DE9205254U1 - Drive for rope lifts - Google Patents

Description

TELEPHONE: 0711/7800993 FAX: 0711/7800996 TEL>SX: 1^7Xi lOr»0p=»3b fEI ETEX:2627-711104O=PAS

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KOHUER SCHMID -*- PARTNER

PATENT ATTORNEYS

KÖHLER SCHMID + P. RUPPMANNSTR. 27 D-7OOO STUTTGART 8O

19 458 S/ann

C. Haushahn GmbH & Co

Borsigstrasse 24

7000 Stuttgart-30

Drive for rope hoists

The invention relates to a drive for cable lifts with an electric drive motor which is coupled to a traction sheave over which the drive cable is guided.

Such a drive for rope lifts is common. For lifts with high ride comfort and high speeds, gearless drives are usually used, preferably with DC

motors are used, but synchronous and asynchronous motors are also used.

With gearless drives, the drive motor must generate a high torque to accelerate the elevator car. As a result, these motors quickly become very large and unwieldy, making installation very difficult. In elevator systems that are to be modernized at a later date or where a defective drive needs to be replaced, it is often very difficult to install such large motors in the existing machine rooms.

A solution to this problem is provided by gearless external rotor motors. Such a gearless external rotor motor consists of the following main components: an external rotor, a traction sheave with double bearings, an internal stator with bearing plate, a fixed axle and a second bearing plate with a brake that acts on the traction sheave from the inside.

This external rotor motor is available as both a direct current and a three-phase motor and can be disassembled into its individual components, external rotor and stator as well as traction sheave. This means that this drive motor can easily be brought into the machine room in disassembled form and assembled on site.

With a rope suspension of 1:1 and with high loads, this motor will soon become too large so that it no longer fits in the existing machine room.

It is therefore the object of the invention to enable a space-saving drive for rope lifts in such a way that it can be installed in an existing machine room without any major inconvenience, even when high loads and acceleration moments are required.

The above task is solved as claimed.

According to a basic aspect of the invention, the drive motor is formed by connecting several electric motors together, and a synchronization control brings about a synchronization of these individual electric motors.

The use of individual electric motors has the advantage that not only can an existing machine room be better utilized, but also that the individual electric motors can be connected together to adapt to different drive concepts.

Preferably, the individual electric motors are of the same type and have a modular design so that they can be broken down into their individual components, as with the known geared external rotor motor described above.

The synchronization control is preferably carried out by an electronic current, voltage frequency converter. Such electronic current, voltage frequency converters for the purpose of synchronizing several electric motors are widely known.

In one embodiment of the drive according to the invention, several gearless electric motors are mechanically rigidly connected in series. The gearless external rotor motor described above is preferably used.

In an alternative drive design, a separate rope strand is provided for moving the elevator car and a counterweight, and an electric motor with a traction sheave is provided for the synchronous drive of each rope strand. In another design, two electric motors, each with a traction sheave, are provided in parallel, and a common drive rope is driven by both traction sheaves in the manner of a pulley. In both embodiments, the gearless external rotor motor described is advantageously used.

The embodiments mentioned can also be advantageously combined, e.g. in that each of the two electric motors of the embodiment described above is formed by several gearless external rotor motors connected in series.

Gear motors can also be used for the drive concept, in which a separate rope strand is provided for moving the elevator car and a counterweight and an electric motor for synchronous driving of each rope strand. Of course, the gear motors should then be of the same type and have the same gear ratio. However, this is not necessary, as the preferred electronic

Synchronization control also allows electric motors rotating at different speeds to be synchronized.

Geared motors can also be used when using two electric motors, each with a traction sheave, in parallel, with a common drive rope being driven through both traction sheaves in the manner of a loop pulley.

The invention is described in more detail below in several embodiments with reference to the drawing. They show:

Fig. 1 a gearless external rotor motor

Fig. 2 shows a first embodiment of a drive with two gearless external rotor motors connected rigidly in series;

Fig. 3 shows a second embodiment with three gearless external rotor motors connected rigidly in series;

Fig. 4 shows a further embodiment of a double motor consisting of two gearless external rotor motors, in which the rope strand between the elevator car and the counterweight is halved and each half is driven by one of the synchronously running motors;

Fig. 5 Two gearless external rotor motors connected in parallel to form a double motor with a

Rope strand guided by a sling pulley.

The known gearless external rotor motor 1 is shown in Fig. 1. This consists of the following main components: an external rotor 2, a drive pulley 3 with double bearings, an internal stator 5a with bearing plate 5, a fixed axle 6 and a second bearing plate 4 with a brake that acts on the drive pulley from the inside.

In the IO design shown in Fig. 2, two gearless external rotor motors 11 and 12 are mechanically connected in series. An additional set of stator and external rotor is mounted on the extended rigid axle 6. The drive pulley 15, 15' is also provided with double the width. The structural multiplication of the basic components of the gearless external rotor motor shown in Fig. 2 means that the achievable torques are at least doubled with the same size of the individual modules. :

A similar design 10' is shown in Fig. 3, in which a total of three gearless external rotor motors 11, 12, 13 are mechanically rigidly coupled one behind the other on an extended rigid axis 6. An electronic synchronization control not shown in Figs. 2 and 3 ensures synchronous, tension-free operation of the rigidly coupled motors 11 and 12, or 11, 12 and 13. The synchronization control used is preferably designed as an electronic current, voltage and frequency converter and is controlled using microcomputers.

Such a converter regulates the current, voltage and frequency of each motor independently, so that both or all three motors rotate synchronously and the respective load transitions are absorbed in the same way by all motors. Since the structure of such an electronic synchronization control is known per se, it will not be explained in more detail.

The design shown in Fig. 4 and designated 20 also contains two gearless external rotor motors 11 and 12, which are not mechanically coupled but are only synchronized by an electronic synchronization control so that their direction of rotation is opposite. In this arrangement, the torque of each motor 11, 12 is transmitted via its own cable strand 21, 22 to the elevator car (not shown) and to the counterweight. This means that twice the torque is also available to accelerate the car. The fixed axles 6 and 6' as well as the bearing plate 4 and 4' with brake and the bearing plate 5 and 5' as well as the traction sheaves 15 and 16 are each present in duplicate. The arrangement shown in Fig. 4 can also be implemented with geared motors, which are preferably arranged so that the traction sheaves face each other.

Even in the embodiment 30 of the elevator drive according to the invention shown in Fig. 5, two gearless external rotor motors 11 and 12 are not mechanically rigidly coupled to a traction sheave 15 and 16, but are connected in parallel. The parallel connection is achieved by guiding the rope 21 in the manner of a loop pulley over both traction sheaves 15 and 16, so

that in this arrangement the sum of the individual moments
of the motors is available. Gear motors can also be used in this arrangement.

The two embodiments of the inventive Side 1 elevator drive described last with reference to Figs. 4 and 5 have the
Advantage that the static load of the elevator is distributed over two axes, so that the individual axis can be dimensioned weaker. In addition, despite the synchronization control, occurring
At the same time, fluctuations in the motors are compensated by the elasticity of the ropes or by slippage of the traction sheaves.

The embodiment 30 shown in Fig. 5 can also be combined with one of the embodiments shown in Figs. 2 and 3, in which instead of just one gearless external rotor motor, several such motors are connected mechanically rigidly in series in the manner shown in Figs. 2 and 3.
and work on one axis.

Claims (8)

19 458 S/anu claims 1. Drive for cable lifts with an electric drive motor, which is coupled to a traction sheave over which the drive cable is guided, characterized in that the drive motor (10; 10'; 20; 30) is formed by interconnecting several electric motors (11, 12, 13), and that a synchronization control is provided which carries out a synchronization of the electric motors. 2. Drive according to claim 1, characterized in that the electric motors (11, 12, 13) are of similar and modular construction. 3. Drive according to claim 1 or 2, characterized in that the synchronization control is carried out by an electronic current, voltage frequency converter. 4. Drive according to one or more of claims 1 to 3, characterized in that several gearless electric motors (11, 12, 13) are mechanically rigidly connected in series (Figs. 2 and 3). - &iacgr;&ogr;■-■· ·■ 5. Drive according to one or more of claims 1 to 3, characterized in that a divided rope strand (21, 22) is provided for moving the elevator car and a counterweight, and that an electric motor (11, 12) is provided for synchronously driving each partial rope strand (21, 22) (Fig. 4). 6. Drive according to one or more of claims 1 to 3, characterized in that two electric motors (11, 12), each with a drive pulley (15, 16), are provided in parallel and that a common drive cable (21) is driven in the manner of a loop pulley by both drive pulleys (15, 16) (Fig. 5). 7. Drive according to one or more of the preceding claims, characterized in that the electric motors (11, 12, 13) are gearless external rotor motors. 8. Drive according to claim 7, characterized in that the drive pulley or pulleys (15, 15'; 15, 16) can be screwed to the external rotor or rotors of the electric motors (11, 12, 13).