FI76749C - Propeller with nozzle - Google Patents

Description

76749

PROPELLER MED DYSA

The invention relates to an extruder system for ice conditions, in which the extruder apparatus has a circularly symmetrical nozzle surrounding the propeller.

The disadvantage of the nozzle propeller is its tendency 5 to become blocked 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 provided by the propeller is reduced and the strainer 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 flow to protect the propeller. This protective cage prevents larger objects from entering the nozzle with the propeller stream. A major problem with this solution is that the protective cage has to be made very dense, which causes a high flow resistance, thus reducing the propulsion efficiency. A disadvantage of safety net solutions can also be considered that their networks are easily clogged with ice.

An apparatus solution is also known in which, in front of the propeller nozzle, protective shields fixed to the ship hull at one end and attached to the nozzle ring at the other end are used. The disadvantage in this case is the high flow resistance caused by the protective shields 25 in question. 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. 1

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 of the nozzle 2 76749 act as anti-wedge parts and an ice-crushing blade. The propeller nozzle can also be formed in such a way that the front edge of the nozzle is pulled back at at least one point so that the front edge 5 of the propeller blades at said point extends in front of the front edge of the nozzle.

This arrangement prevents the ice cubes from stacking against the leading edges of the nozzle. A disadvantage of this solution is that the arrangement does not prevent the passage of ice cubes inside the nozzles, but the ice blocks caught inside the nozzle must be crushed by the work done by the propeller, whereby the propulsion efficiency is reduced. DE 1938480 discloses an annular profile attached to the front edge of a nozzle, which guides smaller foreign objects into a trapezoidal groove inside the nozzle, from which a flow moves the objects out of the rear of the nozzle. A tire profile is a passive protection device that is not intended for ice crushing.

It is an object of the invention to provide an extruder which avoids the above-mentioned disadvantages of the prior art and in which the solution reduces the adverse effects caused by an ice floe blocking the die. It is therefore an object of the invention to provide an extruder which maintains thrust even in difficult ice conditions and which reduces the stresses on the propeller blades, shaft and bearings of a clogging ice floe and which propulsion device has at least one free geometry outlet from the ice or ice

The invention is mainly characterized in that the longitudinal extension of the nozzle of the BO nozzle is provided with an ice crushing circumference provided on the front and / or rear edge of the nozzle. This crushing ring is located in front of or behind the front edge of the nozzle, whereby one flow path is formed for the flow to the nozzle through the area bounded by the icebreaker-B5 and the nozzle itself inside both the flow path central flow path, the flow path remains inside the nozzle to ensure thrust between the crushing ring and the nozzle.

Other features of the invention will become apparent from claims 2-8.

According to the invention, the nozzle propeller comprises an ice crushing ring arranged at the front and / or rear edge of the nozzle. According to the invention, the ice crushing ring is preferably formed at the front edge to crush ice and said nozzle 10 is fitted with fastening ribs to the main nozzle in such a position that the inlet of the flow path between the ice crushing ring and the nozzle is preferably inclined to the central axis of the nozzle. The ice floes are crushed to the front edge of the ice crushing nozzle 15 or remain in front of the front edge of the ice crushing nozzle. With this arrangement, the flow path between the ice crushing ring and the actual nozzle remains free of ice when the wedges of the ice floes between the crushing ring and the nozzle are prevented.

The invention will now be described in detail with reference to some preferred embodiments of the invention shown in the figures of the accompanying drawings, to which, however, the invention is not intended to be exclusively limited.

Figure 1 shows a front view of an extruder device 25 according to the invention.

Figure 2 is a side and cross-sectional view of the nozzle device of Figure 1. The propeller is shown schematically.

Figure 3 is a sectional view of the extruder device 30 taken along line I-I of Figure 1.

Figure 4 shows another embodiment of the invention corresponding to Figure 3.

4,76749

Figure 5 shows a preferred profile shape of the ice crushing ring.

Figure 1 shows a nozzle propeller 10 according to the invention. The figure schematically shows a propeller 16 inside the nozzle 11 5. The actuators of the propeller 16 and the power input are not shown separately. The rotational drive of the propeller 16 can be realized by introducing the rotation into the propeller either directly through the nozzle or by the power unit directly through the drive shaft parallel to the axis of rotation of the propeller 16. The nozzle 11 surrounding the propeller 16 comprises an outer surface 11a and an inner surface 11b. The inner surface 11b is shaped to be flow dynamically advantageous and comprises a curved leading edge 11b2 which is substantially directly connected to the inner central portion 11b. The nozzle may be supported by support devices 15 which can be arranged so that the nozzle can be pivoted by said support and bearing means. . Preferably, the means consist of an upper support and a lower support.

The nozzle propulsion device 10 according to the invention comprises an ice crushing ring 20 arranged in the vicinity of the leading edge 12 of the nozzle 20 11. Said ring 20 is most preferably arranged just at the leading edge 12 of the nozzle 11 and so that the flow inside the nozzle 11 is arranged to pass and through the central area delimited by the ice crushing ring 20 as shown by arrow A2.

The circumference 20 is fixed to the nozzle 11 by separate fixing ribs 21. The ribs 21 are preferably plates arranged between the ice crushing circumference 20 and the nozzle 11 30 so that their surfaces are perpendicular to the flow cross-sectional areas perpendicular 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 the embodiment of Figures 1 and 2

II

5 76749 corresponding nozzle 11 and ice crushing ring 20 in cross-sections. The leading edge 23 of the ice crushing ring 20 is preferably formed to be narrow and ice-cutting.

The leading edge 23 is preferably formed of a small diameter round bar 5. 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 perimeter 20 is arranged to be located in front of the front edge 12 of the nozzle 11 and preferably the ice crushing perimeter 20 is arranged to be located 10 in the vicinity of the front edge 12 This arrangement helps to keep the nozzle unobstructed even in difficult ice conditions. As a result of this arrangement, the ice blocks 15 cannot be wedged 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 this flow path 25 remains free of ice. However, if the ice is able to block the flow of the central flow A2, the flow 20 will still have an ice-free flow 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 plate portions are most preferably curved, creating a flow of flow within the nozzle. The plate parts 22a, 22b 25 are connected at one end to the round bar 24 and at the other end to each other. The plate 22b on the nozzle 11 side is fixed by a rib 21 to the nozzle 11 and its curved inner surface 11b2.

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

There may be a plurality of ice crushing rings 20 in such a way that an ice crushing ring is arranged on both the front edge 12 and / or a similar and similar ice crushing ring 20 is arranged on the rear edge 13.

Figure 4 shows another preferred embodiment of the invention. The circumference 20 'is arranged to be located in front of the actual nozzle and is formed of a relatively small circular rod. The circumference 20 'can also be formed in such a way that the flow paths between the circumference and the nozzle are located at their inlet openings perpendicular to the central flow (A2) entering the nozzle.

In a third embodiment of the invention 10, not shown, the circumference 20 is formed in one piece with the main nozzle itself, whereby a flow path for the flows (A 1) is formed by perforating the main nozzle. The holes are preferably formed in the main nozzle on the circumference and preferably at regular intervals. In this embodiment, the circumference 20 is thus formed by the front and / or rear edge of the nozzle, which is separated from the central nozzle body itself (11) by the respective holes or similar flow paths.

Figure 5 shows a preferred cross-sectional shape of the ice crushing ring 20 ". The circumferential cross-section consists of a curved portion 20 and a sharp ice-crushing edge portion S2 · on the opposite side. with ribs or the like not shown in the figure to the hydrodynamically preferably shaped front and / or rear edge of the nozzle.

Il

Claims (7)

7 76749 An extruder (10) for ice conditions, comprising a circularly symmetrical nozzle (11) surrounding the propeller (16), 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) as a longitudinal extension. is arranged to be located in front of the front edge (12) or behind the rear edge (13) of the nozzle (11), whereby a flow path (25) is formed between the ice crushing ring (20) and the nozzle (11) for the flow (A 1, Ag) entering the nozzle (11) and on the other hand a flow path through the central area delimited by the ice crushing ring (20), so that when the ice clogs the central flow path, a flow path (25) remains between the ice crushing ring (20) and the nozzle (11) to ensure propeller thrust. Nozzle propeller according to claim 1, characterized in that the ice crushing ring (20) comprises an ice crushing leading edge (23) adapted to be positioned relative to the nozzle (11) such that the inlet (26) of the flow channel (25) is inclined to the central axis (x) preventing wedges 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) arranged therein, which at one end are arranged to join each other, and that the nozzle (11) side plate (22b) ) is attached by a rib (21) to the nozzle (11) and its curved inner surface (11b ^) · Nozzle pot 76749 disc according to one of the preceding claims, characterized in that the ice crushing ring (20) consists of a cross-sectional profile with a curved rear edge (S ^) and a sharp leading edge (S2). Nozzle drill according to Claim 1 or 2, characterized in that the ice crushing ring (20) consists of a round bar (20 *) which is connected to the nozzle (11) by ribs (21 ') or the like. A nozzle propeller according to claim 1, characterized in that the nozzle (11) with its ice crushing frame is made in one piece so that large flow openings or bores are arranged in the nozzle body at a distance from the propeller (16)., Which openings form a flow path to the nozzle (11). when the ice floe blocks the nozzle (11) for the flow of the central main flow path (A2). Il 9 76749