DE1012843B - Arrangement for propulsion and control of ships with pivoting propellers - Google Patents

Description

Arrangement for the drive and control of ships with swivel Ship's propeller In the known ship propulsion systems, in which the ship's propeller to control the ship around a mostly perpendicular to its axis of rotation Axis is pivotable, the engine is close to the stern or outside of the same and is pivoted together with the screw. The Drive power via a downward leading one connected to the motor shaft Transfer the shaft and a subsequent angular gear to the screw. This The gear is stored in a special housing (gear head), which has a the tube enclosing the drive shaft is connected to the housing of the prime mover is.

Such systems are because of their simple structure, the light Handling and good accessibility are often preferred as drives for small boats.

For obvious reasons, however, it is not possible to do this Arrangement can also be used for larger drive powers without being exceptional to take structural measures. Above all, it would be very disadvantageous to have a prime mover large power at the stern of the ship can be swiveled.

Disruptive for the control process is in arrangements with pivotable As is well known, the ship's propeller is also the reverse pivoting torque, which is the torque corresponds to the vertical drive shaft and a unidirectional adjustment torque represents. As is known, this disadvantageous effect is eliminated in that the prime mover on the gear head containing the bearing of the angular gear on the propeller transmits a torque that is independent of the pivoting and that is the driving torque corresponds in the drive shaft and counteracts this in its direction of rotation. That Pivoting the propeller and thus steering the ship can then completely unaffected by the torque and the direction of rotation of the drive machine or without special effort of an adjusting force take place.

Swiveling and about its axis z. B. rotatable on a slewing ring However, prime movers with greater power can be installed in the stern of the ship Difficult to accommodate and store together with the control or swivel device. In such cases you are forced to take special measures, or you have to Machine and the swivel mechanism in the interior of the ship's hull and further move forward.

Further difficulties when using larger drive powers arise both when arranged at the stern and in the ship's hull that the desired support of the restoring torque on the z. B. on the housing of the prime mover removed reaction torque requires a large amount of components that z. B. in piston engines (diesel engines) extensive and special measures to Storage of the housing etc. would make necessary. In addition, the prime mover always due to their rigid connection with the boom tube or the gear head swings and unpleasant swing effects in the control with rapid swivel movements can arise. In contrast, it would be obvious, e.g. B. the drive shaft of the propeller Via angular gear with the propulsion engine, which is fixed further forward on the ship's floor some kind of drive to connect.

However, the disadvantage of such an arrangement is that the transmission the drive torque of the drive shaft for the propeller in the gear head and thus a pivoting torque is generated in the boom tube, which in terms of size and direction of rotation equal to the torque in the vertical drive shaft and in the control system always a unidirectional one and its size depends on the respective screw torque dependent adjustment torque caused.

The present invention seeks to eliminate the above Difficulties not only the use of the advantages of the known drives finite swiveling propeller also possible with large drive powers, but In addition, new possibilities with structural and functional Benefits for the propulsion and control of ships.

For this purpose, according to the invention in the drive transmission A planetary gear unit acts as a transfer case between the drive engine and the propeller switched, which in addition to the drive torque on the propeller in the opposite Sensing supporting moment for the bearing parts of the propeller or for the Pivoting device delivers, wherein the first free gear member with the drive shaft, the second with the propeller and the third with the swivel device or is connected to the shaft bearing for the propeller.

With this arrangement, the back torque is no longer through absorbed the reaction torque of the prime mover, but from the hull itself. As a result, the complicated storage facilities are no longer necessary of the machine parts emitting the reaction torque (e.g. the housing), so that normal drive machines can be used and replaced at any time.

To compensate for the difference in torque between the one on the one hand pivotable bearing part of the propeller acting moment and on the other hand the According to the invention, the drive torque is a further operational connection (reduction gear) between the propeller and its storage on the one hand and the transfer case on the other hand, whose members are connected to the reciprocal kinematic relationships to the corresponding links of the transfer case. After the Invention as a reduction gear a planetary gear with the same gear ratios used as the transfer case, each having an equivalent link of the two Gearbox with each other and the planetary gear carrier of the gearbox with the screw drive or the bearing part of the propeller and the pivoting device and the remaining free links are connected to the prime mover for rotation. From the above arrangement according to the invention there are many new and useful possibilities to install the prime mover or the control gear and for the various Design drive and control tasks.

So z. B. the prime mover coaxially with the transfer case be permanently installed on the stern of the ship; or it can be the prime mover and the transfer case sit in the ship's hull and attached to the propeller and be connected to the drive connections leading to the gear head. Finally you can also the transfer case coaxial with the vertical drive shaft for the Propeller on the ship's stern and the propulsion engine coaxially with it or be installed in the ship's hull.

There are also variations with regard to the structure of the transfer case itself possible, which particularly relates to the connection of the individual kinematic links to the prime mover or to the torque distribution to the propeller drive and refer to the gear head.

According to the invention, the following principles apply here: a) If the Drive machine is attached to the ship and only its shaft is rotatable, so must their output torque by means of the transfer case (planetary or bevel gear differential) be branched to two output connections, one of which to the propeller and the other leads to the gear head. The gear ratios of these drive connections are designed in such a way that the gear head can pivot when the Propeller shaft is possible without the shaft of the drive engine turns.

b) The steering device of the ship (directly steering wheel from or by means of controlled auxiliary power, e.g. B. Rowing machine) must always in some way and at some point so connected to the gear branch connected to the gear head be that the same depending on the desired in one or the other direction of rotation can be driven and inevitably causes the desired pivoting movement.

According to the invention are in detail, depending on the existing installation and size ratios, for the arrangement of the gear units, the drive machine and the control devices made advantageous and expedient proposals. These refer to all possible and practically occurring with the components used Combinations and represent in each case the best possible fundamental, kinematic and structural solutions.

These are based on the drawings in their structure and in their mode of operation explained in more detail.

The drawings show schematically examples of the Arrangements according to the invention: Fig. 1 shows an arrangement in which the prime mover with the transfer case and the gear head as a coaxial unit in the stern of the ship is built in; Fig. 2 shows an arrangement in which the prime mover is separated is installed in the ship's hull; Fig. 3 shows an arrangement in which the prime mover is installed with the transfer case in the ship's hull; Fig. 4 shows an arrangement in which the drive machine is arranged in the hull of the ship with only one transfer case is; 5 shows a two-screw drive with an adjusting gear and transfer case; Fig. 6 shows another example of the arrangement of the adjusting gear for a case The embodiment according to FIG. 1 is the gear housing 30 on the bottom flange 15 rigidly attached, serves as a support bracket for the housing 1 attached to it Prime mover, e.g. B. of 4, and also carries the pivot bearing 25 for the pivotable Boom tube 2 with gear head 3. The shaft 4a. of the electric motor is above the Outer gear 31 and the planetary gears 32 mesh with the sun gear 35. The bridge 34 of the transfer case I is coaxially connected to the shaft 8 in a rotationally fixed manner. Of the Web 35 of a further and underlying gear (reduction gear II) is with the boom tube 2 and thus also with the gear head 3 rotatably and the on Planet gears 32 mounted on it are fastened outside with an in the gear housing Ranz 36 and inneu with a sun gear 33 a th tooth in engagement. The sun gears 33, 33 a, are with the worm wheel 37 to a rigid unit and on the shaft 8 rotatably mounted. In the worm wheel 37 engages a worm 29, which of the control of the ship, e.g. B. with the rowing machine 27, both directions of rotation can be driven. The torques of the shaft 8 are transferred because the two Planetary gears I and II have the same gear ratios, in equal proportions, but with a sign on the sun gears 33, 33 a and so that they keep themselves thereby always that transferred from the worm 29 to the worm wheel 37 Adjustment movement can take place without significant effort. This adjustment movement causes - imagine the outer wheel 31 stationary - in each case the desired pivoting of the gear head 3 and thus the screw shaft 11 with screw 12.

In the example of FIG. 2, the housing 1 of the electric motor is in some Distance from the vertical pivot axis attached to the ship's bottom 16 a. The gear housing 38 is fastened on the bottom flange 15. It carries in his upper part the transfer case I and the reduction gear II and below the swivel bearing 25 for the boom tube 2 with gear head 3 and screw 12. After loosening the fastening of the gear housing 38 from the bottom flange 15, the whole unit can be disassembled to be expanded to the interior of the ship.

The shaft 8 is here with the web 34 of the upper gear and the Boom tube 2 rotatably connected to the web 35 of the lower gear. The drive takes place from the electric motor via a cardan shaft 20, one in the gear housing 38 mounted bevel gear 39, an engaging and coaxial with it the shaft 8 mounted bevel gear 40, a connected to the latter outer gear 41 of the lower gear I and the planetary gears 32 on the two rigidly connected to each other and on the shaft 8 rotatably mounted sun gears 33 a, 33 and from there to the Planetary gears 32 of the upper gear II, which in turn are in the gear housing 38 roll fixed ring gear 36 and thereby the web 34 including the shaft 8 drive. The worm wheel 37 is here rigidly connected to the web 35 and is to achieve a pivoting movement by a rowing machine 27 via the worm 29 driven in the appropriate direction of rotation if required.

The embodiment of FIG. 3 satisfies the same task like that of Fig. 2. It differs from the example of Fig. 2 in its details only by the fact that the transfer case I for torque sharing and the transmission II for transmitting the partial torque to the boom tube 2 directly on the housing 1 of the electric motor is flanged. The transmission of the supporting torque and the torque of the screw drive is achieved by two coaxially nested Cardan shafts 17 and 20 on the bevel gears 21, 18, which are also nested in one another and from there via the bevel gears 19, 22 to the boom tube 2 or the shaft B. The gears I and II in the gear case 44 are different from those according to Fig. 1 and 2 only in that in this case the drive from the shaft 4a takes place not on an external gear 31, 41, but on a sun gear 42. The bridge 34 is with the shaft 8 and the web 35 with the boom tube 2 in gear connection. The planetary gears 32 are rotatably mounted on both webs and stand with them on the outside the two gear rings rigidly connected to one another and rotatably mounted in the housing 44 43 and 43 a, inside with the sun gear 42 and with the sun gear attached to the housing 45 engaged. With the two ring gears 43, 43a there is also a worm gear tooth system 46 rigidly connected and is in engagement with the worm 29, which is driven by the steering gear 27 can be driven in both directions of rotation for the purpose of steering. The bevel gear pairs 18, 19 and 21, 22 have the same gear ratios. Correspond in their function the two gear rims rigidly connected to each other and to the worm gear teeth 46 43, 43a exactly the two sun gears 33, 33 a in the example of FIG. 1. The two Planetary gears in the gear housing 44 also have the same gear ratios here on.

The embodiment of FIG. 4 is intended to show that it is also possible is to get by with a single transfer case and the shaft 8 resp. the boom tube 2 to be transmitted torques in an existing per se, the Gearbox downstream of the transfer case (bevel drive in the gearbox housing 24) to be reshaped to the same size.

In the example of FIG. 4, a housing 1 of the electric motor 4 is attached Gear housing 47 flanged. Whose shaft 4a drives over the rotatably with him connected sun gear 42 to the planetary gears 43. The latter can be rotated on the web 34 mounted and are externally in engagement with the outer gear 48. The web 34 protrudes the cardan shaft 20 and the pair of bevel gears 21, 22 with the shaft 8 in a geared manner Link. Likewise, the outer gear 48 is above the cardan shaft 17 and the pair of bevel gears 18, 19 with the boom tube 2 in gear connection. On the hollow shaft of the Outer wheel 48 is attached to the worm wheel 37, which with the worm 29 in the Engagement is. This worm 29 is used to initiate the steering machine 27 adjustment movement necessary for steering. According to those applicable to planetary gears Laws are the torque transmitted to the web 34 in the present example significantly larger (but acting in the opposite direction in the desired sense) than the smaller one Torque that is transmitted to the outer gear 48. Different from the previous ones Embodiments is the gear ratio of the bevel gear pair 18, 19 of that of the bevel gear pair 21, 22 so much different that the transfer case Torques supplied via the cardan shafts 17, 20, converted to the same size, be transferred to the shaft 8 or the boom tube 2.

A big advantage of the propulsion systems with swiveling propellers according to Fig. 1 to 4 is given by the fact that without any substantial power requirement and pivoting of the screw that can be carried out with practically unlimited angular range 12 a propulsion of the ship in the direction of travel "backwards" is also possible without that the direction of rotation of the screw is changed. When transitioning from forward travel for reversing and vice versa, however, is a (temporary) influence of the ship's course available. In the case of small systems, the forward movement can be swiveled take place in reverse so quickly that the resulting change in course is slight remain. In the case of large systems, on the other hand, where a rowing machine is essential reaches, this pivoting can take place under certain circumstances so slowly that the undesired change of course occurs to a considerable extent.

For this purpose, it is proposed that each ship has a two-screw drive to operate two complete screw systems with swiveling screw in parallel and to operate both worms 29 by a special adjusting gear, both at the same time in the same direction of rotation and in the opposite direction Sense of rotation occurring rotation of the two screws 29 then present is made possible.

In one case, the adjustment results in a simultaneous and in the same direction Pivoting both screws, and this is used to make course changes. Otherwise, the two screws swivel z. B. from the normal straight-ahead position from at the same time, in equal measure and opposite. This kind of pivoting has the consequence that in all pivot positions the transverse to Always keep components of the propeller thrust occurring in the longitudinal direction of the ship and therefore a swing carried out in this way also has no effect on the course Has. Remains effective at the same time, in the same degree and in the opposite Meaning that the screw is pivoted only in the longitudinal direction of the ship Acting component of the screw thrust of both screws.

In FIGS. 5 and 6, exemplary embodiments are suitable for this purpose Adjusting gears shown.

In the case of the adjusting gear according to FIG. 5, the housing is in the bearing blocks 57 58 of a bevel gear compensator rotatably mounted. On the housing 58 is the Steering machine 27 flanged and is on her bevel gear 59 at the same time with the Bevel gears 60 and 60a in engagement. These bevel gears 60 and 60a are each with one of the adjusting shafts 61 and 61a rotatably connected. The adjusting shafts are rotatably mounted in the housing 58 and are on the one hand with the adjusting worm 29 one and the other with the adjusting worm 29 of the other drive system in operational connection. For example, there are two complete drive systems Systems according to FIG. 1 selected. Analogously, however, the adjustment gear can also be used in Find connection with systems according to FIGS. 2, 3 and 4 application.

A worm housing 62 is attached to the left bearing block 57. In him the worm wheel 63 is in engagement with the worm 64, which is in the worm housing 62 mounted and driven by a rowing machine 27a in both directions of rotation can be. The worm wheel 63 is rigid on the left bearing bush of the housing 58 connected, and thus by means of the rowing machine 27 a, including the whole housing the steering gear 27 can be pivoted in the bearing blocks 57 without restriction. In this Case are the two bevel gears 60, 60a on the bevel gear 59 of the stationary Rowing machines are coupled and are therefore simultaneously and in the same direction of rotation twisted. When the bevel gear 59 is rotated by the steering engine 27 the two bevel gears 60 and 60a simultaneously to the same extent and in opposite directions twisted. By optionally actuating the rowing machine 27 or rowing machine 27a can adjust the desired type of adjustment of the two visual hoods with the adjustment gear shown are executed.

In the embodiment according to FIG. 6, there is the adjusting gear from a housing 65 in which the two to the adjusting worms 29 of the drive systems leading adjusting shafts 61 and 61 a are rotatably mounted. On the adjustment shafts 61, 61a each of the web 66, 66 a of a planetary gear is attached on which the planet gears 32 are rotatably mounted and with the outer gear 67 and 67a as well are in engagement with the sun gear 68 and 68a, respectively. The outer gears 67, 67a are in Housing 65 coaxially with the sun gears 68, 68 a and the adjusting shafts 61, 61 a rotatably mounted and are on their external teeth 69 each with a pinion 70 engaged.

The two pinions 70 are among themselves and with a worm wheel 71 rigidly connected and rotatably mounted in the housing 65. One with worm wheel 71 Engaging worm 72 can be rotated in both directions by a rowing machine 27 are driven. The sun gears 68 and 68 a are also rotatable in the housing 65 stored and rigidly connected to bevel gears 60 and 60a, in which a also bevel gear 59 rotatably mounted in housing 65 engages at the same time. The bevel gear 59 is rigidly connected to a worm gear 73 and can by engaging it driven into the worm 74 by the steering machine 27 a in both directions of rotation will.

A rotation of the worm 72 by the steering machine 27 causes a simultaneous and equal rotation of the outer gears 67, 67a, and since the sun gears 68, 68 a are held by the bevel gear 59, corresponds this rotation of the outer gears 67, 67a also occurs simultaneously and in the same direction of rotation subsequent rotation of the adjusting shafts 61 and 61a. But is by the rowing machine 27a, the worm 74 is driven in any direction of rotation, so the bevel gear causes 59 a simultaneous, to the same extent and in the opposite direction of rotation taking place Rotation of the sun gears 68, 68a, and there the outer gears 67, 67a from the worm are blocked, this rotation is transmitted via the planetary gears 32 and the Web 66, 66a also on the adjusting shafts 61, 61 a. So it is possible with the Rowing machine 27 the adjusting shafts 61, 61 a in the same direction of rotation and with the rowing machine 27a to rotate in the opposite direction. Are these adjusting shafts 61, 61a with each one of the screws 29 of the drive systems (Fig. 1 to 4) in some way connected by a gear, the opposite can also be used with this adjusting gear or swiveling the two screws in the same direction.

In the case of both adjustment gears (according to FIGS. 5 and 6), however, there is also the possibility of switching on both rowing machines at the same time to combine all practically occurring control maneuvers as required. When the rowing machines 27 electric motors are used in both para @@ el powered drive systems, so can the same adjustment effect or the same pivoting of the screws in the desired Sense achieved without the use of an adjusting mechanism according to FIGS. 5 and 6 be that the two electric motors are electrically connected. Even then is the optional simultaneous or mixed adjustment of the two screws 29 and thus the screws 12 by actuating the appropriate electrical switch possible.

The operating principle of the adjusting mechanism according to FIGS. 5 and 6 can be also by simple means in a hydraulic (hydrostatic), pneumatic way or with steam drives. The position of the pivot axis can also vary from the Different verticals are chosen and, if required for special reasons, the Change the direction of thrust of the screw in any other plane. The screw 12 can also be replaced by a propeller, which is without should allow significant effort to pivot about any pivot axis.

Claims (14)

CLAIMS: 1. Arrangement for propulsion and steering of ships with a propulsion engine permanently installed in the hull and a propeller, which can be pivoted about an axis perpendicular to the screw axis, characterized in that that in the drive transmission between the engine and propeller as Transfer case (I) a planetary gear is connected, which besides the Driving torque on the propeller is a supporting torque acting in the opposite direction for the bearing parts of the propeller or for the pivoting device, wherein the first free Gear member with the drive shaft (4a), the second with the propeller (12) and the third with the pivoting device (29) or is connected to the shaft bearing (3) for the propeller. 2. Arrangement according to Claim 1, characterized in that to compensate for the differential torque between the moment acting on the one hand on the pivotable bearing part of the propeller and on the other hand the drive torque another operational connection (reduction gear II) between the propeller and its storage on the one hand and the transfer case on the other hand is switched, whose members the reciprocal kinematic relationships to the corresponding links of the transfer case. 3. Arrangement according to claims 1 and 2, characterized in that the reduction gear is a planetary gear with the same gear ratios as the transfer case is used, where an equivalent link of the two gears with each other and the planetary gear carriers the gearbox with the propeller drive or the bearing part of the propeller and the pivoting device and the remaining free links with the prime mover are connected to rotation (Fig. 2). 4. Arrangement according to claims 1 and 2, characterized in that the reduction gear (II) consists of a countershaft (bevel gears 18, 19, Fig. 4), the bevel gears (18,19) have the opposite gear ratio than that with them Operationally connected links of the transfer case (Fig. 4). 5. Arrangement according to claims 1, 2 u @ 3, characterized in that the shaft (4a) of the drive machine with the outer sun gear (31) of the transfer case and its inner sun gear (33) with the pivoting device and the planet carrier (34) the shaft (8) leading to the propeller are in drive connection, with a further transfer case being arranged coaxially with this transfer case, the outer sun gear (36) of which is fixed in space, the inner sun gear (33a) with that (33) of the first transfer case and its planetary gear carrier ( 35) are connected to rotate with the bearing housing head of the screw (3) (Fig. 1). 6th Arrangement according to the preceding claims, characterized in that the transfer case and the reduction gear coaxially and with a vertical axis above that of the Drive machine coming transverse shaft (20) are arranged (Fig. 2). 7. Arrangement according to the preceding claims, in particular according to claim 6, characterized characterized in that the drive of the transfer case via its outer sun gear (41) is initiated and its inner sun gear (33) with that (33a) of the Reduction gear is connected, the outer sun gear (36) is fixed in space, and that the planetary gear carrier (35) of the transfer case with the pivoting device and the bearing housing of the propeller (3) and that (34) of the reduction gear with the drive shaft (8) of the propeller is connected to rotate (Fig. 2). B. Arrangement in particular according to Claims 1, 2 and 3, characterized in that that when the drive engine is set up in the ship's hull, the gears (I, II) with the pivoting device (29) are arranged directly on the drive machine (1) and the drive torque or the pivoting torque via cardan shafts. (17, 20) and bevel gear (18,19; 21,22) are transferred to the propeller or to its storage. 9. Arrangement in particular according to claim 8, characterized in that the drive on the inner sun gear (42) of the transfer case takes place, while the inner Sun gear (45) of the reduction gear is fixed in space and the outer, interconnected Sun gears (43, 43a) with the swivel device (29) and the planetary gear carrier (34) of the transfer case with the drive shaft (8) for the propeller and the planetary gear carrier (35) of the reduction gear with the pivot shaft for the bearing housing are in drive connection for the propeller (Fig. 3). 10. Arrangement according to the preceding claims, in particular according to claim 9, characterized in that that the transfer case is arranged on the prime mover and its interior Sun gear (42) is driven and its outer sun gear (48) with the pivoting device as well as via cardan shaft (17) and angular gear (18, 19) with the bearing housing of the The propeller and the planetary gear carrier (34) with the propeller drive (8) is in drive connection via cardan shaft (20) and angular gear (21,22) and wherein the gear ratios of the bevel gear pair (18, 19) and the bevel gear pair (21, 22) reversed to those of the corresponding links in the transfer case behavior. 11. Arrangement according to the preceding claims, characterized in that that with two drive systems operated in parallel, the control of the swivel system takes place by an adjusting gear, which consists of a differential gear whose coaxial free links (60, 60a) each with one of the pivoting systems. Operational are connected and both the web itself (z. B. the housing 58) and the am Bridge-mounted intermediate link (bevel gear 59) of one rowing machine each (27a and 27) independently of each other in both directions of rotation and thus also the two free ones Links (60, 60a) together in any, same or opposite direction of rotation can be driven (Fig. 5). 12. Arrangement according to the preceding claims, characterized in that with two drive systems operated in parallel in a ship the control of the swivel position of both screws by a common adjustment gear takes place, which essentially consists of two coaxial transfer cases consists, each of the two webs of the transfer case with one of the drive systems (61, 61 a.) Operationally linked, two corresponding free members of the Transfer case among themselves and with a steering gear (e.g. outer gears 67, 67a and rowing machine 27) are operationally connected in such a way that they can be operated by the latter in any but are rotated under the same direction of rotation, and that two more corresponding free links of the transfer case also among themselves and with a further rowing machine (e.g. sun gears 68, 68a and rowing machine 27a) Operational are so connected that they of the latter in any, among themselves but can always be driven in the opposite direction of rotation (Fig. 6). 13th Arrangement according to the preceding claims when using two drive machines each with a swiveling propeller, the swiveling device (steering gear) each operated by an electric motor, characterized by such Connection of the electric motors to each other via electrical means that with them Simply by actuating electrical switches, both propellers at the same time or separately in any swivel direction with the screw turning direction remaining the same or can be swiveled in opposite directions. 14. Arrangement according to the preceding claims, characterized in that their 'transfer case and optionally the downstream bevel drives result in a screw drive with a reduced speed compared to the drive machine. Documents considered: German Patent No. 870 655; British Patent No. 598 598; German utility model No. 1691362.