JPH0351733Y2 - - Google Patents

Description

[Detailed Description of the Invention] "Field of Industrial Use" This invention relates to an impact wrench deterioration detection device that can easily and reliably determine the deterioration of an impact wrench.

``Prior Art'' When fastening a workpiece using a bolt with an impact wrench, the tightening torque is proportional to the impact force of the hammer multiplied by the number of hits of the hammer due to the structure of the impact wrench. For this reason, conventional impact wrench torque checkers use a transducer to convert the hammer striking force at a certain moment when an impact occurs fragmentarily into a voltage, and display this value as a substitute torque.

``Problems that the invention attempts to solve'' The conventional impact wrench torque checker described above does not know the number of hammer strikes per unit time of the impact wrench, and it only captures the hammer striking force of the impact wrench at a certain moment. Because of this, there was a problem that the variation in hammering could not be seen.

This idea was made in view of this point, and it is a deterioration detection method for impact wrenches that allows you to know the number of hammer strikes per unit time of an impact wrench, and also allows you to see variations in the hammering of an impact wrench. The purpose is to provide a device.

"Means for Solving the Problems" The means constructed by this invention to solve the above problems is to replace the impact wrench deterioration detection device with a transducer that converts the impact force generated by the rotation of the impact wrench into an electrical signal. , an amplifier that amplifies the output signal of this transducer, an analyzer that converts the time-voltage signal that is the output signal of this amplifier into a frequency-gain signal, and displays the output signal of this analyzer. This means that it is equipped with the following.

"Operation" With such a configuration, the state of deterioration of the impact wrench can be easily and reliably determined by examining the waveform characteristics of the signal output as a frequency-gain signal.

``Embodiment'' Next, an embodiment of this invention will be described with reference to FIG. 1. Reference numeral 1 is an impact wrench, which rotates a chuck 3 by impact with compressed air received from a hose 2. A transducer 4 receives the impact force generated on the chuck 3 at a receiving portion 5 and converts it into an electrical signal.
6 is an amplifier that amplifies the output signal of the transducer 4, and 7 is an analyzer that converts the time-voltage signal, which is the output signal of the amplifier 6, into a frequency-gain signal, and is used to examine frequency components. This is to see the number of hammer strikes per unit time and the variation in striking force. It also has a signal waveform comparison/judgment function (spectrum comparator), so if you input the normal hammer strike signal waveform in advance, you can compare this with the waveform obtained from the impact wrench you just tested. Compare and judge whether it is within the allowable range or not. 8 is a relay box that outputs OK or NG, and 9 is a plotter that displays the output signal from the analyzer 7.

This device configured in this manner is tested by applying the chuck 3 of the impact wrench 1 to the receiving portion 5 of the transducer 4 and applying impact force thereto. Figure 2 shows a comparison between a new impact wrench and a used one, with a sampling time of 0.4
Seconds. As shown in this figure, it can be seen that the new product has a larger swing width than the used product and has sufficient impact force (impact force). FIG. 3 shows the hammer strike signal of FIG. 2 converted into a frequency-gain signal by the analyzer 7, and shows that the first-order component of the frequency indicating the number of hammer strikes is 18 Hz for a new model. In other words, it can be seen that the number of strikes occurs 18 times per second, and 20 hertz for the used product, or 20 times per second.

Looking at this frequency waveform, the new one shows 18
There is a peak near Hertz, and no other components appear around this area, so hammering is done regularly, whereas the waveform of a used product is not as sharp as a new one, and also has a peak around 30 Hertz. , Since there is another peak, it is assumed that there are variations in the hammering of the impact wrench. As mentioned above, the analyzer 7 has a comparison/judgment function, so these data are compared with the data input in advance, and the resulting signal (OK or NG signal) is sent to the relay box 8 and the block 9. will be given to

"Effects of the invention" As explained above, this invention uses the analyzer 7 to convert the impact force of the impact wrench 1 into frequency components for observation.
By analyzing the frequency components, variations in hammering can be determined.

Therefore, the degree of deterioration of the impact wrench 1 can be reliably known by making a judgment together with the data on the number of blows per time that can be seen from the signal before being converted into frequency components.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment of this invention, and FIGS. 2 and 3 are graphs of actual measurement data using the device shown in FIG. 1...impact wrench, 4...transducer, 6...amplifier, 7...analyzer, 9...protruder.

Claims (1)

[Scope of utility model registration request] a transducer that converts the impact force caused by rotation of the impact wrench into an electrical signal; an amplifier that amplifies the output signal of the transducer; and a time-voltage signal that is the output signal of the amplifier. 1. A deterioration detection device for an impact wrench, comprising: a decompressor that converts into a gain signal; and a plotter that displays the output signal of the decompressor.