DE353224C - Steam operated, single or multiple air extractors for underwind firing - Google Patents

Description

lYtit steam-powered, single or multiple air extractors for Underwinding. At Aden, steam-operated air extractors for underwind firing the steam jets out of a nozzle into the surrounding air duct and blows Air drawn in as a mixture with vein: through several air supply nozzles - through. The sudden and considerable increase in cross-section every time Exit of the steam jet:. Into the space of the air nozzles enveloping it and their Walls, some of which act as baffles, require a considerable amount Energy reduction of the steam jet. Therefore, such air suckers have a relative high steam consumption and low efficiency. This shows up cheaper at such nozzles: which blow out without air intake and avoiding baffles, ! gradually widening walls., at the same time also contain spiral ribs, those, gradually transforming the just emerging jet into the helical shape .. But even with such nozzles the degree of effectiveness must decrease immediately when they are in contact with air supply nozzles enveloping the nozzle.

The invention improves the effect of the steam jet nozzles. that the air is introduced into a hollow cone-shaped emerging steam jet. The air dilution that arises in the hollow steam cone is used for suction the air used completely without impact effects, especially since the transition is dreary Steam jet from its hollow cone shape, into the connecting lines or into . a subsequent nozzle takes place only gradually. Since the introduction of the air at a In most cases, it is advisable to use the steam jet conductive jacket at a point located behind the steam nozzle a cross-sectional constriction to give to increase the flow rate. and already once with air mixed steam out exit a second hollow cone-shaped nozzle allow. This sucks in air again inside or inside and outside. With a Such an air intake nozzle is a better use of the energy of the steam jet and a more uniform mixture of steam and air can be achieved.

The drawing shows two embodiments of the invention in Fig. i and 2 in longitudinal section. Fig. 3 shows the developed surface of the rib curvature.

According to Fig. I, the steam is fed to the suction nozzle through a pipe a, from which it passes into a hollow cone-shaped nozzle b, which is covered with ribs b '. These have -like A'bb. 3 shows, first of all, the axial direction according to the arrows v, in which they intercept the steam and divide it into individual strands, in order to then release it in a spiral shape into the mixing chamber f in the direction of the arrows w . The air is supplied through a connecting pipe d and first enters the air nozzle c through one or more channels c, which, if necessary, can be divided into several ring jets by insert funnels e. The air nozzles c and e can also contain ribs with the curvature shown in Fig. 3. However, the ribs should have the same direction and curvature as the ribs b ', so that the air jets sucked in by the steam should be. Insert freely into the steam jet, i.e. when exiting the air nozzle, do not have a direction that deviates from the direction of the steam strands. The mixing chamber f forms a guide surface jacket for the steam jet and the sucked in air, which narrows in cross section to increase the flow energy after its exit and opens into a second jet nozzle g. Contributing to the narrowing of the cross-section are: the mixing chamber f, channels h ' reaching in helically, which pass into the air nozzle h. The nozzles g and h also contain ribs g ', which either merge from the straight direction into .die spiral curvature and are of the same turn as the ribs b', if the steam air flow should already have lost its screw movement with a greater length of the mixing chamber f or the ribs g 'enter the steam air stream with a curvature which corresponds to its direction as it enters the nozzle g. The steam-air mixture coming from the mixing chamber f sucks in air for the second time when it leaves the nozzle g! passes into the exhaust pipe k, which leads into .den ash chamber.

In the example according to Fig. 2, in addition to the inner air supply through the nozzles c, e there is also an outer air supply. For this purpose, the mixing chamber f is connected to the air chamber d ' at the mouth of the steam nozzle b via channels l . They can be pierced by ribs l 'in order to allow the air to pass in strands in the form of strands into the exiting steam jet, which after exiting the nozzle b through the evenly curved inner wall of the mixing chamber f with the sucked air into the following Nozzle g is passed over. Here, too, there is a narrowing of the cross-section to increase the flow energy. In addition to a central air supply through: the air nozzle h, the nozzle g also contains channels m on the circumference for the air inlet, which, in a similar manner as described above, are pierced by ribs which run out in a spiral shape in the second mixing chamber i.

The sucked in air is appropriately preheated so that it can release the steam jet cools down as little as possible. The outlet edges of the nozzles are sharpened to avoid edge turbulence and to avoid associated energy losses. as well as in all places next to Gradual change of direction of the jet also: an unconstrained entry of the air in the steam jet.

Claims (2)

PATENT CLAIMS: i. Steam operated single or multiple Air extractor for underwind firing, in which the steam jet emerging from a nozzle or -the steam-air mixture through in its flow direction: beginning concurrently Ribs are gradually transferred into 'the spiral duct, characterized by that the air in the cone-shaped steam jet or steam air jet exiting is introduced. 2. Air extractor according to claim i, characterized in that @ that the Hollow cone-shaped steam jet or steam air jet through in the direction of flow channels (L) penetrating its guide surface jacket (f) also draws in air from the outside.