DE4241351C1 - Device for controlling a cable-driven hoist - Google Patents

Description

The invention relates to a device for control a rope driven hoist according to the Preamble of claim 1.

With rope-driven hoists at least one motorized pulley used. The rope is running often via at least one pulley and / or Pulleys, and there is one at the end of the rope Bracket device, in the simplest case a crane hook. The with the bracket to which the lifting load is to be approached Delivery stations for the load are often from the Control device for the motor-driven pulley spatially separated. A precise control of Positions for the load along the route is therefore often extremely difficult.

The device according to the invention can in particular are used with rope-driven hoists like the one they are on drilling equipment e.g. B. for drilling for petroleum or Natural gas can be used. Here, the must from numerous Existing drill string in the course of the drilling be assembled or disassembled if e.g. B. the drill string for replacing the chisel from the Borehole must be pulled up. To do this, the Hoist between a lower position in the area of the Drilling platform and an upper position in the area of Periodically move the upper work platform back and forth become. Under the difficult conditions of drilling such as shift operation and climatically unfavorable conditions the desired positions are often not sufficient  approached exactly. Exceeding the positions too far can cause serious damage to the derrick or Lead drilling platform. It is therefore important that desired positions on the route as automatically as possible to control or in good time before reaching the desired position controls the drive device slow down.

There are no facilities from the prior art known with which this could be achieved. In US 4,616,321 is an observation device for a Drilling rig described in the case of the tower roll Devices for determining the drilling depth arranged are. There is also a weight sensor on the motor-driven pulley (dead rope anchor) and a Detector arranged below the tower roller. With these A signal is given when the facilities moving pulley of the pulley in the area of Tower roll arrives. The one attached to the tower roller Sensor enables due to the always existing Slip does not exactly control positions along the driveway. The lower approach position in The area of the drilling platform cannot be detected. After all, there is no controlled release Braking.

According to GB 2 154 026 A there is a sensor on the tower roller provided with which the route of said Stranges should be determined. This occurs the above disadvantages already mentioned. It is also a second sensor provided with which the location of the Pipe connections should be recognized. This is with the regularly soiled strands are not sufficient for sure.

The object of the invention is to provide a generic device for Specify control of a rope-driven hoist with the desired positions along the route in can be started automatically in a safe manner.

The problem is solved by a device according to claim 1. Claim 7 describes a Use of the device according to the invention for the Control of a rope-driven hoist on one Derrick.

The object is achieved according to the invention by a device having the features of claim 1.

Instead of the lifting device, another device can also be moved End of rope can be used as a reference point. It is further provided to register the weight on the hoist. Out representative of the position of the hoist Signal that at any time during the movement of the hoist or at least when using digital signals in there are very short intervals According to the invention, the desired positions first started one after the other. For each position, the becomes the measured value belonging to the position is saved. Then will using brake tests along the route for at least two speeds of rotation of the driven Rope pulley determines the braking distance. The brake tests become the dependence of the braking distance on the speed of the motorized role set. While driving then at any time the position of the mounting element and the speed of the motor-driven pulley and the associated required braking distance known. The braking distance can also be used at variable speeds Reach the desired positions. For this, the automatic driving style Braking device in good time before reaching the  desired positions activated. Because of the the necessary number of revolutions necessary braking distance known is the braking can be controlled so that the Holding element stops at the desired position. As far as speed-dependent braking devices such. B. Eddy current brakes can be used additional braking devices, e.g. B. disc or Drum brakes, then be activated. Latter can also immediately if the eddy current brake fails activated for braking.

Using the attached figure, the device in an embodiment of a drilling rig explained.

The desired positions 11 and 12 are to be approached on a drilling rig 1 with a cable pull, to which a holding element 13 is attached. Position 11 corresponds to the upper work platform. Position 12 corresponds to the required distance above the drilling platform. To control the drilling system including the motor-driven roller 5 , a control device 2 with a driving lever for the elevator is provided. By means of an operating mode selector switch 3 , the necessary procedural steps, such as reading in the upper and lower position, automatic operation or manual operation, can be carried out in connection with the device provided for recording, processing and storing measured values 4 . The motors 9 , shown with indicated control lines, are arranged on the motor-driven roller. A braking device 8 is also provided. The braking device 8 preferably consists of an eddy current brake, but can also contain further, in particular mechanical, brakes. Transducers 6 and 7 are arranged on the pulley 5 . With the transducers 6 and 7 , the rotation of the pulley 5 is registered. As shown, the sensors 6 and 7 can be arranged on a tap of the axis of the brake 8 . The device for recording, processing and registering the measured values 4 is connected to the device 10 for activating the braking device 8 .

To control the rope-driven hoist, consisting of the motor-driven rope pulley 5 , the tower pulley 14 , the mounting element 13 , shown here together with the movable pulley of the pulley, in connection with a measuring device for determining the weight load, which is usually attached to the rope pulley 5 , a measuring device for checking positions on the route as well as a measured value processing and control unit is provided. Surprisingly, it has been shown that the measuring devices 6 and 7 for the controlled approach to the desired positions 11 and 12 should be arranged directly on the motor-driven pulley 5 .

The measuring devices 6 and 7 for checking positions 11 and 12 on the travel path can advantageously be designed as a rev counter. Absolute encoders are preferably used as such. This is e.g. B. around potentiometers with which, for example, the measurement of up to 1024 revolutions is possible. The use of other absolute encoders, e.g. B. with coded disks is also possible. For safety reasons, an incremental value transmitter 7 is preferred in addition to the absolute value transmitter 6 . Measured signals from both sensors can be compared with each other for safety and if the measured values deviate, additional safety measures can be taken.

When the control according to the invention is in operation, the position of the holding element 13 is essentially registered. The weight is also measured. When the mounting element 13 is moved by means of the motor-driven pulley 5 , the braking device 8 is activated while maintaining the required braking distance when certain positions are reached. These specific positions are within the working range defined by positions 11 and 12 . They are automatically selected by the control as a function of the speed of the rope pulley so that the position 11 or 12 to be approached is reached at the respective speed after activation of the braking device. Positions 11 and 12 are first approached in manual mode. The associated measured values of the absolute encoder 6 are stored in the device 4 . Already when driving from one position to another, according to a preferred operating mode, the device 4 can automatically set two different rotational speeds of the motor-driven pulley 6 . The device 4 then activates the triggering of the braking device in this program by means of the device 10 for activating the brake 8 . For the two selected speeds of rotation, e.g. B. 150 and 250 RPM, the required braking distance is measured by registering the revolutions of the rope pulley 5 in the processing device 4 . The braking distance depends in a non-linear manner on the speed of rotation. This dependency is parabolic in particular, whereby the slope of the parabola can vary depending on the braking power. The brake tests determine the curve that is relevant for the current state of the system from the family of possible parabolas. Since the parabola shifts in the direction of the ordinate with increasing weight load, further brake tests can be carried out automatically with increasing weight load. This can take place, for example, at 20, 40, 60 and 80% of the permissible total load on the elevator. In addition, it can be provided that the braking distance, e.g. B. by aging of the brake to correct automatically.

The braking device 8 can be controlled via the activation device 10 by the measured value processing device 4 , in which these measured values are present, from the braking distance known from the measured value of the absolute value transmitter 6 at each rotational speed and the position of the holding element 13 also known from the measured value of the absolute value transmitter 6 . Since the braking distance is maintained here, the holding element 13 comes to a standstill at the desired positions 11 and 12 . In order to fix the holding element 13 at the positions 11 and 12 , additional braking devices, which can also be used as emergency brakes, can be provided.

The absolute encoder is installed so that the positions to be approached are always in its working area. When re-hanging the rope, e.g. B. if the rope has to be cut, or in the event of changes in reeving, e.g. B. from 5 to 10 turns on the block and tackle, positions 11 and 12 are moved to once and the new associated measured values of the absolute encoder are registered. The braking distance is then also automatically calibrated again.

Claims (7)

1. Device for controlling a rope-driven hoist with at least one motor-driven, brakable rope pulley and a holding element for loads connected to the rope, which travels through the rotation of the rope pulley, in particular periodically repeatable, whereby measuring devices for determining the weight load and for checking positions arranged on the route and a device for measuring value processing, processing and storage as well as control and braking devices, characterized in that the measuring device ( 6 , 7 ) for checking positions ( 11 , 12 ) is arranged on the motor-driven pulley ( 5 ) is. 2. Device according to claim 1, characterized in that the measuring device ( 6 , 7 ) for checking positions ( 11 , 12 ) on the travel path is designed to determine the revolutions of the motor-driven pulley. 3. Apparatus according to claim 2, characterized in that the measuring device for determining the revolutions of the motor-driven pulley is designed as an absolute encoder ( 6 ). 4. Device according to one of claims 1 to 3, characterized in that in addition to the absolute encoder ( 6 ) on the roller and an incremental encoder ( 7 ) is arranged. 5. Device according to one of claims 1 to 4, characterized in that the device ( 4 ) for recording measured values and control is arranged in a manner which can be acted on the braking device ( 8 ). 6. The device according to claim 5, characterized in that devices ( 10 ) for activating the braking device ( 8 ) by the device ( 4 ) for measuring value recording and processing and control are arranged. 7. Use of a device according to one of claims 1 to 6 for the control of a cable-driven hoist on a derrick ( 1 ), characterized in that with the measuring device ( 6 , 7 ) for checking positions on the route and with the device ( 4 ) to record and control the measured values, the measured values are registered, correspond to the desired, periodically accessible positions ( 11 , 12 ) of the mounting element and that for at least two rotational speeds of the motor-driven pulley ( 5 ) the braking distance by triggering the devices ( 10 ) for activating the braking device and Recording the measured values of the measuring device ( 6 , 7 ) for checking positions on the guideway is determined and stored, and the devices ( 10 ) for activating the braking device while maintaining the braking distance are triggered before reaching the desired positions ( 11 , 12 ) on the guideway.