DE7610700U1 - REVERSING GEAR, IN PARTICULAR FOR A Z-DRIVE FOR WATER VEHICLES - Google Patents

Description

Reversing gear, especially for a Z-drive for watercraft

The invention relates to a reversing gear as described in the preamble of the main claim.

There are already reversing gear for such purposes known in which the drive bevel gears alternately by means of a with claws or the like. Coupling sleeve with the drive shaft be coupled. These reversing gears can only be shifted at a standstill or they cause if they are running Gear shifts, shift shocks.

The invention is based on a reversing gear that works smoothly and without noticeable jolts when the gear is running. Becomes a such a transmission is used in a watercraft, so should this can be reversed quickly and reliably. The object on which the invention is based is achieved with the features of the main claim solved.

A particularly soft shifting transmission results in the feature of claim 2.

A particularly important embodiment of the invention results from the features of claim 3 because they are particularly effective Way shift shocks can be avoided.

An operationally reliable reversing gear results in the characteristics of claim 4.

Fig. K shows a stop device in the coupling according to the invention.

Fig. 5 shows an example of the switching on and off introductory bevels.

From a motor 2 mounted in a watercraft 1, a reversing clutch k is driven via an essentially horizontal drive shaft 3, optionally via two drive bevel gears 5 »6« which mesh with a common output bevel gear 7, an output shaft 8 leading under the water surface, on which the said output bevel gear 7 is seated. The reversing clutch and said bevel gears form a reversing gear. From the output shaft, the torque is transferred to a pair of bevel gears 9

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An embodiment with the features of claim 3 results in a |;

particularly easy to switch gear.

Further advantages and features of the invention are from the following To be found in the description.

The invention is shown on the basis of one with FIGS. 1 to 5 Exemplary embodiment explained.

Fig. 1 shows schematically the overall structure of a Z-drive for watercraft.

Fig. 2 shows a detail of a reversing gear according to the invention in section.

Fig. 3 shows the switching force increasing rolling elements that can run up on ramps.

transmitted substantially horizontal propeller shaft 10 on which the propeller 11 is arranged. This Z-drive can be designed as a so-called rudder propeller, in which the propeller for the purpose of steering the watercraft about an essentially vertical axis, e.g. the axis of the output shaft 8,
is pivotable. This pivotability is not a requirement of the invention.

The drive bevel gears 5 »6 are rotatably mounted on the drive shaft and held axially, for example with disks 13 or a shoulder lk . Between the two drive bevel gears, the drive shaft is provided with a collar or the like, which serves as a shift sleeve carrier 15. The shift sleeve carrier can also be placed on the drive shaft and fastened there. On the clutch gear a shift sleeve is moved longitudinally l6 _t is secured on the clutch gear with non-illustrated known means against rotation. A friction ring 17, 18 is rotatably centered on both sides of the shift sleeve carrier. The outer diameter of the friction rings corresponds to the outer diameter of the shift sleeve carrier. The friction rings are provided with recesses to accommodate the external toothing of so-called external disks 20. The external disks interact with so-called internal disks 21, which with internal teeth mesh with corresponding external teeth 22 of the drive bevel gears 5 »6. The plate packs formed in this way are axially aligned
supported on the outside by a pressure plate 70.70 '. The friction ring or the friction rings and the sleeve carrier are provided with milled grooves 6O, 6l, FIG. 3, on the facing side. The millings each have two flat inclined surfaces 62.63.6 (1.65.

In between there are balls as rolling elements. When friction ring and socket carrier are rotated relative to each other, the balls 66 can run onto the flat inclined surfaces, which thus serve as a ramp and thereby push the friction ring or the friction rings away from the sleeve carrier and thereby the aforementioned lamellae press together. This causes the gears to move over the lamellae, the relevant Rsibring, the relevant balls and the sleeve carrier are coupled to the shaft. Deviating from FIG. 3 the millings can also be inclined so that the rolling elements can only run onto the ramp in one direction of rotation.

The friction rings 17tl8 are pressed onto the sleeve carrier with one or more return springs Jl bent in the shape of a hairpin. For reasons of assembly, the return springs are arranged on the outside of the friction body or on the friction bodies. The shift sleeve l6 consists of a sleeve body 33 which is provided on the outside on the circumference with an annular groove Jk for a shift fork, not shown. On the inner circumference of the body is provided on the front side with two inclined surfaces converging towards the center, which are called first pressure surfaces 351 36 (FIG. 5). If the inclined surfaces of the friction bodies serving as a ramp for the rolling bodies are inclined in a certain circumferential direction, widening (deepening) the milling, then the first pressure surfaces 35 »36 converge in the same direction to the center plane (plane of rotation) of the socket body. Openings 37, which receive the return springs 31, close to the part of the sleeve body forming the first pressure surfaces. At an axial distance from the first pressure surfaces 35,36 are on the socket

body webs 38,39 provided on the the first pressure surfaces facing side with these parallel second pressure surfaces 4O, 4l form. The sleeve body and the webs form so Inwardly open grooves 42, 43 · On the circumference of the friction body, teeth 44, 45 are provided, those facing the shift sleeve Each side has a so-called counter-pressure surface 46, 47 are provided, which are parallel to the aforementioned first pressure surfaces on the sleeve body. On the other hand is that Tooth provided with a mating surface 48, 49 which is parallel to the respective facing second pressure surface on the web. In the axial direction, the grooves 42, 43 are wider than the teeth 44, 45 · On the side facing the web, the teeth are with a Surface 50,51 provided, which is at least approximately at right angles to the plane of rotation (Direction of rotation) is directed. On the side facing the teeth are the webs 38,39 with a contact surface 52,53, which is also directed approximately at right angles to the plane of rotation. In the socket carrier is one of a spring loaded locking pin 56 guided radially displaceably.

In the middle of the sleeve body there is a locking hole 57 for locking the shift sleeve is provided in the switched-off state. On the front sides of the shift sleeve there are two, after the Side open, i.e. half, locking bores 58,59 for fixing of the two switch-on states, the locking pin and the inclined surfaces support on the front sides of the shift sleeve body the switch-on process.

To describe the mode of operation, it is assumed that the drive shaft rotates in the direction of arrow 54 (FIG. 5). is

♦ · · · ff »

If the reversing clutch is switched off, the areas 50, 51 are located
of the teeth 44,45 on the stop surfaces 52,53. The rolling elements 66 are located in the deepest points of the millings. There is a relative movement between the shift sleeve and the friction rings
prevented by the surfaces 50,51 and stop surfaces 52,53 of the teeth and webs. If the left clutch is to be switched on, the shift sleeve is shifted to the left (Fig. 5). Included
the lock of web 39 and tooth 45 remains on the right side, but the lock is released on the left side. At the same time, the first pressure surface 35 touches the counter-pressure surface 46 and pushes the friction ring 18 slightly to the left. This achieves pre-coupling, ie those that come into contact
Inner and outer disks twist the friction ring against the
Direction of arrow 54 relative to the sleeve body, thereby running
the ball 6θ on the ramp and presses the larvae together,
whereby the coupling is completed. By the inclination of the
first pressure surface, its friction is reduced, it also supports the relative movement, ie the running up of the
Rolling elements on the ramp.

To switch off, the sleeve is moved to the right. Included
the second pressure surface 40 and the mating surface 48 collide, the lamellae are lifted, the friction ring 18 is removed from the
Sleeve carrier taken over the rolling elements 25 and, supported by the inclination of the second pressure surface and the mating surface as well as by the springs 31 », the rolling elements run down from the ramps and lie down again in the lowest point of the cutouts. The disengaging process is ended.

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The pressure plates 70 are with axial play axially to the inner and outer discs arranged. The play is limited on the one hand by a shoulder 71 formed by the drive bevel gears 5 * 6, 72 and on the other hand each of a snap ring 73 * 7 ^ or the like. The pressure rings are from disc springs 7517 & in the sense of coupling burdened. The snap rings are arranged so that the Lamellae are not pressed together by the pressure ring when the friction rings 17 ^ e are in the state of uncoupling. In the shift sleeve carrier 15 is or are one or more. Pins 77 are provided so that their axis is parallel to the axis of rotation. Furthermore, the pins are arranged so that their sake Perimeter in the centering 78 for the friction rings is while the other part protrudes raised from the centering. The friction rings are at their centering 7 ° * corresponding Perimeter provided with a recess 79 which surrounds the pin or pins. The pin or pins act as a stop for the friction ring in question, which can only rotate over a limited angle. Because when coupling the rolling elements run up on the ramps, the friction ring needs mobility in the circumferential direction for its axial movement. There on the other hand the pin as a stop limits this mobility, it also serves as a stop for the axial movement. When coupling pushes the friction ring does not press the lamellas against a fixed end plate but against the resiliently yielding pressure plate 70 or 70 '. the The maximum frictional force and thus the maximum transferable torque therefore depends on the tension of the spring 75 or 76.

Exceeding the predetermined overload motnents by Weeds, as it usually happens when changing gears at high speeds or

I f

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can occur in boat gears, for example in the case of groundwork not possible with the coupling described. As a result of the specified arrangement, the springs 75176 can be disengaged State does not act on the slats, because a mutual axial support is provided and the spring deflection in the direction is too limited to the slats.

List of terms

Watercraft

engine

drive shaft

Reversing coupling

/ -) Drive bevel gears

Output bevel gear

Output shaft

Bevel gear pair

Propeller shaft

propeller
12th

Discs

shoulder

Shift sleeve carrier

Shift sleeve

ο) friction ring

Outer lamellas

Inner lamellas

External gearing

Return spring

Socket body

Ring groove

first printing area

first printing area breakthroughs 38)

39) ^Ste « ^e

. ) second printing areas

Grooves

)
4 ₅ ) teeth

._) counter pressure area

Counter surface surfaces

Stop surfaces arrow

Locking pin locking hole

half locking holes milled

Sloping spheres

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j j 69 • · · 1 · ι 70 \ printing plates £ 70 ') printing plates i
Ij > Shoulders 73)
. ) Snap rings 75)
r) disc springs ! 77 pen ; 78 centering 79 recess 80 L.

Claims (3)

• r ♦ »· * * 9 ·« ψ * «t Γ2 ^ ·" * ^^ "" * "Munich," d »n April 6, 1976 wSTilTiiSI« ^ ** '11 * 2503 Lieh / Wo 356.00 IW Penalty M i (M11) 3W11 CLAIMS 1. Reversing gear, consisting of a reversing clutch and two drive bevel gears acting on a common output bevel gear, in particular for a Z-drive for watercraft, characterized in that the reversing clutch (4) consists of two friction clutches that can be alternately switched on, whose friction body with the engaging force reinforcing , on ramps or the like. Rolling bodies, such as balls (66), are pressed against one another, whereby the friction bodies are supported against resiliently flexible elements, such as disc springs (75, 76). 2. Reversing gear according to claim 1, characterized in that the friction bodies of the reversing clutch are disks. 3. Reversing gear according to claim 1, characterized in that I the resilient elements of the reversing clutch, e.g. B. I disc springs (75i76) between the friction bodies and the Drive bevel gears (5 »6) are arranged. | . Reversing gear according to Claim 1, characterized in that two stops (74, 77) are provided for the path of the resiliently flexible elements (75 »76), of which the first (77) when exceeded and the second (74) until the maximum permissible torque is effective. | η · * ■ rue t · *. »(« ff «■ · ο« _a - 2— · 5. Reversing gear according to claim 1, characterized in that the reversing clutch (4) is switched with a shift sleeve (l6) and the friction bodies, e.g. lamellae (20,21) are pressed together via friction rings, the inclined surfaces forming ramps for the force-boosting rolling bodies (66) are provided, the shift sleeve (l6) and the friction rings (I7, l8) interlocking with at least one tooth (44) and an associated groove (42) pointing essentially in the circumferential direction, the tooth and groove with the insertion and Switching off surfaces (35,46,40,48) which press on one another are provided, of which at least the surfaces (40,48) which press on one another when switching off are directed at an angle to the plane of rotation against the inclined inclined surfaces (25,28). I '6. Reversing gear according to claim 5 » characterized in that the surfaces (35,46) pressing on one another when switching on are approximately parallel to those pressing on one another when switching off f! Areas (40,48) are arranged.