EP0203370A1 - Screwing device with motor-driven screw driver - Google Patents

Abstract

1. Screwing device with motor-driven screw-driver (5), and with a torque measuring means (2) and an evaluation means (15) for torque limitation, characterized in that the screwdriver (5) is axially displaceable with respect to a nonaxially displaceable motor shaft (1) and the housing of the screwing device by a predetermined displacement length (a), in that a distance measuring means (11) monitors the axial displacement of the screwdriver (5) and in that, on reaching the predetermined displacement length (a), the motor speed is reduced and the torque occurring monitored.

Description

State of the art

The invention relates to a screw device with a motor-driven screwdriver according to the preamble of the main claim. Screwing devices of this type are used as screwing machines, for example for screwing in a large number of identical screws. On the one hand, the screws should be screwed in quickly on the respective workpiece, but a predetermined maximum torque should not be exceeded when the screws are tightened. For this reason, the screwing device has a torque measuring device for monitoring the maximum torque. The screw is first screwed in at a high speed in order to then be tightened to the predetermined maximum final torque when the speed is reduced. The switch to lower speed is initiated in known screw devices when a certain torque threshold is reached when tightening the screw. In practice, however, the maximum permissible final torque is often exceeded in these known screwing devices, since, for example at high speeds, the required rapid speed reduction is not possible due to the inertia. Will be great for the workpiece and the screw hard materials are used, this results in a very steep increase in torque as soon as the screw head touches the surface of the workpiece. In these cases, too, reliable torque limitation, in particular at high screwing speeds, cannot be guaranteed in the known screwing devices with exclusive torque monitoring.

Advantages of the invention

The screwing device according to the invention with the features of the main claim has the advantage that the speed of the motor-driven screwdriver can be reduced in time by an additional displacement measuring device to such an extent that the then effective torque measuring device ensures reliable torque monitoring and an exact tightening of the screws predetermined final torque enables. For this purpose, the displacement measuring device monitors the axial displacement of the screwdriver, which preferably has a spline shaft, which engages axially displaceably in corresponding grooves on the drive spindle of the screwing device. If the displacement measuring device detects a predetermined axial displacement, the speed of the drive motor, which can be an electric or compressed air motor, is reduced and the torque measuring device is activated at the same time.

In a particularly advantageous manner, it is further provided that a common evaluation device is used for the monitoring and evaluation of the axial displacement of the screwdriver and the torque, the input of which can be optionally connected to the displacement measuring device or the torque measuring device via a changeover switch. At the beginning of the screwing process is only that Displacement measuring device connected to the evaluation device, since torque monitoring is initially not required. Only when the screw head is at a predetermined, adjustable distance from the workpiece surface is this determined by the displacement measuring device, whereupon the evaluation device causes a switchover to the torque measuring device with simultaneous speed reduction. So that such a switchover between torque measuring device and displacement measuring device is possible without any problems, sensors of the same type, for example measuring coils, capacitive or optical sensors, are used in these measuring devices. The torque measuring device can be designed in a manner known per se, as described in DE-OS 29 51 148. The displacement measuring device preferably has an annular coil which surrounds the spline shaft and which, for example, monitors the position of an annular groove provided on the spline shaft.

The preferred embodiment provides that the displacement measurement and the torque measurement are carried out using the eddy current measurement method.

drawing

• Fig. 1 eine Teilansicht einer Schraubvorrichtung im Bereich der Antriebsspindel,
• Fig. 2 ein stark vereinfachtes Blockschaltbild der elektrischen Schaltung zur Begrenzung des Enddrehmoments,
• Fig. 3 ein detaillierteres Schaltbild der in Fig. 2 enthaltenen Auswerteeinrichtung und der mit ihr eingangsseitig verbundenen Einrichtungen und
• Fig. 4 ein Flußdiagramm zur Veranschaulichung der Funktionsweise der Schraubvorrichtung.

The invention is explained below with reference to the drawing. Show it:

• 1 is a partial view of a screwing device in the area of the drive spindle,
• 2 is a highly simplified block diagram of the electrical circuit for limiting the final torque,
• FIG. 3 shows a more detailed circuit diagram of the evaluation device contained in FIG. 2 and the devices and connected to it on the input side
• Fig. 4 is a flow chart to illustrate the operation of the screw device.

1 shows the lower part of the motor shaft 1 of a screwing device which is connected to a drive spindle 3 via a torque measuring device 2. At the lower end of the drive spindle 3, a spline shaft 4 engages in it, which forms the shaft of an axially displaceable screwdriver 5. At the lower end of the screwdriver 5 there is a screw attachment 6 into which the screw head 7 of a screw 9 to be screwed into a workpiece 8 engages from below. For this purpose, a threaded bore 10 is provided on the workpiece 8, which is indicated here by broken lines.

At the lower end of the drive spindle 3 there is a displacement measuring device 11 which is rigidly connected to the drive spindle 3. The displacement measuring device 11 has a ring coil 12 as a sensor element, which surrounds the spline shaft 4 in a ring shape. If the spline shaft 4 moves downward in the direction of arrow a during the screwing process, then an annular groove 13 attached to the spline shaft 4 enters the area of the toroidal coil 12. This causes a change in the inductance of the toroidal coil 12, causing a corresponding electrical signal to be removed -Measuring device 11 is delivered to an evaluation device. The evaluation device is described in more detail with reference to FIG. 3.

The drive spindle 3 has an opening 14 adapted to the profile of the spline shaft 4 for receiving the spline shaft 4, which can also be designed as a bushing provided with longitudinal grooves.

The function of the screwing device is explained with reference to FIG. 2, which shows the highly simplified block diagram of the electrical circuit. At the start of the screwing process, an evaluation device 15 is supplied with a start signal from the outside, which then switches on the motor M driving the motor shaft 1. For this purpose, the evaluation device 15 is connected to a motor controller 16 that controls the speed of the motor M. The engine M initially runs at high speed.

Via a changeover switch 17, the switching position of which is controlled by the evaluation device 15, the displacement measuring device 11 is first connected to the input of the evaluation device 15. As soon as the distance measuring device 11 reports a predetermined distance between the screw head 7 and the surface of the workpiece 8 to the evaluation device 15, this switches the changeover switch 17 into the other position (not shown here) and thus connects the torque measuring device 2 to the input of the evaluation device 15. At the same time, the evaluation device 15 causes a reduction in the engine speed via the engine control 16.

The screwing process is now continued with a possibly greatly reduced engine speed, with the torque being monitored continuously via the torque measuring device 2. If the torque rises when the screw head 7 is in contact with the workpiece 8, the screwing operation is switched off as soon as a previously set final torque or a maximum torque is determined by the torque measuring device 2 and transmitted to the evaluation device 15. The evaluation device 15 then switches off the motor M via the motor controller 16 and can subsequently switch the switch 17 into the position shown here.

To determine the distance between the screw head 7 and the workpiece 8 provided for the switch 17, it is sufficient if the drive spindle 3 is brought into a corresponding vertical position that the annular groove 13 comes into the region of the annular coil 12 and at just the desired distance a corresponding electrical signal characterizing this state is transmitted to the displacement measuring device 11 to the evaluation device 15. A distance between the screw head 7 and the workpiece 8 corresponding to the respective requirements can thus be determined in a simple manner, at which a speed reduction is carried out during the screwing process. At very high speeds at the beginning of the screwing process, a correspondingly larger distance can be provided for the speed changeover than at low initial speeds. The distance that is decisive for the speed reduction must in any case be selected such that, taking into account the inertia of the rotating masses, such a speed reduction can be carried out that an exceeding of a predetermined torque when tightening the screw 9 is reliably avoided.

In Fig. 3 in particular the evaluation circuit 15 is shown in more detail. It contains an oscillator G which supplies a high-frequency AC voltage (for example 20 kHz to 10 MHz). The first output terminal of the oscillator G is connected to the one end of a measuring coil 18 via a first resistor R1 and to the output terminal of the changeover switch 17 via a second resistor R2. The second output terminal of the oscillator G is connected to a tap of the measuring coil 18 and via two capacitors C1, C2 to R1 and R2. One of the one Terminal of the switch 17 is connected to the other end of the measuring coil 18 and the other input terminal to one end of the ring coil 12. The other end of the ring coil 12 is connected to the tap of the measuring coil 18. The upper part of the measuring coil 18 shown in the drawing serves as a compensation coil 28 in order to eliminate the influence of any temperature fluctuations that may occur on the measurement result and also to enable a common zero point setting for the displacement and torque measurement. The lower part of the measuring coil 18 serves as an inductive sensor for torque measurement. Via the switch 17, the lower part of the measuring coil 18 or the ring coil 12 can be connected to the oscillator G via R2.

The measuring coil 18 and the ring coil 12 are arranged in a bridge circuit which has the corner points F, K and M. The corner point F of the bridge circuit is connected via the series connection of a capacitor C3 and a rectifier D1 to a storage capacitor C4, to which a discharge resistor R3 is connected in connection point D, which is also connected to the corner point M of the bridge circuit like capacitor C4 and another rectifier D2 connected.

In a mirror-image manner, the corner point K is connected via a series connection of a capacitor C5 and a rectifier D3 to a storage capacitor C5, to which a discharge resistor R4 is connected at the connection point E, which, like the capacitor C5 and a rectifier D4, is connected to the corner point M of the bridge circuit connected.

To suppress harmonics, there are two RC elements consisting of resistors R5, R6 and Capacitors C6 and C7 are provided. The practically harmonic-free DC voltage which arises at the series connection of the transverse capacitors C6, C7 can be changed with the aid of the compensation coil 28 and the resistors R1, R2, which can be designed as adjustable resistors, for adjustment purposes.

For further processing of this DC voltage, a differential amplifier 19 is provided which is connected to this DC voltage with its two inputs. The first input of the differential amplifier 19 connected to the series resistor R5 is simultaneously connected to the output of the differential amplifier via a resistor R7, while the second input of the differential amplifier 19 connected to the series resistor R6 is connected to ground via a resistor R8.

At the output of the differential amplifier 19 there is a signal which is applied on the one hand as an input signal A to a first input of a switching mechanism 20, and on the other hand serves as a status signal C for controlling the motor M, while a signal B is present at a second input of the switching mechanism 20 Provides information about the state of the screwdriver.

A control signal for actuating the changeover switch 17 is formed in the switching mechanism 20 by logically combining the signal A supplied by the differential amplifier 19 and the signal B describing the state of the screwdriver.

When the screwdriver 5 is in its initial position and either stands still or starts up, the signal B = 1 is present at the second input of the switching mechanism 20 and the switch 17 is in the switch position shown, so that the toroidal coil 12 is connected to the evaluation device 15. At the same time, signal A occurring at the output of differential amplifier 19 is queried by switching mechanism 20. When the screwing process begins, it is initially at "zero". However, if the screwing process has progressed so far that the ring groove 13 enters the area of the ring coil 12, then the signal at the output of the differential amplifier 19 becomes A = 1.

This signal acts as a status signal C for the control of the motor M and causes the motor M to be switched to a lower speed. The change in the signal A from A = 0 to A = 1 has the effect in the switching mechanism 20 that it issues a switch command to the switch 17. The switch 17 goes into the other position, not shown, so that the measuring coil 18 is effective.

After the screwing process has ended, the motor M is switched off, so that the signal B = 0 occurs at the second input of the switching mechanism 20. Simultaneously or at the latest when the screwdriver 5 is lifted off the screw head 7, the spindle torque falls back to zero and the signal A given by the output of the differential amplifier 19 to the first input of the switching mechanism 20 again becomes A = 0. However, the switch 17 receives a switch command from the switch mechanism 20 to switch to the switch position shown when the signal present at the second input of the switch mechanism 20 becomes B = 1 again. This is the case when the screwdriver 5 is brought into the starting position for the next screwing operation.

Using the flow chart shown in Figure 4 the process of the displacement torque measurement is now specified.

After the start, the speed n initially increases. This initial state is indicated to the switching mechanism 20 by a signal B = 1. The switch 17 (Figure 3) is in the position shown, so that the distance measurement can follow. During this section of the screwing process, it is constantly checked whether a predetermined displacement or a travel threshold is reached. When the travel threshold is reached, A = 1 and the speed n is reduced. Then there is a switchover to the torque measurement and A becomes "0" again. In this section of the screwing process, a constant torque measurement is carried out, which is then monitored to determine whether a predefined torque threshold is reached. When the torque threshold is reached, A = 1 and the screwing process is ended by the drive motor being switched off and the screwdriver being raised to its starting position. B = 0 and A = 0 are set. The next screwing process can be initiated by a new start signal.

Claims (9)

1. Screwing device with a motor-driven screwdriver and with a torque measuring device and an evaluation device for torque limitation, characterized in that the screwdriver (5) is axially displaceable, that a displacement measuring device (11) monitors the axial displacement, and that when a predetermined one is reached Displacement length the engine speed is reduced. 2. Apparatus according to claim 1, characterized in that the input of the evaluation device (15) can be connected either via a changeover switch (17) to the displacement measuring device (11) or the torque measuring device (2), that initially only during the screwing process the displacement measuring device (11) is connected to the evaluation device (15), and that when a predetermined displacement length is reached, the evaluation device (15) reduces the engine speed and causes the changeover switch (17) to switch over. 3. Device according to one of claims 1 or 2, characterized in that both the displacement measuring device (11) and the torque measuring device (2) have identical sensors. 4. The device according to claim 3, characterized in that the sensors are measuring coils (12, 18). 5. Device according to one of the preceding claims, characterized in that the screwdriver (5) counter-. is axially displaceable over the housing or the motor shaft (1) of the screwing device. 6. The device according to claim 5, characterized in that the screwdriver (5) has a spline shaft (4) which engages in a correspondingly profiled opening (14) of a drive spindle (3) via a torque measuring device (2) with the Motor shaft (1) is connected. 7. Device according to one of the preceding claims, characterized in that the screwdriver (5) has a marking, the axial displacement of which is monitored by a sensor connected to the displacement measuring device (11). 8. The device according to claim 7, characterized in that an annular groove (13) is provided as a mark, and that the sensor of the displacement measuring device (11) is an annular coil (12). 9. Device according to one of the preceding claims, characterized in that the displacement measurement and the torque measurement are carried out according to the eddy current measuring method.

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