening 26, as well as a U-clip or stirrup 32 emanating from the circular panel 30 and extending in the direction of outlet opening 24 into outlet chamber 22.
A crossbar 34 is provided on insert 28 opposite to inlet opening 26. Crossbar 34 forms a preatomizer element on which impacts a fluid jet entering through inlet opening 26.
The perspective view of
The view of
The cylindrical outer shape of mouthpiece housing 12 can be gathered from the side view of
The sectional view of
The view of
The perspective view of
Insert 28 of
The perspective view of
Another alternative embodiment is shown in the perspective view of
The perspective view of
The perspective view of
The sectional view of
The sectional view of
In the side view of
In the case of the inventive spray nozzle 10, a fluid volume flow through outlet opening 24 is determined by the size of the inlet opening in the insert panel. Outlet opening 24 and the outlet cone 14 connecting onto outlet opening 24 are then responsible for the shaping of the spray cone. Thus, the spray nozzle according to the invention can be manufactured with different shapes for the outlet openings and outlet cones, so that the spray cone shape required for a given application can be obtained. As the discharged fluid volume flow is determined by the inlet opening in the panel, such an outlet opening shape adaptation does not lead to a change in the discharged fluid volume flow. Conversely the discharged fluid volume flow can be adapted by modifying the panel, without significantly modifying the shape of the discharged spray cone.
It is also pointed out that the inventive spray nozzle 10 has large passage cross-sections and is consequently little sensitive to clogging. The solid spray cone with an oval cross-section produced by spray nozzle 10 is produced by a single outlet opening 24 and the panel also has a single, cross-sectionally large inlet opening.
The sectional view of
The spray nozzle 80 is also not very sensitive to clogging and is easy to manufacture, because rod 86 and panel 90 can be manufactured as simple turned parts.
The view of
Number | Date | Country | Kind |
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10 2005 047 195 | Sep 2005 | DE | national |
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Number | Date | Country |
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2 252 218 | May 1973 | DE |
31 31 070 | Apr 1982 | DE |
34 29 411 | Feb 1986 | DE |
1 047 504 | Nov 2000 | EP |
1 243 343 | Sep 2002 | EP |
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Number | Date | Country | |
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20070069049 A1 | Mar 2007 | US |