EP3245127A1

EP3245127A1 - Braking-stopping unit for command issuer

Info

Publication number: EP3245127A1
Application number: EP16707615.7A
Authority: EP
Inventors: Karl-Heinz Schweer; Anja QUAST
Original assignee: Aventics GmbH
Current assignee: Aventics GmbH
Priority date: 2015-01-15
Filing date: 2016-01-15
Publication date: 2017-11-22
Anticipated expiration: 2036-01-15
Also published as: DE102015000192B4; DE102015000192A1; EP3245127B1; US20180329446A1; ES2692023T3; WO2016112893A1; CN107406132A; DK3245127T3; US10401897B2; CN107406132B

Abstract

The invention relates to a braking-stopping unit for the defined stopping and braking of a manually operable command issuer for ship's drives, comprising an external rotor (1, 1') with a circular opening forming a bearing ring and an inner rotor (2, 2', 2") arranged in the opening, which are arranged in a rotationally movable manner relative to each other, wherein one of the two rotor elements is statically fixed in its position and the other rotor element is designed either with a manually operable actuator or constructed so as to be connectable to such an actuator. The inner rotor (2, 2', 2") is configured with at least three spring arms (3, 3', 3", 3"', 3a, 3b) which are radially arranged in the circumferential direction and are connected thereto on one side, wherein said spring arms can be pushed into a respective recess arranged in the outer surface of the inner rotor (2, 2', 2"), at least one spring arm (3", 3a, 3b) being provided at its free end with a stopping means (5, 5a, 5b, 5a', 5b') which cooperates in a detachable and form- and force-locking manner with at least one corresponding latching recess in the running surface (6) of the bearing ring and at least two spring arms (3, 3', 3'") being arranged in each case in pairs within the rotational plane to rotate in opposition to each other and having a braking means (4, 4', 4 ") at each of their free ends. According to the invention, the spring arms (3, 3', 3", 3'", 3a, 3b) act in each case radially non-positively on the running surface (6) of the bearing ring via the braking (4, 4', 4") and stopping means (5, 5a, 5b, 5a', 5b').

Description

Brake detent unit for command transmitter

Technical area

The invention relates to a unit for defined locking and braking of a manually operable command transmitter for the speed and transmission adjustment of

Ship propulsion.

State of the art

The field of application of the present invention extends to the

Ship control technology. The helm of ships is usually equipped with a command transmitter for remote control of the ship propulsion. The commanders acts here today usually as an actuator via an electrical connection to an electric engine control of the ship's drive directly controlling the speed and / or transmission adjustment of the ship's drive. Such manually mechanically adjustable command transmitter must be performed sufficiently stable to protect against accidental adjustment by vibration or light touch to remain safe in the selected position. At the same time they should be sensitive and adjustable without noticeable breakaway torque between the switching positions. For exact control, it is also necessary that the actuator engages clearly noticeable at the switching positions of the travel. Typical switching positions are with drives with

For example, the positions Gearbox Neutral - Gearbox Advance - Gearbox reverse are reversed, the position Propeller Neutral for drives with variable pitch propellers. In commonly known in the art commanders the locking function is often performed on spring-loaded balls or rollers that engage releasably in a corresponding counterbore or groove. For example, for the brake function

| Confirmation copy Band brakes that act on a shaft, or axially acting brake elements that act spring loaded on a disc used. A disadvantage of these solutions that a large number of components is required, which must be positioned precisely and move as free of play to each other. A detent ball that does not grasp the ball socket exactly or a brake with backlash creates a spongy acting and give the impression of lack of precision. Each of these components is also subject to wear, which is why the implementation of

various functions with as few components is desirable.

Finally, the assembly of many small items is uneconomical.

From DD 244533 AI is a command generator for marine propulsion with a drive lever, a switching disc and a driven by a first hydraulic actuator locking disk, which are mounted on a rotatably mounted shaft known. In the

Detent disc engages a locking pin, which is actuated by a further hydraulic actuator motor. Furthermore, a brake acting on the edge of the locking disc is provided, which is actuated by a third servo motor. The proposed by DD 244533 AI locking and braking function is complex due to the required hydraulic actuators, production-consuming and has a high space requirement. From DE 19936946 Cl a command generator for marine propulsion is known with a guided in a shift gate, in two functional levels pivoting hand lever. For engaging the shift lever in its switching positions, DE 19936946 Cl provides a disk connected to a pivot shaft with circumferential recesses into which engages a resiliently mounted detent pin. For automatic reset of the

Hand lever in a rest position engages a tension spring to this. In addition to the storage of the hand lever regardless of this carried out reset and locking functions each require additional components and have an additional space requirement. By acting on him tension spring pivotal movement of the hand lever is braked only in a direction of movement against the spring force. Other means for stabilizing braking the pivoting movements of the hand lever are not disclosed by DE 19936946 Cl. From DE 199 63 476 A 1 a commander of the aforementioned type is known, which is rotatably mounted in addition to its longitudinal axis in both directions of rotation against a spring action and the rotational movement detecting sensor for controlling an aggregate, for example. A motor control having. The addition to the storage of the hand lever regardless of this executed spring damping of the rotary motion requires additional components and has an additional space requirement.

From DE 1 992 922 U a locking device for a machine telegraph is known, in which a command lever with a detent roller is displaceably guided on a detent track. Such a device has depending on the selected height of the locking projections relative to the recesses either a relatively high breakaway torque or a relatively unstable position in the respective switching position. Furthermore, it is advantageous to design the command generator pivotally on a circular path, rather than linear

slidable, since this is space-saving in providing a switching path of the same length and allows a more ergonomic operation.

From DE 103 52 445 B4 is a braking element for the controlled opening and

Closing hoods, drawers, drawers, etc. known. The brake element comprises an outer rotor with a bearing shell forming an opening and an inner rotor disposed in the opening, which are rotatably mounted relative to each other, wherein the inner rotor one or more radially against a spring force can be erected, one-sided connected to this braking members, each in a in the lateral surface of the inner rotor introduced recess can be pressed and bear against the inner surface of the bearing shell. The disclosed by DE 103 52 445 B4 brake element (so-called Minibremselement) is not suitable for use as a command transmitter due to its spatial dimensions and also provides no manually operated actuator, such as a lever, or means for mounting such an actuator before. In addition, the brake element exerts due to the identical orientation of the or the brake elements within the plane of rotation only in one direction - against the Aufstellmoment the brake elements - a braking function or the braking function in the opposite direction is at least significantly reduced. Finally, see the DE 103 52 445 B4 proposed brake element no means for locking the inner rotor against the outer rotor before.

DISCLOSURE OF THE INVENTION

The invention has for its object to provide a storage unit for a manually operated command transmitter with an integrated combined braking / locking function, which is as compact and simple as possible and can be easily and inexpensively manufactured and assembled. The object is achieved by a braking / locking unit according to claim 1, advantageous embodiments are described in the subclaims.

The core of the invention is a brake-locking unit for command transmitter with an outer rotor with a bearing ring forming a circular opening and an opening disposed in the inner rotor, which are arranged rotatably relative to each other, one of the two rotor elements statically fixed in position and the other rotor element is designed either with a manually operable actuator or designed with such a connectable and the inner rotor is arranged with at least three radially arranged in the circumferential direction and one side connected to this spring arms, which are each located in a in the lateral surface of the inner rotor

Recess are pressed, wherein at least one spring arm is formed at its free end with a latching means which releasably positively and non-positively with at least one corresponding recess in the running surface of the bearing ring

interacts and at least two spring arms in pairs within the

Rotation plane to each other in opposite directions and are formed at their free ends in each case with a braking means and wherein the spring arms via the brake and locking means in each case act radially frictionally on the running surface of the bearing ring. The respectively in its position statically fixed rotor element serves as fixed in its position stator (inside or outside stator), for example, by being mounted on or on a console or an elevated housing. The other, in this rotatably mounted rotor element (inner or outer rotor) is used to change the

Switching position by either using a manually operable actuator, For example, a lever, is formed or configured with such a connectable by having, for example, holes for screwing a control lever. The spring arms arranged in the circumferential direction with braking means exert different friction moments on the running surface depending on the direction of rotation. This is greater in the direction of rotation against the pitching moment of the respective spring arm than in the opposite direction. By the spring arms with braking means in the plane of rotation are arranged in pairs opposite each other in opposite directions, the two friction moments exerted by them add up to an identical Gesamtreibmoment, whereby the brake / locking unit is braked substantially uniformly stabilizing in both directions. The latching recess (s) in the running surface of the bearing ring each represent the switching position (s) of the brake / latch unit. By the or the spring arm (s) with locking means in the switching position in each case form-fitting in the

corresponding recessed recess engages in the running surface of the bearing ring, the brake / locking unit is stabilized in the respective position. In a renewed adjustment or the respective spring arm (s) is pressed with latching means in the respective recess in the lateral surface of the inner rotor, wherein the latching means leaves the respective latching recess again.

An even greater uniformity of exerted in both directions

Braking effects is achieved by at least two spring arms are provided with locking means in a brake-latching unit with a total of at least four spring arms and in pairs opposite to each other within the plane of rotation, wherein the locking means are arranged in a common radial portion and in each case synchronously with the or the recess (en) interact. The spring arms with locking means act radially non-positively on the running surface of the bearing ring and thus exert a certain frictional torque against the rotation of the brake / latch unit. This is greater in the direction of rotation against the pitching moment of the respective spring arm than in the opposite direction. By the spring arms are arranged with locking means within the plane of rotation in pairs opposite to each other in opposite directions, and the force exerted on the locking means Gesamtreibmoment is the same in both directions of rotation. By in the above embodiment, the locking means are each a Federarmpaares arranged in a common radial portion and respectively synchronously cooperate with the same recess, at the same time an identical breakaway torque is ensured when releasing the detent in both directions without an additional second recess for each spring arm second locking means must be provided in the running surface of the bearing ring. For this purpose, the locking means of a Federarmpaares within the same radial portion are preferably arranged adjacent to each other in the circumferential direction. This ensures a compact design while maintaining a steady in both directions breakaway torque.

For a more precise adjustability of the brake / latching forces and an increase in the range of application of the brake / latch unit, the spring arms with brake means and / or the spring arms with latching means are configured spring-loaded, wherein the compression springs are arranged in the inner rotor and act radially on the spring arms. In this embodiment, the required for the desired friction torque of the braking means and the sufficiently stable seat of the locking means radial force is generated substantially by the bias of the compression springs. Compression springs can be designed due to the design at a correspondingly predetermined preload and spring force with a much smaller spring rate than is possible with only designed as leaf springs spring arms. Thus, the spring force and thus also the radial force exerted by you on the brake and locking means can always be made almost constant even with different component tolerances. Furthermore, the radial forces required for the desired friction torque and the desired stability of the seat of the latching means in the latching recesses - independently of each other - can be varied and adapted to different requirements.

For a particularly simple and inexpensive manufacture and assembly of the brake-locking unit, the spring arms, locking means and braking means are designed with the inner rotor as a one-piece component. The braking / locking unit consists in this embodiment with all the necessary functional elements only two components.

In the above embodiment, by using the inner and outer rotors as plastic Molded parts are made, the production can be further simplified and costs can be further reduced. Furthermore, this design ensures a very low overall weight of the device. An improvement in the smooth running of the brake / latch unit is achieved by the rotor elements are designed with a common ball bearing.

To improve the operation of the rotor elements are formed with a stop limit, which limits their rotatable degree of freedom. In this way, the extension of the switching path of the brake / latch unit is limited to the switching positions.

For automatic detection of the parking position of the brake-locking unit is the

rotatable rotor element formed with a sensor magnet. This allows recordable, in cooperation with a corresponding Hall sensor, a non-contact detection of the angular position of the rotatable rotor element and thus also an associated with this actuator.

Further measures improving the invention will be described in more detail below together with the description of preferred embodiments of the invention with reference to FIGS. Show it:

Figure 1 is a perspective exploded view of a brake / latch unit for a

Commander,

Figure 2 is a perspective front view of the brake / latch unit according to FIG

1 in the assembled state,

Figure 3 is a perspective top view of an alternative embodiment

Inner rotor of a brake / detent unit according to FIGS. 1 and 2,

Figure 4 is a perspective sectional view of another embodiment of Brake / catch unit,

FIG. 5 shows a perspective front view of the assembled brake / detent unit according to FIG. 4.

1 and 2 consists of an outer rotor 1 and an inner rotor 2, which is formed with three spring arms 3, 3 'and 3 "arranged radially in the circumferential direction and fixedly connected thereto on one side, designed as leaf springs The spring arms 3, 3 'and 3 "are respectively corresponding recesses in the lateral surface of the inner rotor 2, in which the spring arms 3, 3' and 3" can be pressed in. The spring arms 3 and 3 'are at their free end with the braking means 4 and 4 ', the spring arm 3 "formed with the locking means 5. The spring arms 3, 3 ', 3 ", the brake means 4, 4' and the latching means 5 are designed as a one-piece component with the inner rotor 2. The outer rotor 1 has a circular opening which has a bearing ring with the running surface 6 for receiving the inner rotor The outer rotor 1 is formed with three latching recesses 7, 7 'and 7 "which serve for the positive reception of the latching means 5 and the corresponding one

Determine switching positions of the brake / latch unit. For assembly, the spring arms 3, 3 ', 3 "are pressed into the respective corresponding recesses in the lateral surface of the inner rotor 2 and the inner rotor 2 is inserted into the outer rotor 1. Due to the prestressing produced thereby, the spring arms 3, 3', 3" act in the mounted state radially non-positively on the tread 6 of the extra rotor 1. In this way, in particular on the braking means 4 and 4 'generates a friction torque, the one

Rotary movement of the inner rotor 2 against the outer rotor 1 counteracts. The

Bias of the spring arms 3, 3 'is in this case selected such that they generate the radial force required for the desired friction torque. The two in

Circumferentially arranged spring arms 3 and 3 'exercise on the braking surface 4 and 4' depending on the direction of rotation different friction moments on the tread 6. This is greater in the direction of rotation against the pitching moment of the respective spring arm than in the opposite direction. By the two spring arms 3 and 3 'are arranged in opposite directions in the plane of rotation, the two friction moments exerted by them add up in each case to an identical Gesamtreibmoment, whereby the brake / Rasteinheit is braked in both directions substantially uniformly stabilizing. The bias of the spring arm 3 "is chosen such that a sufficiently stable positive and non-positive fit of the locking means 5 in the

Locking recesses 7, 7 'and 7 "is guaranteed in the switching positions at the same time as low breakaway torque when loosening the seat.The preload is thus chosen so that an accidental adjustment by vibrations during driving or a light touch sufficiently reliably avoided, however A rotationally symmetrical seat of the inner rotor 2 in the outer rotor is ensured by the additional guide means 8. In the brake / detent unit according to FIGS. 1 and 2, the outer rotor 1 serves as a stator, in which it acts via the radial The inner rotor 2 is rotatably mounted in the installed state in the outer rotor 2 and serves to manually change the switching position by means of a control lever, which via the frontal bores 10 and 10 ' at the inner rotor 2 can be screwed.

FIG. 3 shows an alternative embodiment of an inner rotor 2 ', compatible with the outer rotor 1, with two mutually opposite directions within the plane of rotation

arranged spring arms 3a and 3b with locking means 5a and 5b. In tests with the

Embodiment of the inner rotor 2 according to Figures 1 and 2 showed that the spring arm 3 "on the locking means 5 in the for a sufficiently stable positive and non-positive fit in the recesses 7, 7 'and 7" required bias to a certain friction torque the tread 6 of the outer rotor 1 exerts. This

Frictional torque is greater in the direction of rotation against the moment of installation of the spring arm 3 "than in the opposite direction

Rotation level to each other oppositely arranged spring arms 3a and 3b with locking means 5a and 5b is replaced, is also the over the two locking means 5a and 5b exerted Gesamtreibmoment equal in both directions and ensures an absolute uniformity of the force exerted in both directions of braking. Since the two latching means 5a and 5b are also arranged in a common radial section and in each case interact synchronously with the latching recesses 7, 7 'and 7 ", in this embodiment of the inner rotor 2' is also identical in both directions of rotation Losbrechmoment ensured without additional recesses in the

Tread 6 must be created.

Figures 4 and 5 show an alternative embodiment of the brake / latch unit. The outer rotor 1 'and the inner rotor 2 "are designed with an integrated ball bearing and form with the groove elements 1 la and 1 lb a common circumferential groove for balls arranged in it, of which on the sectional view of Figure 4, the cut balls 12 and 12' Since the bearing is designed as a fully spherical bearing, no separate ball cage is required.The running groove is sufficiently deep so that axial forces can also be absorbed, thereby ensuring that one with the end holes 10 "'and 10" ". 4 and 5, not shown in the axial and radial direction is guided backlash and no significant additional friction torque is generated by bearing friction of the inner rotor 2 "all spring arms with braking and locking means, of which on the

4, only the spring arm 3 "'can be seen, in this embodiment are designed to be spring-loaded.For this purpose, compression springs are respectively arranged in the inner rotor 2" under the spring arms. 4 shows only the compression spring 13 arranged below the latching means 5a 'and 5b' and partially the compression spring 13 'arranged under the braking means 4. For limiting the degree of freedom of the inner rotor 2 and thus also limiting the

Swiveling path of an adjusting lever connected to the front-side bores 10 "'and 10""of the inner rotor 2", not illustrated in FIGS. 4 and 5, the inner rotor 2 "and the outer rotor 1' are designed with a limit stop on the front side. The stop element 14a connected at the end side is guided between two stop elements 14b and 14b 'connected to the outer rotor, whereby the degree of freedom of the rotational movement of the inner rotor 2 "is limited to a total of 140.degree .. The inner rotor 2" is also provided with a recess 15 for receiving one in the front side Figures 4 and 5, not shown sensor magnet provided. In cooperation with a corresponding, not shown in Figures 4 and 5 Hall sensor, which is arranged perpendicular to the axis of rotation of the brake locking unit at a distance of 0.5 to 2mm in front of the sensor magnet, this allows a non-contact detection of the angular position of the Inner rotor 2 "and thus one with this connected control lever. For sealing the device interior of the brake locking unit relative to the environment of the outer rotor 1 'has a circumferential sealing groove 16 for receiving a (not shown) O-ring. The seal against the adjusting lever via a lip seal. The running surface of the sealing lip 17 is protected by a protective ring 18 against direct exposure to spray or jet water.

LIST OF REFERENCE NUMBERS

1, 1 'outer rotor

2, 2 ', 2 "inner rotor

3, 3 ', 3 ", 3"', 3a, 3b spring arms

4, 4 ', 4 "braking means

5, 5a, 5b, 5a ', 5b' locking means

6 tread

7, 7 ', 7 "recess

8 guiding means

9 tapped hole

10, 10 ', 10 ", 10"' bore

I Ia, I Ib groove element

12, 12 'ball

13, 13 'compression spring

14a, 14b 'stop elements

15 recess

16 sealing groove

17 sealing lip

18 protection ring

Claims

claims

A brake control unit for a command transmitter, comprising an outer rotor (1, 12) having a bearing opening forming a circular opening and an opening disposed in the inner rotor (2, 2 ', 2 "), which are arranged rotatably relative to each other, wherein one of the two Rotor elements fixed statically in its position and the other rotor element is formed either with a manually operable actuator or configured with such a connectable and the inner rotor (2, 2 ', 2 ") with at least three radially arranged in the circumferential direction and one side connected to this spring arms ( 3, 3 ', 3 ", 3"', 3a, 3b) is formed, which in each case in a in the outer surface of the inner rotor (2, 2 ', 2 ") located recess are pressed, characterized in that at least one spring arm ( 3 ", 3a, 3b) at its free end with a latching means (5, 5a, 5b, 5a ', 5b') is formed, which releasably positively and non-positively with at least one corresponding Rastausnehmun g in the running surface (6) of the bearing ring cooperates and at least two spring arms (3, 3 ', 3 "') in pairs within the

Rotation plane to each other in opposite directions and at their free ends each with a braking means (4, 4 ', 4 ") are formed, wherein the spring arms (3, 3', 3", 3 "', 3a, 3b) via the brake ( 4, 4 ', 4 ") and latching means (5, 5a, 5b, 5a', 5b in each case radially

frictionally acting on the running surface (6) of the bearing ring.

2. brake-latch unit according to claim 1 with at least four spring arms (3, 3 ', 3 ", 3'", 3a, 3b), characterized in that at least two spring arms (3a, 3b) with latching means (5a, 5b) is provided and in pairs within the plane of rotation are arranged in opposite directions to each other.

3. brake-latching unit according to claim 2, characterized in that the latching means (5a, 5b, 5a ', 5b') are arranged in each case a Federarmpaares in a common radial section and in each case synchronously with the or the latching recess (s) (7, 7 ', 7 ") interact.

4. brake-latch unit according to one claims 1 to 3, characterized in that the

Spring arms (3 "') with braking means (4") and / or the spring arms with latching means (5a ¹ , 5b') are configured spring-loaded, wherein the compression springs (13, 13 ') in the inner rotor (2 ") are arranged and act radially on the spring arms (3"').

5. brake-latching unit according to one claims 1 to 4, characterized in that the spring arms (3, 3 ', 3 ", 3'", 3a, 3b), latching means (5, 5a, 5b, 5a ', 5b') and braking means (4, 4 ', 4 ") are designed with the inner rotor as a one-piece component.

6. brake-latch unit according to claim 5, characterized in that the inner (2, 2 ', 2 ") and outer rotor (1,) are designed as plastic injection molded parts.

7. brake-locking unit according to one of claims 1 to 6, characterized in that the rotor elements are designed with a common ball bearing.

8. brake-latching unit according to one of claims 1 to 7, characterized in that the rotor elements are formed with a stop limit.

9. brake-latching unit according to one of claims 1 to 8, characterized in that the rotatable rotor element is formed with a sensor magnet.