DE3233600A1 - MOLDING PLANT WITH SEVERAL MELT MOLDED EQUIPMENT WITH A SLIDING LOCK - Google Patents

Description

Stopinc Aktiengesellschaft, Baar (Switzerland) Case 3185

Casting plant with several melt vessels, each equipped with a slide closure

The invention relates to a casting installation according to the generic term of claim 1.

In systems of this type, it is common to have a separate drive motor with a reduction gear for each slide lock to be provided and like the closure itself to the melt vessel to assemble. This becomes necessary (in contrast to the actuation of the lock by means of a removable hydraulic lifting cylinder) considered to ensure proper mechanical power transmission between the motor and the lock via the gear members. However, compared to the hydraulic lifting drive, this requires a considerable amount of additional effort, and relatively sensitive engine is constantly exposed to very harsh operating conditions, not only at the casting station, but also at Transport of the melting vessels (e.g. steel pouring ladles, intermediate vessels in continuous casting plants).

Above all, the invention provides a more cost-effective solution for the motorized slide lock drive on the melt vessels a system aimed at. This object is achieved with the features according to the characterizing part of claim 1.

With the arrangement according to the invention, a single, on The drive unit available in the casting area actuates the closures of any number of melt vessels one after the other. Inevitable Differences in the positioning and dimensions of the individual vessels are caused by the cardan shaft balanced, and this and the quick coupling have only a low torque on the drive side of the reduction transferred to. This also keeps the reaction forces between the drive unit and the (mostly pendularly suspended) vessel are low.

According to claim 2, the rotary drive unit at the casting station be firmly mounted. It can then be accommodated in a protected place, as can the energy supply (electrical or hydraulic Lines) can be permanently installed. This simplifies maintenance and increases operational reliability. An arrangement according to claim 3 is indicated, for example, in the case of pouring ladles which are suspended from a crane in different pouring positions be driven (die casting). The rotary drive unit can advantageously have an emergency motor in addition to a main motor (Claim 4). Furthermore, the gears mounted on the vessels do not necessarily have to be used for the entire reduction ratio be designed, but it can be a partial reduction gear, according to claim 5, in the rotary drive unit be provided.

The invention is applicable to all motor-driven sliding lock types applicable, i.e. in particular twist locks, but also swivel locks and (with appropriate design of the reduction gear) linear locks. It is also conceivable that one and the same drive unit Alternately, different types of closures attached to the vessels of the system are actuated.

Embodiments of the invention are described below in conjunction explained in more detail with the drawing. Show it:

Fig. 1 the casting station e.g. a continuous casting plant with on the Ladle trolley with permanently mounted drive unit,

2 shows an example with a laterally attached to a pouring ladle Drive unit, and

3 shows a plug connection between the cardan shaft and the reduction gear in detail, in conjunction with a linear slide lock.

Fig. 1 shows a ladle carriage located at the pouring station

I with one by means of tabs 3 in a known manner on the car Detached pouring ladle 2. Under the pouring ladle there is an intermediate vessel 5 (tundish) into which the melt is poured out the pan 2 is poured off. To regulate the discharge is on A sliding lock 10, e.g. a rotary lock, is attached to the bottom of the pan and a reduction gear 11 is used to drive it is also mounted on the pan 2.

At a suitable location of the pouring station, preferably on one Console 4 of the ladle carriage 1 is designated as a whole by 20 Rotary drive unit permanently mounted. It has a drive motor 21 and an extendable cardan shaft 22 which is provided with a quick coupling 24 at the end. To the slewing ring With the quick coupling 24, the transmission 11 has a stub shaft 12 on the input side.

Thus, the rotary drive unit 20 with telescopic articulated shaft belongs to it 22 and quick coupling 24 for equipping the pouring station, while each pouring ladle intended for this pouring station 2 with slide lock 10 and reduction gear

II is provided. On a pouring ladle brought into pouring position the drive connection between motor 21 and slide lock 10 is established by attaching the quick-release coupling

24 is produced on the stub shaft 12, and after the end of casting, the drive connection is restored in an equally simple manner separated. The articulated shaft and the quick coupling of a known type can be relatively easy to measure because only a relatively low torque is to be transmitted on the input side of the reduction gear. Also comes Thanks to the extendable articulated shaft, precise positioning of the pouring ladle 2 on the ladle carriage 1 is not necessary. With this type of construction, the drive motor 21 can easily be accommodated in a protected location, where it is above all exposed to heat radiation is much less exposed. This considerably reduces the maintenance effort and the operational safety elevated. In addition to the main motor 21, as shown, an emergency motor 21 'can be provided, e.g. an electric motor can be used as a The main motor can be combined with a hydraulic motor as an emergency motor.

If the intermediate vessel 5 is also provided with a bottom closure for regulating the outflow, the same drive arrangement can in principle also be made here. A bottom closure 10 'with a reduction gear II ¹ and a rotary coupling part 12' on the input side are shown in FIG. 1 on the intermediate vessel 5 by dot-dash lines. The associated rotary drive unit (not shown), which belongs to the equipment of the pouring station, can then, for example, be stationary or mounted on the tundish trolley. Establishing and releasing the drive connection between the drive unit and the reduction gear 11 * when the intermediate vessel is changed takes place in the same way by means of the rotary coupling part 12 'and the associated quick coupling as described above in connection with the pouring ladle 2.

A stationary installation of the drive unit at the casting station is possible if the melt vessels always have the same casting

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to take position. If on the other hand, as is the case with pouring in Chill molds is common, ladles hanging on the pouring crane one after the other be moved into different casting positions, a Arrangement according to FIG. 2 can be expedient. The designated 30 The rotary drive unit is easily detachably connected to the pouring ladle 2 itself by using an auxiliary crane and the eyelet 34 is plugged into corresponding tabs on the pan shell by means of socket pins 35. The one in the pouring position The pouring ladle 2 shown above a mold 6 is again provided with a bottom closure 10, e.g. a rotary closure, and associated reduction gear 13 equipped. The rotary drive unit 30 includes the one mounted on a base 33 Motor 31 and the extendable articulated shaft 22 provided with quick coupling 24. When the unit 30 is attached to the pan 2 is, the quick coupling 24 with the stub shaft 14 of the transmission 13 can be easily coupled or uncoupled. As the This example shows, a partial reduction between motor 31 and cardan shaft 22 can be provided, as here in the form of a spur gear 32, so that the gear 13 on the pan does not perform the entire rotary reduction. The decisive factor is that the torque between the coupling parts 24 and 14 is still relatively small (compared to the one on Closure 10 required drive torque), whereby the reaction forces that the detachable connection between the drive unit and load the pouring pan (plug connection 35), also stay small.

3 shows, on a larger scale, an embodiment of the invention for driving linear slide closures; the parts belonging to the equipment of a melt vessel are shown, from the rotary drive unit of the casting station on the other hand, only the end of the extendable cardan shaft 22 with universal joint 23 and plug-in coupling 24. The one shown schematically Sliding lock 10 "is on the bottom of the pouring ladle

attached. The associated reduction gear 15 has a threaded spindle 18 with a splined shaft end 16, which is in the bearing 17 is mounted radially and axially. The spindle 18 is in engagement with a rising hollow spindle 19, which the slide of the Closure 10 ″ moved linearly according to the revolutions of the threaded spindle 18. The coupling sleeve 24 on the universal joint is attached to the shaft end 16 in a manner known per se and secured e.g. by means of a tangential pin, whereby the detachable rotary drive connection is made. This embodiment also offers the possibility of using the floor closures several melt vessels each in the pouring position of to operate a single drive motor belonging to the casting station. So it is not necessary to have one for every vessel Motor (e.g. electric motor) and, moreover, the relatively sensitive motor at the pouring station can be protected much better be accommodated.

Thanks to the extendable cardan shaft which, in the systems described above, is the connection between the pouring station equipment and the respective melt vessel, the exact location of the latter in the pouring position is not important but there can be horizontal and vertical position deviations as well as slight pendulum movements without further ado be balanced. The melt vessel can also be used in an emergency be driven away from the pouring station immediately, even without first releasing the quick-release coupling 24 by simply pressing on of the cardan shaft 22 whose inner shaft is pulled out of its hollow shaft and each part remains hanging on the relevant universal joint.

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Claims (5)

Stopinc Aktiengesellschaft, Baar (Switzerland) PA 31 85 Casting plant with several melt vessels, each equipped with a slide closure 1. Casting plant with several, optionally movable to a casting station Melt vessels, each with one via a reduction gear are equipped with an actuatable slide closure, characterized in that on each melt vessel (2,5) the reduction gear (11,13,15) has a rotary coupling part (12,14,16) on the input side and that the The plant's pouring station with a rotary drive unit (20, 30), which is connected to the rotary coupling part (12, 14,16) on a melt vessel in the pouring position (2.5) can be coupled. 2. Casting plant according to claim 1, characterized in that the rotary drive unit (20) at the casting station, e.g. on a The casting platform or on a ladle carriage (1) is permanently mounted. 3. Casting system according to claim 1, characterized in that the rotary drive unit (30) is located on a in the casting position Melt vessel (2) attached in an easily detachable manner, preferably is infected. 4. Casting plant according to one of the preceding claims, characterized in that the rotary drive unit (20) has a main motor (21) and an emergency motor (21 ¹ ). 5. Casting system according to one of the preceding claims, characterized in that between the motor shaft and the cardan shaft (22) of the rotary drive unit (30) a partial reduction gear (32) is arranged.