NO316680B1 - Nozzle - Google Patents

Abstract

A nozzle comprising a nozzle body (200, 400; 6, 8) provided with a number of groups of openings (220, 225) arranged around the circumference. A turbine wheel (300; 7) is arranged in a chamber in the nozzle housing, where the turbine wheel divides an inner chamber into an inlet (120) and an inner chamber. (210). The turbine wheel is arranged to be able to rotate together with the nozzle body in order thereby to be able to obtain a further increase in pressure than that known from other nozzles.

Description

The invention relates to a nozzle as stated in the introduction to independent claim 1.

A large number of injection devices are known. A number of devices are known for finely distributing water by a certain form of atomization.

NO-B-176748 describes a nozzle for atomizing water for fire-fighting purposes, where a ring of nozzle channels is rotatably mounted on a nozzle holder which is adapted to direct water from a house via a channel and holes, to an annular groove at the nozzle channels inlet. The ring is designed to rotate under the influence of reaction force from water flowing through the nozzle channels. This patent states in the introductory part that when extinguishing fires, it has "... proven effective to use finely divided water droplets, almost in the form of a fog, which settles over the flames".

US 4,272,024 shows a nozzle with a rotating outlet head where a turbine is arranged between the supply channel and the outlet head, which drives the outlet head. US 5,433,383 shows a nozzle for producing water mist with a turbine driven by the water, which sets the water in a rotating motion.

NO-C-178819 describes a high-pressure water spray gun for firefighting, designed with a cylindrical body for connection to a water hammer and a spray head which is rotatable in the body under the influence of water exiting through a pair of jet nozzles around the barrel of the spray head. In each pair, the nozzle axes converge and the nozzles are closest to each other in a mixing region at or just outside the outer surface of the barrel. At least one nozzle has a non-radial axis. The spray head can be engaged in the body and can be moved to an exposed working position under the influence of the water pressure, against the action of a spring.

US 4,393,941 describes a body for extinguishing pipe fires, comprising a cylindrical nozzle housing with an axially extending supply channel and a number of radial nozzles along the supply channel. One end of the nozzle housing is shaped like a point and the housing has a large bulk and thus a relatively large weight, so that it can penetrate material and reach the fire.

Norwegian patent application 20005039 describes a nozzle set which is characterized by the fact that it is equipped with a number of channels (301) which run through the nozzle cover in the plane of rotation of the nozzle set but at an angle in relation to the radius of the nozzle cover, where each channel has a vane-shaped opening towards an inner chamber.

On the basis of this state of the art, the invention proposes a nozzle which includes a hollow nozzle body rotatably placed at the end of a supply channel, where the nozzle body and the supply channel form an inner chamber and an inlet and an outer chamber; which nozzle body is equipped with at least two openings arranged around the circumference of the nozzle body, the openings being arranged in pairs and where the openings in each pair have their axes closest to each other in a mixing area near the outer surface of the nozzle body; wherein said inner chamber is in fluid communication with said openings via a number of internal channels in said nozzle body and the outer chamber; where the inner channels form a fluid connection between the inner and outer chamber and run through the nozzle body at an angle in relation to the nozzle body's radius vector in a plane perpendicular to the nozzle body's axis of rotation. The nozzle according to the invention is characterized by the fact that a paddle wheel is arranged as a boundary between the inner chamber and the inlet, which paddle wheel is arranged to be able to rotate together with the nozzle body and about an axis which is parallel to the longitudinal axis of the supply channel.

With the paddle-shaped channel opening known from Norwegian patent application 20005039, the same effect is achieved as with the nozzle device described in NO-C-178819, but at a significantly lower pressure. The nozzle according to the invention uses the same principles as described in these publications, namely water crushing (NO-C-178819) and pressure increase (NO 20005039), but shows a further increase in pressure due to the paddle wheel.

Further features of the invention will appear from the independent patent claims 2-9.

Embodiments of the invention will now be described in more detail, with reference to the drawings, where: Figure 1 shows a sectional view of a simplified nozzle according to an embodiment of the invention. Figure 2 shows a section along the line A-A in Figure 1. For illustrative purposes, only four channels are shown. Figure 3 shows a section along the line B-B in Figure 1. For illustration reasons, only two channel pairs are shown.

Figure 4 shows an embodiment of the paddle wheel according to the invention in various sections.

Figure 5 shows speed and power diagrams for a number of turbine blades, as well as relevant variables. Figure 6 shows pressure increase as a function of circulation number for different amounts of water, at the impeller and in the inner chamber. Figure 7 shows pressure increase as a function of circulation number for different amounts of water, in the outer chamber of the nozzle. Figure 8 shows an exploded view of a second embodiment of the invention, and illustrates an alternative mounting of the nozzle according to the invention.

A first embodiment of the invention will now be described, particularly with reference to figures 1-5. A nozzle including a hollow nozzle housing 200 with an insert 400 is rotatably placed around a supply channel 100 with an inlet 120. The nozzle housing and the insert are in the assembled state fixed to each other and for all practical purposes in use can be considered as one nozzle body (200,400). The nozzle body and the supply channel together form an inner chamber 210 and an inlet 120, where both the inner chamber and the inlet are in fluid communication with each other. The nozzle body (here: the nozzle housing) is equipped with a number of groups of openings 220,225 arranged around the circumference (two pairs are shown in Fig. 3 for illustrative purposes), the two openings in each group having their axes closest to each other in a mixed area near the outer surface of the nozzle housing. The inner chamber 210 is in fluid communication with said openings via a number of inner channels 420 (four channels are shown in Fig. 2 for illustrative purposes) in said insert 400 and an outer chamber 250; each one of the inner channels 420 runs through the insert in the plane of rotation of the nozzle preferably at an angle 6 in relation to the radius of the insert and the nozzle housing. The angle 8 (see Fig. 2) can be between 20° and 70°, preferably 50°.

Furthermore, a paddle wheel 300 is arranged in the nozzle body, where the paddle wheel forms a boundary between the inner chamber 210 and the inlet 120. The paddle wheel 300 is arranged to be able to rotate together with the nozzle body, usually fixed in it, and in a plane which is mainly parallel to the plane of rotation of the nozzle body and mainly normal to the longitudinal axis of the supply channel 100.

As can be seen from, among other things, Figures 2 and 5, the impeller 300 includes a number of blades 310 arranged at an angle a + 6 in relation to the plane of rotation of the impeller. The sum of a + B is between 20° and 70°, preferably 50°.

The nozzle body also includes an opening 410 from the inner chamber 210 towards the atmosphere, and the longitudinal axis of this opening is mainly but not necessarily parallel to the axis of rotation of the nozzle. The opening 410 may be a venturi nozzle.

With the paddle-shaped channel opening known from Norwegian patent application 20005039, the same effect is achieved as with the nozzle device described in NO-C-178819, but at a significantly lower pressure. The nozzle according to the invention uses the same principles as described in these publications, namely water crushing (NO-C-178819) and pressure increase (NO 20005039), but exhibits a further pressure increase due to the vane wheel which acts as a pressure barrier between the inner chamber 210 and the inlet 120. For-search has shown that the pressure in the inlet, due to the paddle wheel, is kept approximately constant when the nozzle housing-insert-paddle wheel rotates around the supply channel. The rotational torque that is achieved at the nozzle outlet 220,225 is just so great that the paddle wheel can achieve a rotational speed of more than 2000 RPM, which in turn gives the desired pressure.

Figure 5 shows velocity and power diagrams for a number of turbine blades 310, with velocity components u and c and the resulting velocity component v, describing an angle cc+P with the blade and a plane respectively. Figure 5 also shows the lifting force LS and the resistance force DS that are generated for the blade. Moments generated by the nozzles along the periphery go into the paddle nozzle to overcome friction and push up the water in the paddle wheel or turbo wheel. This impeller would be equivalent to an axial pump consisting of a cascade of straight vanes. The lift (LS) is calculated in a known manner on the basis of the vane's lift coefficient, geometric properties, the density of the fluid and the velocity (v) squared. The calculations for the resistance are similar.

The torque generated by the nozzles along the periphery helps overcome friction and push up the water in the turbo wheel. The turbo wheel will thus be comparable to an axial pump consisting of straight vanes. The torque generated is:

where: p = density of water

g = 9.81 W

H = lifting height (m)

Qt = volume flow through the nozzle after the impeller B ■ co1 = the friction torque

The lift generated on such a straight blade is given as:

The lift from the impeller is then for a straight cascade given as:

where: p = density of water

g = 9.81 V2

H = lifting height (m)

Qt = volume flow through the nozzle after the impeller Bo2 = the friction torque

CL = the lift coefficient

/ = blade length

The angles a and /? can be seen from figure 5.

The resistance through the outlet nozzle after the turbo wheel can be written in the same way as for the peripheral nozzles:

The pressure drop through the turbo passage then becomes:

This is illustrated in Figures 6 and 7, both of which show theoretically calculated values for pressure increase as a function of circulation number. Figure 6 shows pressure increase as a function of circulation number for different amounts of water (volume flows), at the impeller and in the inner chamber where H is the lift height in metres. Figure 7 shows a pressure increase as a function of circulation number for different amounts of water (volume flows) in the nozzle's outer chamber.

Figure 8 shows a second embodiment of the invention, but with the main emphasis on illustrating how the nozzle according to the invention can be mounted in an extinguishing unit. The figure shows the nozzle housing 6 (corresponding to 200), the supply channel 5 (corresponding to 100), the vane wheel 7 (corresponding to 300), and the insert 8 (corresponding to 400) with internal channels 8a (corresponding to 420).

The nozzle housing with supply channel can be mounted on one of the piston halves 4. By means of a locking ring 3, spring 11, and a second piston part 2, the nozzle according to the invention can be moved by water pressure and spring force out of and into a protective housing 1 The one piston half 2 has recesses for o-rings 9 and 10. The nozzle housing 6 does not show the openings (corresponding to 220, 225). The table below indicates the connection between the two versions.

Component list

Claims (9)

1. Nozzle including a hollow nozzle body (200,400; 6,8) rotatably located at the end of a supply channel (100; 5), the nozzle body and the supply channel forming an inner chamber (210) and an inlet (120) and an outer chamber (250); which nozzle body is equipped with at least two openings (220,225) arranged around the circumference of the nozzle body, the openings being arranged in pairs and where the openings in each pair have their axes closest to each other in a mixing area near the outer surface of the nozzle body; wherein said inner chamber (210) is in fluid communication with said openings via a number of internal channels (420; 8a) in said nozzle body (400; 8) and the outer chamber (250); where the inner channels form a fluid connection between the inner and outer chamber and run through the nozzle body at an angle (9) in relation to the nozzle body's radius vector in a plane perpendicular to the nozzle body's axis of rotation, characterized in that a paddle wheel (300; 7) is arranged which a boundary between the inner chamber (210) and the inlet (120), which paddle wheel is arranged to be able to rotate together with the nozzle body and about an axis which is parallel to the longitudinal axis of the supply channel (100; 5). 2. Nozzle according to claim 1, characterized in that the impeller (300; 7) includes a number of blades (310) arranged at an angle (a + B) in relation to a plane which is perpendicular to the axis of rotation of the impeller. 3. Nozzle according to claim 2, characterized in that said angle (a + B) is between 20° and 70°. 4. Nozzle according to claim 3, characterized in that said angle (a + B) is 50°. 5. Nozzle according to claim 1, characterized in that the nozzle body includes an insert (400; 8) adapted to be placed in one of the outer parts of the nozzle housing (200; 6). 6. Nozzle according to claim 1, characterized in that the nozzle body includes an opening (410) from the inner chamber (210) towards the atmosphere, the longitudinal axis of which opening is mainly parallel to the axis of rotation of the nozzle. 7. Nozzle according to claim 6, characterized in that said opening (410) is a venturi nozzle. 8. Nozzle according to claim 1, characterized in that the angle (9) is between 20 and 70° 9. Nozzle according to claim 8, characterized in that the angle (8) is 50°