EP0284974A1 - Power screw driver with torque limitation - Google Patents

Abstract

The invention relates to a power wrench with torque limitation with a drive unit and a downstream transmission with an output shaft for attaching a key nut. According to the invention, the drive unit is an air motor (2) with a compressed air supply (13) and a compressed air outlet (14), the differential pressure between the compressed air supply (13) and compressed air outlet (14) (measuring lines 19 and 20) is used. The differential pressure is measured in a differential pressure meter (21) and the measurement signal is fed to a control unit (23). The control unit (23) contains a comparison unit which compares the measured differential pressure signal with a differential pressure setpoint (setting potentiometer 24) and, in the case of equality, outputs a switching signal to a switching unit (solenoid valve 18) for switching off the power wrench. As a result, simple torque detection is achieved by measuring the differential pressure in conjunction with a simple switch-off option. In further embodiments, the speed of the air motor is additionally used as an influencing variable for determining the torque.

Description

The invention relates to a power wrench with torque limitation according to the preamble of claim 1.

Screw connections, especially heavy screw connections, often have to be tightened to a specified torque. For this purpose, a number of devices, so-called power wrenches, are known.

A known power wrench (EP-OS 0 042 558) uses a separate, deformable component for torque determination, which coaxially surrounds the output shaft of the power wrench. This torsionally flexible connecting piece is increasingly twisted during the screwing process with increasing screwing torque and actuates an elastic switch when a certain deformation amplitude has been reached. The drive device is then switched off with the aid of this switch. Given the very small torsion paths, it can be expected that mechanical switch actuation will only act inaccurately and therefore the torque determination will be inaccurate. An additional component is also required, which increases both the weight and the cost of the power wrench. This also applies to the further embodiment mentioned in the same document, in which Deh on the torsionally elastic connecting piece voltage measuring strips are applied, which lead to the known effort and problems with strain gauge measurements.

In contrast, the object of the invention is to develop a generic power wrench with torque limitation and air motor drive so that the disadvantages of the prior art do not occur.

This object is achieved with the features of claim 1.

According to claim 1, an air motor with a compressed air supply and a compressed air outlet is used as the drive unit. It has been shown that the pressure difference between the compressed air supply and the compressed air outlet can be used advantageously as a measure of the torque delivered by the power wrench. For a torque determination, the pressure increase in the pneumatic system or the compressed air supply with increasing torque is therefore not used, but the pressure difference applied to the air motor. As a result, marginal influences that could influence the torque determination, such as different operating temperatures, different or fluctuating pressures in the supply air supply, etc., can be largely eliminated, so that a simple and relatively accurate torque determination from the pressure difference is possible.

For the differential pressure measurement, the known differential pressure meters, such as membrane boxes, piezoelectric sensors, inductive sensors, etc. can be used.

Such a differential pressure meter is connected to a comparator unit on which a differential pressure setpoint is specified and which has a switching output which switches to the set differential pressure setpoint when the measured pressure difference rises. This switching output is connected to a switching unit that switches off the power wrench when the differential pressure setpoint is reached.

The specific torque values assigned to differential pressure values are expediently determined by experiment for a specific power wrench design and a corresponding characteristic curve is stored in the comparator unit. Basically, higher differential pressure values correspond to higher torque values.

The operation of such a power wrench is very easy, since the power wrench runs after switching on until the specified setpoint torque corresponding to a set differential pressure value is reached and switches off there automatically.

For measuring the differential pressure, it is expedient according to claim 2 to lead air lines from the compressed air supply line and the compressed air outlet line to the differential pressure meter. The most appropriate branch point for the measuring lines depends on the type and geometry of the respective air motor and can, for example, also be in the corresponding working area areas of the motor. The most suitable branch locations for the measuring lines are to be determined experimentally.

In order to be able to automatically switch off the power wrench at different torque setpoints, it is proposed with claim 3 to make the respectively assigned differential pressure setpoint adjustable by hand, the setting scale being calibrated in torque values.

A particularly advantageous embodiment results from further electrical processing of the differential pressure value in a differential pressure transducer, which converts the differential pressure signal into an electrical signal. However, a mechanical design is also possible in which the differential pressure meter is connected to a downstream mechanical comparison and switching unit.

A simple and inexpensive design results, however, according to claim 5, when the comparator unit carries out an electrical comparison and the setpoint as electri signal can be specified by a potentiometer.

The relationship between the measured differential pressure and the torque delivered by the power wrench depends on the type and geometry of the air motor and will generally not be linear. Such non-linearities can be taken into account, for example, using a corresponding non-linear scale on the setpoint adjuster. According to claim 6, however, it is advantageous to provide the setpoint adjuster with a linear scale and to compensate for non-linearities via a linearizing unit. The linearizing unit can, for example, be attached as an electrical unit in the electrical transmitter or electrical comparator or, in the case of a mechanical embodiment, can be implemented, for example, by a cam disk.

To switch off the power wrench when the predetermined setpoint torque is reached, a switching valve is advantageously used according to claim 7, which switches off the compressed air supply. In an electrical version of the comparator unit, a solenoid valve is expediently used for this, and in a mechanical version, a correspondingly working, mechanically controllable valve.

For switching on (and switching off) by hand, a conventionally known, manually controllable switching valve is provided in the compressed air supply line anyway. For the automatic switch-off, either a second valve can be provided for this or the manual switch valve can also be used. For this purpose, a known electrical or mechanical priority circuit for the automatic switch-off over the manual switch must be provided for this valve.

According to claim 8, it is proposed to use a solenoid valve which has bistable positions for the open and closed positions which can be controlled electrically by switching pulses. This ensures that only little energy has to be applied for reversing the solenoid valve. Correspond The accumulator required for this can be designed to be small enough so that it can still be accommodated in the machine housing for long-term work. In addition, it is achieved that the power wrench can also be used in explosion-protected areas because of the small accumulator, since this can be cast, for example, in the machine electronics.

A particularly preferred embodiment results according to claim 9 in that, in addition to the determined differential pressure, the speed of the air motor is also used to determine the torque output by the power wrench. This results in a further influencing variable which increases the accuracy of the shutdown. The direct influence of the speed can vary depending on the air motor used and the geometric conditions. To take the speed into account, the determined speed signal and the differential pressure signal are supplied to the switching unit. In the switching unit, empirically and experimentally determined characteristic and reference variables or characteristic and reference fields are stored in corresponding memories, from which the associated torque is determined for a specific speed signal and differential pressure signal and is compared with the setpoint torque set.

In a simpler embodiment, it is sufficient to supply the differential pressure signal and the speed signal to a combination circuit, and to use this linked signal in the switching unit for a setpoint / actual value comparison or an assignment to stored characteristic diagrams.

It has been shown that a precise determination of the torque is obtained in concrete versions if, according to claim 10, the product of the differential pressure signal and the period is optionally used with a further constant than the changing signal under load for a shutdown.

The arrangement is particularly compact, simple and also inexpensive in that, according to claim 11, the differential pressure transducer which is required anyway is also used to determine the speed. The amplitude of the differential pressure signal fluctuates in the rhythm of the lamellae of the air motor passing the sensor openings. The frequency of the differential pressure signal divided by the number of fins is therefore a measure of the speed of the air motor or of its period. A speed signal can be obtained in the usual way simply by generating pulses when the signal passes through a trigger threshold (e.g. on every negative edge), which are counted into a counter with a gate circuit and a timer.

According to claim 12, all electrical parts are contained in the machine and potted there. No external control and regulating units are therefore necessary and all influences influencing the torque determination are taken into account in the machine itself. The machine can also be used in explosion-proof areas, since no external electrical supply is necessary.

Using an exemplary embodiment, the invention is explained in more detail with further details, features and advantages.

• Fig. 1 eine schematische Darstellung einer Längsansicht eines Kraftschraubers,
• Fig. 2 eine schematische Ansicht eines Querschnitts durch einen Luftmotor des Kraftschraubers nach Fig. 1 mit den Elementen für eine Drehmomentbegrenzung,
• Fig. 3 eine schematische Ansicht entsprechend Fig. 2, bei der zusätzlich ein Drehzahlsignal für die Drehmomentbegren­zung erfaßt ist,
• Fig. 4 eine schematische Darstellung gemäß Fig. 3, bei der die Drehzahlermittlung über das Differenzdrucksignal erfolgt,
• Fig. 5 eine schematische Darstellung des Amplitudenverlaufs des Differenzdrucksignals.

Show it

• 1 is a schematic representation of a longitudinal view of a power wrench,
• 2 shows a schematic view of a cross section through an air motor of the power wrench according to FIG. 1 with the elements for torque limitation,
• 3 is a schematic view corresponding to FIG. 2, in which a speed signal for torque limitation is additionally detected,
• 4 shows a schematic illustration according to FIG. 3, in which the speed is determined via the differential pressure signal,
• Fig. 5 is a schematic representation of the amplitude profile of the differential pressure signal.

1 shows a power wrench 1 with an air motor as the drive unit, a downstream transmission 3, a support leg 4, a screw head 5, a handle 6, a control part 7 and a compressed air connection 8.

2 shows a cross section through the compressed air motor 2, from which a rotor 9 with slats 10 which can be displaced in slots can be seen, the slats 10 being supported on an eccentrically offset running surface 11. This creates working chambers 12 of variable volume which can be pressurized with compressed air via a compressed air inlet opening 13. The compressed air emerges again after a rotor rotation at the compressed air outlet opening 14.

The compressed air supply takes place via a line 15 or via the compressed air connection 8. In line 15 there is a shut-off valve 17 which can be actuated via a hand switch 16 and, in series (in front of or behind the shut-off valve 17), a solenoid valve 18 with which line 15 can also be shut off is.

The pressure difference between the pressure of the air supply and the pressure of the air outlet is tapped via two measuring lines 19 and 20 branching off at the corresponding points and measured via a differential pressure transducer 21.

The transducer 21 converts the differential pressure signal into a corresponding electrical direct voltage signal which is fed to the unit 23 via the line 22. In this unit 23 there is a comparator unit for comparing the externally adjustable target value (potentiometer 24 in FIG. 1; target value arrow 25 in FIG. 2) with the differential pressure signal (Lei tion 22) included. A linearization unit is also included, which is indicated schematically as curve 26. A flip-flop circuit is also included, which switches if the set differential pressure setpoint or torque setpoint is equal to the measured differential pressure that increases during the screwing process. This switching signal is supplied to the magnet of the solenoid valve 18 via the electrical line 27, as a result of which the solenoid valve 18 is switched into its blocking position.

The power wrench 1 shown has the following function: To tighten (or loosen) the power wrench 1 with its screw head 5 is placed on the screw connection and the support leg 4 is brought into contact with a fixed counter bearing.

There is no differential pressure between the compressed air inlet 13 or between the lines 15, 20 and the compressed air outlet 14 or the line 19, since the compressed air to the air motor 2 is blocked via the manually operated shut-off valve 17. Therefore, the solenoid valve is switched to passage via the transmitter 21 and the downstream electronics.

When the shut-off valve 17 is opened with the aid of the hand switch 16, compressed air enters the air motor 2 via the line 15, as a result of which it runs at a high rotational speed and tightens the screw connection via the downstream transmission 3. The more the screw connection is tightened, the greater the counterforce on the rotor 9 of the air motor 2. As a result, the rotor 9 or the fins 10 oppose the compressed air present with greater resistance, as a result of which the pressure difference between the compressed air entering the motor and the compressed air outlet from the Motor rises and is therefore a measure of the torque delivered by the power wrench 1.

Before the start of the screwing process, the desired tightening torque was specified on the potentiometer 24 as the switch-off setpoint. If the measured pressure difference or the corresponding electrical signal has reached the setpoint, this will be Solenoid valve 18, for example by a switching pulse, switched to its blocking position. As a result, the air supply as drive energy is interrupted and the air motor 2 stops without any significant overrun, whereby the power wrench 1 is switched off (regardless of the position of the valve 17). After the automatic shutdown, the shut-off valve 17 is then manually moved into its locked position by the operator and the screwdriver is removed.

The embodiment shown with an automatic shutdown of the energy supply is a preferred exemplary embodiment. However, it can be seen that other shutdowns can also be carried out using the same principle, for example by switching a clutch in the transmission.

3 also shows a speed sensor 30, the speed signal of which is fed via line 31 to unit 23 in addition to the differential pressure signal (line 22). On the basis of the measured variables for the differential pressure and the rotational speed, the output torque is determined in the unit 23 from parameters or characteristic fields stored there and compared with the set torque setpoint 25.

In the embodiment shown in broken lines, the speed signal is not fed directly to the unit 23, but to a logic circuit 32, as is the differential pressure signal (line 33). The linked signal determined in the combination circuit 32 is then supplied to the unit 23 for a comparison. Since the differential pressure signal fluctuates in amplitude (see FIG. 5), it is expedient to pass this signal over a smoothing unit 34 and thus to determine an average differential pressure.

In Fig. 4, the speed is instead of a conventional, inductive, capacitive or working on light pulses speed sensor directly on the amplitude fluctuations of the Differential pressure signal determined. 5 shows the amplitude profile of the differential pressure signal.

The differential pressure signal is fed to a unit 35 which essentially contains a trigger circuit, a gate circuit with a timer and a counter. Each time the negative edge of the differential pressure signal (points 36) passes, a pulse is generated which is counted into a counter controlled by a timer, the count being a measure of the speed of the air motor. In the embodiment shown here, the speed variable and an averaged differential pressure value are fed to the logic circuit 32, which performs a multiplication of these variables and makes the determined product available as a variable variable for a shutdown.

In summary, it is found that the invention enables simple, accurate and effective torque limitation in a pneumatically operated power wrench.

Claims (12)

1. power wrench with torque limitation with a drive unit and a downstream transmission with an output shaft for attaching a key nut,
characterized,
that the drive unit is an air motor (2) with a compressed air supply (8, 15, 13) and a compressed air outlet (14),
that a differential pressure meter (21) is provided for measuring the pressure difference between compressed air supply (15, 13) and compressed air outlet (14), the pressure difference being used as a measure of the torque delivered by the power wrench (1),
that the measured pressure difference as an actual value is compared with a predetermined pressure difference as a differential pressure setpoint or torque setpoint (24, 25) by a comparator unit with a switching output and
that when the differential pressure setpoint is reached, the power wrench (1) is shuttered by a switching unit (23, 18) is tested. 2. Power wrench according to claim 1, characterized in that from the compressed air supply line (15) or compressed air outlet line and / or from the corresponding work area areas (13, 14) of the air motor (2) air lines (19, 20) to the differential pressure meter (21) . 3. Power wrench according to claim 1 or 2, characterized in that the switch-off pressure difference is adjustable as a differential pressure setpoint (24, 25), the setting scale being calibrated in assigned torque values. 4. Power wrench according to one of claims 1 to 3, characterized in that the differential pressure meter is a transmitter (21) which converts the differential pressure signal into an electrical signal (line 22). 5. Power wrench according to claim 4, characterized in that the comparator unit (23) carries out an electrical comparison and the setpoint as an electrical signal (potentiometer 24) can be predetermined. 6. Power screwdriver according to one of claims 1 to 5, characterized in that a linearizing unit is provided between the differential pressure meter (21) and the switching unit (18). 7. Power screwdriver according to one of claims 1 to 6, characterized in that the switching unit is a switching valve connected to the comparator unit, in particular a solenoid valve (18) in the compressed air supply line (15). 8. Power screwdriver according to claim 7, characterized in that the solenoid valve (18) each has an electrically controllable by switching pulses, bistable position for the open and closed position. 9. Power wrench according to one of claims 1 to 8, characterized in that for determining the torque delivered by the power wrench, the speed of the air motor is further determined and a corresponding speed signal and the differential pressure signal are optionally supplied via a logic circuit (32) to the switching unit (23) . 10. Power wrench according to claim 9, characterized in that the combination circuit (32) performs a multiplication of the differential pressure signal and the period corresponding to one revolution of the air motor and this product is used in the switching unit for a shutdown. 11. Power wrench according to claim 9 or 10, characterized in that for determining the speed of the air motor or the period of the differential pressure transmitter (21) or the amplitude of the differential pressure signal which changes periodically in accordance with the speed is used, when passing through a trigger threshold Pulses are generated, which are counted into a counter with a gate circuit and a timer and the count value is in each case a measure of the present speed. 12. Power screwdriver according to one of claims 1 to 11, characterized in that all electrical parts are contained in the housing of the power screwdriver and are potted there, so that no external control and regulating units are necessary and all influences influencing the torque finding in the power screwdriver itself are taken into account and the power wrench can be used in explosion-proof areas.

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