FI83751C - DYSPROPELLER. - Google Patents

Description

83751

NUT PROPELLER - DYSPROPELLER

The invention relates to an extruder according to the preamble of claim 1.

In an extruder, in which a cylindrical nozzle surrounds the actual propeller, a considerably better thrust is achieved compared to conventional propeller equipment. The disadvantage of a nozzle propeller can be considered to be the tendency to clog when a large ice floe hits it and stays in front of the nozzle, preventing water from entering the propeller. As a result, the thrust produced by the propeller is reduced and the propeller blades, shaft and bearings are then subjected to high stresses.

In connection with nozzle propellers, device arrangements are already known which have been used to prevent ice from penetrating the nozzle. A solution is known in which a protective cage is placed in front of the propeller. Although the guard cage prevents larger objects from passing inside the nozzle, it causes high flow resistance, thus reducing the efficiency of the propeller. A disadvantage of safety net solutions can also be considered that the network is easily clogged with ice.

An apparatus solution is also known in which fins attached at one end to the hull and at the other end to the nozzle ring are used in front of the propeller nozzle. The disadvantage in this case is the high flow resistance caused by the protective shields. In this solution, the shields are located at their leading edges of the flow approximately perpendicular to the flow. Large pieces of ice then get caught in the fins and thus clog the nozzle.

An apparatus solution is also known in which the propeller nozzle is shaped on its inner surface such that the tip of the propeller blades crushes a block of ice wedged between the propeller blade and the nozzle. These internal irregularities in the nozzle. acting as anti-wedge parts and ice crushing blades 2 83751. The propeller nozzle may also be formed such that the leading edge of the nozzle is pulled back at at least one point so that the leading edge of the propeller blades at said point extends in front of the leading edge of the nozzle. This arrangement prevents the ice cubes from stacking against the leading edges of the nozzle. A disadvantage of the solution is that the arrangement does not prevent the passage of ice fragments inside the nozzles, but the ice blocks entrained inside the nozzle must be crushed by the work performed by the propeller, whereby the propulsion efficiency is reduced.

The object of the invention is to provide an extruder arrangement which avoids the above-mentioned disadvantages of the prior art and in which the solution prevents the entry of ice floes into the nozzle from the front or behind. It is therefore an object of the invention to provide an extruder which maintains thrust even in difficult conditions and which prevents the passage of large ice floes into the nozzle, thus preventing stresses on the propeller, its shaft and bearings of large ice floes and reducing the adverse effects caused by large ice floes. It is a further object of the invention to provide a nozzle propeller in which the adverse effects caused by an ice floe blocking the nozzle are reduced so that the propeller device always has one flow path free of ice, allowing flow inside the propeller nozzle.

The object of the invention is achieved by a solution according to claim 1.

In a preferred embodiment, the nozzle protective members comprise a plurality of solid ice spikes projecting from the front edge of the nozzle and having an ice cutting or crushing leading edge. The ice spikes are fitted to the front and / or rear edge of the nozzle of the nozzle disc discipline so as to cause the lowest possible flow resistance. The ice spikes are attached to the nozzle, for example by welding. The length of the ice spikes is only a small fraction of the length of the nozzle.

I: 3 83751

When the nozzle is equipped with ice crushing ice spikes, the additional material costs are low.

In another embodiment, the protective members of the nozzle consist of an ice crushing ring arranged at the front and / or rear edge of the nozzle, which is preferably formed at the front edge to cut ice. Said circumference is preferably fitted with fastening ribs to the nozzle in such a position that the inlet of the flow path between the ice crushing circumference and the nozzle is oblique to the central axis of the nozzle. The ice floes are crushed to the front edge of the perimeter or remain in front of the front edge of the perimeter, leaving the flow path between the ice crushing perimeter and the actual nozzle free of ice.

The invention will now be described in more detail with reference to the accompanying drawings, in which Fig. 1 shows a front view of an extruder device according to the invention, Fig. 2 shows a side view of the extruder device according to Fig. 1, partly in section, Fig. 3 shows section II, Fig. 4 shows a second embodiment of the invention. Fig. 5 shows a preferred profile shape of the ice crushing ring, Fig. 6 shows a third embodiment of the invention seen from the front, Fig. 7 shows the extruder device according to Fig. 6 seen from the side, Fig. 8 shows a partial view of the section II of Fig. 6.

Figure 1 shows an extruder propeller device 10. Inside the nozzle 11 there is a propeller 16, the operating devices and the power input of which are not shown separately. The nozzle 11 comprises an outer surface 11a and an inner surface 11b. The inner surface is shaped to be flow dynamically advantageous and comprises a curved leading edge 11b2 which is substantially directly connected to the inner central portion 11b1. The nozzle may be supported so that the nozzle can be pivoted on bearing means. Preferably, these means form an upper support and a lower support.

In one embodiment, the extruder device 10 according to the invention comprises an ice crushing ring 20 arranged in the vicinity of the front edge 12 of the nozzle. 20 through the delimited central area (arrow A2).

The perimeter 20 is attached to the nozzle 11 by fastening ribs 21. The ribs 21 are preferably plates with side surfaces parallel to the central axis x of the nozzle 11. This arrangement is advantageous in trying to keep the flow resistance to a minimum. Figure 3 shows in more detail a cross-section of the nozzle 11 and the ice crushing ring 20 according to the embodiment of Figures 1 and 2. The leading edge 23 of the ice crushing ring is formed quite narrow and ice-cutting. It is preferably made of a small diameter round bar. This small diameter of the leading edge 23 contributes to the crushing of the ice. The leading edge 23 can also be wedge-shaped or sharp. The rim 20 is located in front of the leading edge 12 of the nozzle 11, and preferably the inlet 26 of the flow path 25 between the rim 20 and the nozzle 11 is oblique to the central axis x of the nozzle and propeller. The arrangement helps the nozzle to remain unobstructed even in difficult ice conditions. The ice blocks cannot easily wedge between the front edge 23 of the ice crushing ring 20 and the wheel bar 15 at the front edge 12 of the nozzle 11, but the flow path 25 remains free of ice. However, if the ice can prevent the passage of the central flow A2, there will still be an ice-free flow for the flow A2 through the inlet 26 inside the nozzle 11.

In the embodiment of Figure 3, the ice crushing ring 20 comprises plate portions 22a, 22b associated with the round bar 24. These are most preferably curved, creating a flow of flow within the nozzle. The plate parts 22a, 22b are connected at one end to the round bar 24 and at the other end to each other. The nozzle 11 side plate 22b is attached by a rib 21 to the curved inner surface Hb2 of the nozzle 11. Thus, the rib 21 attaches the ice crushing ring 20 to the nozzle 11. The cross-sectional shape of the ice crushing ring 20 is a circle.

In another embodiment, the circumference 20 is molded in one piece with the nozzle 11.

There may be several ice crushing rings 20 so that both the edge 12 and the rear edge 13 have an ice crushing ring 20.

Figure 4 shows another preferred embodiment of the invention. The circumference 20 'is in front of the actual nozzle and is made of a relatively small diameter round bar. The circumference 20 'is connected by ribs 21' to the front edge 12 of the nozzle. The circumference 20 'can also be formed so that the plane of the flow path inlet between the circumference and the nozzle is perpendicular to the central flow into the nozzle (A2).

In an embodiment of the invention not shown in the figures, the circumference 20 is formed in one piece with the main nozzle itself, whereby the flow paths for the flows are formed by perforating the main nozzle. The holes are preferably evenly spaced. In this embodiment, the circumference 20 is thus formed by the front and / or rear edge of the nozzle.

Figure 5 shows a preferred cross-sectional shape of the ice crushing ring 20 ''. The cross-section consists of a curved portion and a sharp, ice-crushing edge portion S2 on the opposite side. Preferably, a triangular profile 40 with a sharp leading edge 40a is then connected to the round bar 24 '.

Figures 6-8 show a nozzle 11, 6 83751 surrounding a propeller 16 provided with ice spikes 30 extending axially beyond the leading edge 12 or trailing edge (not shown) of the nozzle. The spikes 30 are attached by welding both the outer surface 11a of the nozzle and its curved inner surface 11b to the leading edge 12 or 13 in the vicinity. The outer nozzle surface 11a is a substantially straight surface. The inner nozzle surface 11b, on the other hand, consists of a straight nozzle surface portion 11b 1 and an associated curved nozzle leading edge 12 side portion Hb 2 · In the embodiment shown, there are eight β with respect to the axis x 'parallel to the propeller axis. The angle β is most preferably between 0-60 °. The front part 32 of the upper edge of the ice spike 30 is at an angle α to the axis x * 'parallel to the propeller axis. The angle α is preferably between 20 ° and 60 °. The edges 31 and 32 are connected by an ice-crushing leading edge 33 which is substantially perpendicular to the axes x 'and x' '. Associated with the edge portion 32 is a relatively short edge portion 34 parallel to the propeller shaft and a edge portion 35 further associated with the surface 11a of the leading edge 12 of the nozzle 11. The orientation of the edges 31 and 32 increases the size of the ice spike so that the ice spike becomes strong enough. The ice spike 30 is welded to the die 11 at 37. The side surfaces of the ice spike 30 are indicated by the numbers 36a and 36b. The ice spikes 30 can also be formed, for example, by casting them in one piece with the nozzle. Ice spikes can also be made by forging.

The ice spikes 30 operate as follows. When the ice floe hits the ice spike 30, the ice spike acts at its leading edge 33 to break the ice floe. If the ice floe is so large that it does not break, the ice spikes 30 keep the ice floe off the front edge 12 of the nozzle 11 in a position where a gap is left between the ice floe and the nozzle from which water can flow.

If the ice spikes 30 are made of plate-like parts, they 7 83751 are arranged on the front and / or rear edges 12 and 13 of the nozzle 11 so that the side surfaces 36a, 36b of the ice spikes 30 are parallel to the propeller shaft. In this case, the ice spikes 30 form the smallest possible flow resistance. In another preferred embodiment, the plate-like ice spikes are arranged at such an angle to the flow D to the nozzle that the flow to the nozzle and the propeller is caused to swirl in the opposite direction to the direction of rotation of the propeller, thereby improving the efficiency of the propeller.

According to the invention, the ice spikes 30 can also be arranged only on the rear edge 13 of the nozzle 11 or on both the rear edge 13 and the front edge 12. In this case, when the base is retracted, the ice spikes act on the rear edge 13 of the nozzle. Ice spikes can also be wedge-shaped and sharp at the leading edge. The ice spike can also be a toothed part.

The invention is not limited to the embodiments shown, but several variations of the invention are conceivable within the scope of the appended claims.

Claims (14)

8 83751 A nozzle (10) for ice conditions, comprising a nozzle (11) surrounding the propeller (16), characterized in that the front and / or rear edge of the nozzle (11) comprises protective members whose radial position is substantially outside the inner surface of the nozzle (11) and which axially extending beyond the nozzle (11) such that said members either crush the ice board hitting the members or leave the board in a position relative to the nozzle (11) such that there is a free flow of water between the ice board and the nozzle (11) inside the nozzle (11). A nozzle propeller (10) according to claim 1, characterized in that said protective members comprise an ice crushing ring (20) and that the nozzle device has an external flow path (25) for the flow into the nozzle (11) between the ice crushing ring (20) and the nozzle (11) itself. through the nozzle (11) and a central flow path through the central region defined by the ice crushing ring (20) so that if ice blocks the central flow path, an external flow path (25) inside the nozzle (11) remains for the flow (A 1). Nozzle propeller according to Claim 2, characterized in that the front edge (12) and / or the rear edge (13) of the nozzle (11) is provided with an ice crushing ring (20) located in front of or behind the rear edge (12) of the nozzle (11). so that an external flow path (25) is formed between the ice crushing ring (20) and the nozzle (11) for the flow entering the nozzle (11) and a central flow path through the central area delimited by the ice crushing ring (20), leaving an external flow path for the flow (A ^) (25) between the ice crushing ring (20) and the nozzle (11). 9 83751 Nozzle propeller according to claim 2, characterized in that the ice crushing ring (20) comprises an ice crushing leading edge (23) so located relative to the nozzle (11) that the inlet (26) of the external flow path (25) is inclined to the nozzle central axis (x) , thus preventing ice floes from wedging between the ice crushing ring (20) and the nozzle (11). Extruder according to one of the preceding claims, characterized in that the ice crushing ring (20) has an ice-crushing sharp leading edge (23). Nozzle propeller according to one of the preceding claims, characterized in that the ice crushing ring (20) comprises a round bar (24) and curved plates (22a, 22b) fitted to it, which are connected at one end, and that the nozzle (11) side plate (22b) ) is attached by a rib (21) to the nozzle (11), preferably to its curved inner surface (11b2) - Nozzle propulsion device according to one of the preceding claims, characterized in that the cross-sectional profile of the ice crushing ring (20) has a curved rear edge () and a sharp front edge (S2). Nozzle propeller device according to one of the preceding claims, characterized in that the ice crushing ring (20) comprises a round bar (20 ') which is connected to the nozzle (11) by ribs (21') or the like. Nozzle-propeller device according to one of the preceding claims, characterized in that the nozzle (11) comprises flow openings or bores in the nozzle body which form a flow path for the flow (A 1) inside the nozzle (11) when the ice float blocks the central flow path of the nozzle (11). Nozzle insertion (10) according to one of the preceding claims, characterized in that the front and / or rear edge (12, 13) of the nozzle (11) has ice spikes (30) adapted to crush the ice floe hitting them and / or is adapted to leave it in a position where there is a flow path inside the nozzle (11) between the ice floe fixed by the ice spikes (30) and the nozzle (11). Nozzle propeller according to Claim 10, characterized in that the ice spikes (30) project from the nozzle edge (12 and / or 13) and are attached to the nozzle edge (12 and / or 13) at one end. Nozzle propeller according to Claim 10 or 11, characterized in that the ice spike (30) is a wedge-shaped or tooth-shaped part. Nozzle propeller according to one of Claims 10 to 12, characterized in that the ice spike (30) is a straight plate part with parallel side surfaces (36a, 36b). Extruder according to one of Claims 10 to 13, characterized in that the ice spike (30) has an ice-crushing leading edge (33). Nozzle propeller according to one of Claims 10 to 14, characterized in that the ice spike (30) is attached to the nozzle (11) by welding and is connected to the outer surface (11a) of the nozzle and to the propeller-side surface (11b) of the nozzle. il 83751