SE532128C2 - Nut wrench with a power transmission gear and rotation sensing means, as well as method for determining gear status - Google Patents

Description

so 128 depending on the sequential gearing. This results in a non-linear torque growth in the screw joint during tightening.

It is thus a problem associated with nutrunners provided with torque transducers located "upstream" of the reduction gear in terms of the uncertainty in the instantaneous magnitude of the torque actually transmitted via the output shaft. This is mainly due to variiOnGI in the outgoing speed from the gear which are caused not only by the gear grips mentioned above but also by damaged components in the reduction gear.

Another source of torque sensing errors is some elastic torsional deformation of the transmission components and the output shaft which affects the angle of rotation as well as the recorded dynamics, service life and installed torque.

One way to ensure an acceptable accuracy of the torque delivered is to keep track of the status of the power transmission and to enable decisions when the gear is mechanically worn down to such a level that overhaul and repair of the tool is necessary. A worn gear causes a degraded output power h0S the tool, which means that the tool's output torque may no longer be what it was originally set for. This means that screw connections tightened with such a nutrunner may not be pre-tensioned to an acceptable level.

In the case of nutrunners with an electric motor driven and controlled by an electronic control unit, there are means for monitoring both the delivered torque and the rotation parameters of the motor. In electric motor arrangements of this type, however, neither the angular movement of the output shaft nor the effective reduction ratio is correctly determined, for mechanical wear or other defects of the gear affect the rotational movement transmitted from the motor to the output shaft. A further problem with electric nutrunners of the above-mentioned type relates to a certain elastic flexibility of the power transmission under torque load, which means that the output shaft goes out of phase with the electric motor so that the angular position of the screw connection does not correspond to the motor angular position. There is thus an angular displacement between the output shaft and the motor.

The main object of the invention is to create a nutrunner with a motor arranged to deliver torque to an output shaft via a gear and which comprises means for indicating the rotational movement of the output shaft in order thereby to reveal excessive wear or other damage to the gear causing unacceptable deviations of the delivered torque and also to detect the magnitude of the elastic resilience of the power transmission to thereby determine the angular displacement of the output shaft relative to the motor.

Further objects and advantages of the invention will become apparent from the following description and claims.

A preferred embodiment of the invention is described below in detail with reference to the accompanying drawing. 532 '228 List of drawings Fig. 1 shows a front part of a nutrunner according to the invention.

Fig. 2 shows on a larger scale a longitudinal section through the output shaft of the nutrunner in Fig. 1 and illustrates a rotation sensing member.

Fig. 3 shows a diagram illustrating the normal regular variation in the rotational movement of the output shaft of the bevel gear.

Fig. 4 shows a diagram illustrating the normal regular variation in the rotational movement of the output shaft of the bevel gear with a tooth wear superimposed thereon.

The front portion of the nutrunner shown in Fig. 1 comprises a housing 10 which is connectable to a rear section (not shown) of the nutrunner which contains a rotary motor and power supply means connected to the motor. This front housing portion 10 includes an angle head 11 with an output shaft 12 mounted in a front ball bearing 13 and a rear needle bearing 14. The output shaft 12 is formed with an end portion 15 for supporting a nut sleeve for connection to a screw connection for tightening. The front ball bearing 13 has one of its ball bearings formed directly on the output shaft 12, while the other bearing web is formed on an end closure 17 threaded into the front end of the angle head 11. The output shaft 12 is connected to the motor via an angular gear 18 and an intermediate shaft 19, the angular gear 18 comprising a pinion gear 20 on the intermediate shaft 19 and a crown wheel 21 on the output shaft 12.

The intermediate shaft 19 is mounted in a rear adjustable bearing 22 and a front needle bearing 23 and is provided at its rear end with a coupling sleeve 24 for connection to the motor. 532 128 In the angle head 11 there is arranged a rotation sensing device in the form of a sensor 26 of the Hall element type which is mounted in the angle head 11 and an actuator 27 arranged on the output shaft 12. The actuator 27 is advantageously formed as a thin plastic band 29 mounted around the crown wheel 21 and magnetized in transversely equidistantly placed bands. These magnetic bands are very narrow to achieve a high resolution and cause a pulsating activation of the sensor 26. The latter is connected to an electronic control and evaluation unit (not shown) located at the rear end of the nutrunner, the sensor 26 emitting electrical pulses thereto. unit corresponding to the magnetic bands 29 passing the sensor upon rotation of the output shaft 12.

As an alternative to magnetic tape and Hall element sensor for indicating the rotational movement of the output shaft 12, the output shaft 12 may also be provided with a circumferentially spaced row of teeth for activating an inductive sensor located in the angle head.

Other types of rotation sensing devices may alternatively be used.

During the operation of the nutrunner, the electronic control and evaluation unit monitors the instantaneous rotational movement which is based on the train of signal pulses from the rotation sensing sensor. Regular variations in the rotational movement are illustrated by the sinusoidal torque / angle curve (T / o) in Fig. 3. Far-reaching wear of the angular gear, which normally means impaired engagement between the gear teeth, is illustrated as superimposed irregularities on the sinusoidal curve. This is illustrated in Fig. 4. All types of irregularities in the rotational movement of the output shaft cause greater or lesser variations in the delivered torque, and by keeping an eye on these irregularities it is also possible to get a true picture of the torque actually delivered. to the screw connection during tightening. This is important because the torque sensors of most nutrunners are located upstream of the reduction / angle gear to avoid too clumsy angle heads, which means that the torque indicated with this type of torque sensor does not reveal any irregularities of the torque applied to the screw connection. By means of a nutrunner provided with a rotation sensing and indicating device according to the invention, it has been made possible to reveal irregularities in the delivered torque and thereby to ensure that the desired torque is actually applied to the tightened screw connection.

Claims (6)

532 138 Patent claims. A nutrunner comprising a housing (10, 11), a rotary motor, an output shaft (12) arranged to support a tool for engagement with a screw connection, and a power transmission gear (18) for connecting the motor to the output shaft (12) The output device (26, 27) is associated with the output shaft (12) for generating signals indicating the instantaneous rotational movement of the output shaft (12), an evaluation unit being connected to the rotation sensing device (26, 27) for determining of the status of the power transmission gear (18) by detecting and analyzing irregularities in the rotational movement of the output shaft (12). 2.. Nutrunner according to claim 1, characterized in that the rotation sensing device (26, 27) comprises an actuating means (27) arranged on the output shaft (12), and a stationary sensor (26) mounted in the housing (10, 11), wherein said activating means (27) is arranged to deliver equidistant pulses to said sensor (26) corresponding to the rotational movement of the output shaft (12), and that said sensor (26) is arranged to generate electrical signals corresponding to said pulses. 3.. Nutrunner according to claim 2, characterized in that the gear (18) comprises an angular gear with a crown wheel (21) arranged on the output shaft (12), the actuating means (27) being arranged on the crown wheel (21). A nutrunner according to any one of claims 1-3, characterized by an electric motor, and an electronic power supply and control unit comprising means connected to the motor and E33 128 arranged to determine the delivered torque and rotational movement of the motor, said evaluation unit being included in said power supply and control unit and is arranged to compare the rotational movement of the motor with the indicated rotational movement of the output shaft (12) for detecting the angular lag of the output shaft (12) relative to the motor as well as undesired irregularities in the rotational movement of the output shaft (12) . A method for determining the status of a power transmission gear (18) of a nutrunner having a rotary motor and wherein the gear (18) is arranged to connect the rotary motor to a rotary tool engaging tool via an output shaft (12), comprising the following step 0 indicating the instantaneous rotational movement of the output shaft (12), and analysis of the indicated instantaneous rotational movement of the output shaft (12) for detecting undesired irregularities in the rotational movement of the output shaft (12). Method according to claim 5, characterized in that the indication of the instantaneous rotational movement of the output shaft (12) is performed via pulse signals equidistantly generated upon rotation of the output shaft (12).