WO2023245213A1

WO2023245213A1 - Device for coupling an actuator to a movable object

Info

Publication number: WO2023245213A1
Application number: PCT/AT2023/060121
Authority: WO
Inventors: Christian GLOESSL; Sebastian MICHELIC; Heinz-Dieter RUMPLER
Original assignee: qoncept engineering GmbH
Priority date: 2022-06-23
Filing date: 2023-04-11
Publication date: 2023-12-28
Also published as: AT525872B1; AT525872A4

Abstract

The invention relates to a device for coupling an actuator (1) to a movable object (2), comprising an actuator (1), with a male coupling part (I) which comprises a locking pin (4) and with a female coupling part (II) which comprises a locking receptacle (6) for the locking pin (4), the female coupling part (II) having an alignment aid (3) for the male coupling part (I) to compensate for offset tolerances. In order to provide advantageous coupling conditions, the male coupling part (I) comprises a drive pin (5) which is movable relative to and in parallel with the locking pin (4), and the actuator (1) is designed as a linear drive to move the drive pin (5) in the direction of the pin axis (10).

Description

Device for coupling an actuator to a movable object

Technical area

The invention relates to a device for coupling an actuator to a movable object, with an actuator, with a male coupling part having a locking pin and with a female coupling part having a locking receptacle for the locking pin, the female coupling part being used to compensate for offset tolerances Coupling part has an alignment aid for the male coupling part. The device is a coupling device.

State of the art

From US20140112699A1 a coupling device comprising a male coupling part and a female coupling part is known. The male coupling part includes a locking pin that can be inserted into a locking receptacle of the female coupling part. By rotating the locking pin using an actuator, the two coupling parts can be locked together. The coupling device therefore only has a limited function.

Alignment aids for compensating for offset tolerances when coupling two coupling parts, especially when coupling media couplings, are known from AT523281A1. These alignment aids can also be used in the present invention.

The device according to the invention relates in particular to a multi-coupling mechanism, i.e. a coupling device that combines several functions and with which not only the object to be coupled, but also In addition, a drive mechanism for the movable object can be coupled to a base or to another object. In particular, it should be possible to establish an automatic connection between a drive and a moving object, for example between a casting ladle and a ladle casting device in the steelworks. It is currently known to have the operating personnel manually connect a slide drive (usually hydraulic cylinder) for the cast ladle to the slide cassette. Newer developments use sensor-controlled multi-axis robots, which are relatively maintenance-intensive.

Presentation of the invention

The invention is therefore based on the object of providing a device for coupling an actuator to a movable object, which ensures a quick and secure connection between an actuator and a movable object without requiring a high-maintenance structure.

The invention solves the problem in that the male coupling part has a drive pin which is displaceable relative to the locking pin and parallel to it and in that the actuating drive is designed as a linear drive for displacing the drive pin in the direction of the pin axis.

As a result of the measures according to the invention, coupling parts that are offset from one another can also be quickly connected to one another by first bringing them together, whereby the locking pin of the male coupling part is guided by the alignment aid of the female coupling part, which is preferably arranged on the movable object, to the locking receptacle and locked there. In this way, a secure alignment of the coupling parts to one another in a locking position can be achieved. The actuator, which is designed as a simple linear drive, can then control the drive pin for displacement so that it can be connected to a movable object and thus brought into the drive position. The sensitive one The drive pin, which in this drive position acts as a connecting component between the actuator and the movable object, as well as the actuator are not exposed to the risk of damage due to movements of the movable object, since this is secured in the locking position via one coupling part with the other coupling part. In the drive position, the actuator can be used as an actuator for different devices of the movable object to be actuated, so that the device can be used not only to couple the movable object to a base, but also to control various components of the movable object. Because the actuator is used both to relocate the drive pin and to drive any components in the movable object, only a small number of drive components are required, resulting in a low-maintenance device overall. In principle, the two coupling parts can be brought together manually, although the joining can be easily automated if the male coupling part can be moved in the coupling direction via an actuating cylinder. In this case, the female coupling part can be assigned to the mobile object and the mobile object can be moved via a lifting device. A cast ladle is particularly suitable as a mobile object, with the actuator in the drive position being drive-connected to a slide of the cast ladle. In this way, the cast ladle can be controlled by the actuator to release its contents.

Although it is conceivable that the locking pin and the drive pin run parallel to one another, particularly robust and failure-prone as well as compact construction conditions result when the drive pin is arranged coaxially displaceable in the locking pin. This results in a telescopic extension of the drive pin from the locking pin. At the same time, the robust locking pin protects the drive pin and, if necessary, the actuator when the two coupling components are brought together. So that the drive pin can be guided through the locking receptacle, the head of the drive pin can have a smaller diameter than the locking receptacle. So that the actuator can be connected to the movable object quickly and easily, it is proposed that the female coupling part has a drive pin receptacle for connecting the drive pin to the movable object. There can be a force and/or positive connection between the drive pin receptacle and the drive pin in the drive position. The drive pin receptacle is preferably assigned to a component of the movable object to be controlled.

For easy locking of the locking pin with the locking receptacle or the drive pin with the drive pin receptacle, the drive pin and/or the locking pin can be designed to be rotatable. In this way, the male and female components are brought together via a translational movement and the components are fixed in the locking position (between the locking receptacle and the locking pin) or in the drive position (between the drive pin receptacle and the drive pin) via a rotational movement, for example by springs of the respective pins Receiving grooves of the respective receptacles are screwed in and are thereby locked against relative movement of the components in the direction of the pin axis to one another. The rotational movement can be accomplished by one or more rotary drives. The rotary drive can rotate the drive pin and the locking pin together. Alternatively or additionally, the drive pin and the locking pin can be rotated independently of one another.

Locking is just as simple if the locking receptacle and/or the drive pin receptacle are designed to be rotatable. Their rotation can also be done via rotary drives. Both the receptacles and the pins can also be designed to rotate in opposite directions in order to further accelerate the locking process.

Preferably, the lock can comprise the locking receptacle and the locking pin in the locking position in the manner of a Bayonet lock can be formed. In a similar way, the connection comprising the drive pin receptacle and the drive pin in the drive position can be designed in the manner of a bayonet lock. In this way, the combination of the linear drive and the rotary drive can create a connection that is easy to make and release.

In order to further simplify the alignment of particularly very heavy coupling parts, the alignment aid can have a catch jaw for the locking pin and the drive pin. In this way, it is not necessary to carry out precise movements when threading the locking pin into the locking receptacle, since the catch jaw forms a correspondingly large receiving area and forms a guide to the actual locking receptacle, so that the male coupling part is automatically centered.

Especially if one of the two coupling parts, in particular the male coupling part, is mounted in a swinging manner, the coupling parts are gently centered and aligned with one another. The oscillating or resilient mounting can be such that movement compensation is made possible transversely to the coupling direction or the direction of the pin axis. In order to avoid excessive shock loads when the coupling parts are brought together, the oscillating bearing can alternatively or additionally be such that movement compensation in the coupling direction or in the direction of the pin axis is made possible.

In order to enable not only an alignment of the coupling parts to one another transversely to the coupling direction, but also an alignment in the coupling direction and at the same time to protect the drive pin from shock loads, it is proposed that the locking receptacle forms a stop for the locking pin. In this way, the movement of the male coupling part in the coupling direction is restricted, so that the coupling parts can be brought together quickly without having to take the drive pin into account, since the Locking pin anyway hits against the stop of the locking receptacle before the drive pin hits the movable object or the drive pin receptacle. At the same time, the stop aligns the locking pin and the locking receptacle in the coupling direction, which also results in faster locking.

In order to independently monitor the locking mechanism and the coupling for driving the actuator to an element of the movable object to be actuated, it is proposed that the drive pin protrudes over the locking pin in the coupling direction. In this way, the components are spatially separated in the horizontal direction so that they do not overlap each other, which provides easy access for sensors for monitoring or maintenance work.

So that in addition to the actual actuation of an element of the movable object, the object can also be equipped with the resources necessary for this, it is provided in a particularly preferred embodiment of the device according to the invention that media couplings are assigned to both coupling parts, which are preferably arranged distributed radially around the pin axis. The media couplings can thus be spaced apart from the pin axis by the same amount on both coupling parts in the radial direction and can preferably be arranged on the circumference around the pin axis. When the coupling parts are aligned with one another, the media couplings are also aligned so that they can be coupled to one another automatically. Media such as electricity, hydraulic fluid and/or cooling fluid can be provided via the media couplings.

Particularly robust and easy-to-automate coupling conditions arise when the male coupling part is mounted in a bearing block and when the bearing block can be moved in the coupling direction via an adjusting cylinder. The bearing block can be moved using rollers. In addition, the housing of the bearing block offers protection for any sensitive ones Components of the device, such as the actuator and the oscillating bearing of the male coupling part.

Brief description of the invention

The subject matter of the invention is shown schematically in the drawing, for example. Show it

1 shows a device according to the invention with a cast ladle as a movable object in a partially sectioned side view,

2 shows a detail of the device according to the invention from FIG. 1 in a released position and in an enlarged, partially cut cross section,

Fig. 4 shows the female coupling part II from Fig. 3 in section along line IV-IV and Fig. 5 shows a design variant of the device according to the invention with media couplings.

Ways of carrying out the invention

A device according to the invention for coupling an actuator 1 to a movable object 2, for example a cast ladle, comprises, for example, FIGS. 1 and 2, a first, male coupling part I and a second, female coupling part II with an alignment aid 3 for the male coupling part I to compensate for offset tolerances when coupling the two coupling parts I, II. The male coupling part I also has a Locking pin 4, which can be connected to a locking receptacle 6 of the female coupling part II. According to the invention, the male coupling part I has a drive pin 5 which can be connected to an element of the movable object 2 to be actuated and which is displaceable in or on the male coupling part I relative to the locking pin 4 and parallel thereto. The drive pin 5 can be connected via the actuator 1 designed as a linear drive Direction of the pin axis 10 can be shifted. In this way, the actuating mechanism, comprising the drive pin 5, is decoupled from the force-absorbing locking mechanism, comprising the locking pin 4 and the locking receptacle 6, and is therefore not exposed to any external forces, since these are carried by the locking mechanism. Since the actuator 1 is a simple linear drive and is used both to relocate the drive pin 5 and to drive any components in the movable object 2, the drive is extremely simple and requires little maintenance. With the alignment aid 3 leading to the locking receptacle 6, the locking pin 4 and the drive pin 5 can be aligned with the female coupling part II, resulting in a quick coupling.

Particularly reliable protection of the drive results when the drive pin 5 is arranged coaxially in the locking pin 4 so that it can be moved. The drive pin 5 is therefore telescopically displaceable in the locking pin 4, so that the locking pin 4 forms a protective outer shell for the drive pin 5. Advantageously, centering the locking pin 4 also results in a centering of the drive pin 5, which further facilitates alignment during the coupling process.

In order to make the connection to the element to be actuated, for example to a slide 20, particularly simple, the female coupling part II can have a drive pin receptacle 7 for the drive pin 5, which is connected to the element to be actuated. In this way, the drive can also be connected to the element to be actuated automatically.

For mutual locking of locking pin 4 and locking receptacle 6 on the one hand and drive pin 5 and drive pin receptacle 7 on the other hand, the locking receptacle 6 and the drive pin receptacle 7 can have a receiving groove 8 for springs 9 of the locking or drive pin 4.5 (Fig. 2). The springs 9 can preferably be screwed into the receiving grooves 8. For this you can Drive pin 5 and / or the locking pin 4 can be designed to be rotatable. Alternatively or additionally, the locking receptacle 6 and/or the drive pin receptacle 7 can be designed to be rotatable. The rotation can take place via a rotary drive 12. Fig. 2 shows the device, with the coupling parts l, ll being detached from one another. If the male coupling part I is now guided into the coupling part 2 until the locking pin 4 and the drive pin 5 are in their corresponding receptacles 6.7, the springs 9 can be screwed into the receiving grooves 8 by rotating the locking and drive pin 4.5 , so that a secured locking and drive position shown in FIG. 3 is entered into. In an alternative embodiment, locking pin 4 and drive pin 5 can be rotated independently of one another, so that first the locking pin 4 inserted into the locking receptacle 6 is rotated, whereby a secure locking position can be achieved, and only then the drive pin 5 via the actuator 1 in the direction of the drive pin receptacle 7 is brought and then rotated, whereby the drive position in which an element of the movable object 2 to be actuated can be controlled is entered. From Fig. 4, the locking and drive position, in which the springs 9 are screwed into the receiving grooves 8 in the manner of a bayonet lock, can be seen.

So that when the coupling parts 1, ll are brought together, the locking pin 5 is aligned with the locking receptacle 6 in the coupling direction R, the locking receptacle 6 can form a stop 23 for the locking pin 5. The male coupling part I is therefore guided into the female coupling part II until the locking pin 5, preferably its springs 9, strike, after which it can be screwed into the locking position, since the stop 23 is of course aligned in such a way that the receiving groove 8 of the locking receptacle 6 and the spring 9 of the locking pin 5 lies in one plane in the stop 23.

For example, from Fig. 5 it can be seen that the alignment aid 3 can have a catch jaw 11 for the locking pin 4 and the drive pin 5. The Drive pin 5 can protrude beyond the locking pin 4 in the coupling direction R.

5 further shows that media couplings 13-16 can be assigned to both coupling parts I, II, which are preferably arranged distributed radially around the pin axis 10.

In the Figs. 2, 3 and 5 it is indicated that a coupling part I can be mounted in a swinging manner by a resilient suspension 21. This resilient suspension 21, together with the catch jaw 11, allows larger deviations of the coupling parts l, ll to be coupled. In this way, the object 2 with the coupling part II assigned to it can be placed in the vicinity of the other coupling part I, for example with the help of a crane 22. The male coupling part I, which is arranged, for example, in a bearing block 17 and which can be displaced on rails 18 in the coupling direction R, can be brought to the female coupling part II of the object 2 using the actuating cylinder 19. At the same time, if at least one additional media coupling 13-16 is provided, this can also be coupled, for example for coupling actuators, as well as media (e.g. cooling air, inert gas shielding) and electrics (e.g. early slag detection) in one movement. The coupling device has a compact size, is space-saving and can be integrated into existing systems.

Overall, the result is a robust, low-maintenance and easy-to-couple coupling device.

A manipulator drive, in particular the actuating cylinder 19, moves the coupling part I assigned to it in the direction of the catch jaw 11 of the other coupling part II. The alignment aid 3, together with the resilient bearing 21 of the other coupling part, compensates for axial deviations and inclination errors. The coupling is self-centering. The locking pin 4 is resiliently mounted together with the drive pin 5 (in particular resiliently suspended in the bearing block). The movement in the clutch direction R stops, if, for example, springs 9 projecting radially outwards (protruding from the drive pin 4 and/or drive pin 5) come into contact with a stop 23 of the respective counterpart (for example a bayonet pin guide) of the other coupling part. At the same time or with a predetermined short stroke, it is ensured that both pins, namely the locking and drive pins 4.5, are in contact with the corresponding counterparts. The locking is then carried out with the rotary drive 12 by, for example, simultaneously turning the locking and drive pins 4.5 until the bayonet lock is closed. The bearing block 17 is now firmly connected to the object 2. Any media couplings are also connected. The drive pin 5 is drive-connected to the slide 20, which can now be actuated with the actuator 1. Actuating forces are absorbed by the coupling in the area between the locking pin 4 and the locking receptacle 6. The entire clutch is coupled and the slide 20 is ready for operation. Uncoupling takes place in the reverse order.

Claims

Patent claims

1 . Device for coupling an actuator (1) to a movable object (2), with an actuator (1), with a male coupling part (I) having a locking pin (4) and with a locking receptacle (6) for the locking pin (4), having a female coupling part (II), wherein to compensate for offset tolerances, the female coupling part (II) has an alignment aid (3) for the male coupling part (I), characterized in that the male coupling part (I) has a relative to the locking pin (4) and has a drive pin (5) displaceably arranged parallel to this and that the actuating drive (1) is designed as a linear drive for displacing the drive pin (5) in the direction of the pin axis (10).

2. Device according to claim 1, characterized in that the drive pin (5) is arranged coaxially displaceable in the locking pin (4).

3. Device according to claim 1 or 2, characterized in that the female coupling part (II) has a drive pin receptacle (7) for connecting the drive pin (5) to the movable object (2).

4. Device according to one of claims 1 to 3, characterized in that the drive pin (5) and / or the locking pin (4) are designed to be rotatable.

5. Device according to one of claims 1 to 4, characterized in that the locking receptacle (6) and / or the drive pin receptacle (7) are designed to be rotatable.

6. Device according to one of claims 1 to 5, characterized in that the lock comprises the locking receptacle (6) and the Locking pin (4) is designed in a locking position in the manner of a bayonet lock.

7. Device according to one of claims 3 to 6, characterized in that the connection comprising the drive pin receptacle (7) and the drive pin (5) is designed in a drive position in the manner of a bayonet lock.

8. Device according to one of claims 1 to 7, characterized in that the alignment aid (3) has a catch jaw (11) for the locking pin (4) and the drive pin (5).

9. Device according to one of claims 1 to 8, characterized in that one of the two coupling parts (I, II) is mounted in a swinging manner.

10. Device according to one of claims 1 to 5, characterized in that the locking receptacle (6) forms a stop for the locking pin (4).

11. Device according to one of claims 1 to 6, characterized in that the drive pin (5) projects beyond the locking pin (4) in the coupling direction (R).

12. Device according to one of claims 1 to 10, characterized in that both coupling parts (I, II) are assigned media couplings (13-16), which are preferably arranged distributed radially around the pin axis (10).

13. Device according to one of claims 1 to 12, characterized in that the male coupling part (I) is mounted in a bearing block (17) and that the bearing block (17) can be displaced in the coupling direction (R) via an adjusting cylinder (19).