WO2015086576A1 - Operating hours meter having a magnetic sensor - Google Patents

Abstract

The invention relates to a measuring device for recording the running time of a machine tool having an electric motor, said measuring device containing: at least one sensor by means of which a magnetic field generated in the machine tool can be detected and a signal value can be generated when the magnetic field is detected; a counter having a running time counting mechanism; and at least one comparator circuit, which is designed to compare the signal value generated by the sensor with a previously defined reference value and, if the signal value is greater than the reference value, to start the running time counting mechanism of the counter and, if the signal value is less than the reference value, to stop the running time counting mechanism. The invention further relates to a method for recording the running time of a machine tool, comprising the steps: detection of a magnetic field generated by the electric motor; generation of a signal value corresponding to the detection of the magnetic field; comparison of the signal value with a previously defined reference value; starting of a running time counting mechanism of a counter if the signal value is greater than the reference value; and stopping of the running time counting mechanism of the counter if the signal value is less than the reference value. Fig.

Description

 "Operating hours counter with magnetic field sensor"

The present invention relates to a measuring device for detecting the running time of a machine tool with an electric motor, and to a method for detecting a running time of a machine tool.

As is well known, almost all available machine tools are subject to commonly occurring wear due to intensive and prolonged use.

 In order to avoid wear-related failures of the machine tools or even certain components of these machine tools and thus to enable the best possible functionality of the machine tool, regular inspections are associated with routine maintenance, in which worn components are repaired or replaced, unavoidable.

 The machine tool should therefore be inspected and maintained at regular intervals. However, the measurement of these regular time intervals involves some difficulties. Usually, the machine tools are serviced after predetermined periods of time (e.g., weeks or months) when the machine tool is owned by a user.

 In such a procedure, however, can not really be determined how long the machine tool was actually in use. In other words, the net operating time of the machine tool can not be determined. It is thus possible that although the machine tool was owned by a user for months, the machine tool was either not in use at all or only for a short time.

In the event that the machine tool was not really or only briefly put into operation, a maintenance or a routine replacement of one or more wear-resistant components, but where the wear is not obvious, would be a not to be despised cost factor. Moreover, the absence of the machine tool from the user would only take precious time for probably unnecessary maintenance work, which could have continued to work properly. The failure to be able to grasp the actual time of use of a machine tool is the reason that the operating costs of a machine tool are significantly increased and at the same time the operational readiness or availability of the machine tool is greatly reduced.

It is therefore an object of the present invention to provide a measuring apparatus and method capable of effectively and accurately detecting the actual use time period of a machine tool, thereby eliminating unnecessary maintenance or downtime in which the machine tool is not operational and waiting will minimize.

The object is achieved according to the invention by the subject matter of independent claim 1 and by the subject matter of independent claim 4. Further advantageous embodiments of the present invention are contained in the corresponding subclaims.

 Thus, a measuring device for detecting the running time of a machine tool is provided.

 According to the invention, the measuring device is characterized by

 - At least one sensor with which a magnetic field generated in the machine tool can be detected and with which a signal value in the detection of the magnetic field can be generated;

a counter with a runtime counter; and

 - At least one comparator circuit which is adapted to compare the signal value generated by the sensor with a predetermined reference value and in the case that the signal value is greater than the reference value, the runtime counter of the counter to start and

 in case the signal value is smaller than the reference value, stop the countdown counter of the counter.

By means of the measuring device according to the invention, the running time of a machine tool can be effectively detected on the basis of a magnetic field generated in the electric motor. Since the activation of the electric motor is absolutely necessary for operating the machine tool, the magnetic field necessarily generated by the electric motor or its detection by means of a sensor can be used as proof for the operation of the machine tool. According to a further advantageous embodiment of the present invention can be provided that the sensor is realized by a magnetic field sensor. The magnetic field sensor can be realized for example in the form of a Hall sensor. The use of a Hall sensor provides a particularly convenient and easy-to-use sensor.

Furthermore, it may be possible for the signal value generated by the sensor to be realized in the form of a voltage value. As a result, the signal value generated by the sensor can be effectively compared with a previously stored reference voltage in the comparator circuit.

In addition, a method for detecting a running time of a machine tool with an electric motor is provided.

 According to the invention, this process contains the steps:

 Detecting a magnetic field generated by the electric motor;

 Generating a signal value corresponding to the detection of the magnetic field;

 Comparing the signal value with a predetermined reference value;

- starting a runtime counter of a counter in the event that the signal value is greater than the reference value; and

 - stopping the countdown timer of the counter in case the signal value is smaller than the reference value.

 By means of the method according to the invention, the running time of a machine tool can be effectively detected on the basis of a magnetic field generated in the electric motor. Since the activation of the electric motor is absolutely necessary for operating the machine tool, the magnetic field or its detection necessarily generated by the electric motor can be used as proof for the operation of the machine tool.

According to an advantageous embodiment of the present invention can be provided that the signal value is realized in the form of a voltage value. As a result, the signal value generated by the sensor can be effectively compared with a previously stored reference voltage in the comparator circuit. The invention will be explained with reference to advantageous embodiments, in this case shows

Fig. 1 is a side view of a machine tool with an inventive

 Measuring device for detecting the running time of a machine tool; and

Fig. 2 is a circuit diagram for the inventive measuring device.

Embodiment:

 Fig. 1 shows a machine tool 1 in the form of a battery-operated screwdriver. However, it is also possible that any other type of machine tools, such as e.g. Drills, rotary hammers, saws, grinding machines or the like can be used. In addition, the machine tool can also be operated by a mains voltage as an alternative to the rechargeable battery or in addition to the rechargeable battery. For this purpose, the machine tool 1 contains a corresponding power cable for connecting the machine tool to a mains voltage source. The power cord and the mains voltage source are not shown in the figures.

The machine tool 1 essentially comprises a housing 10, an electric motor 20, a handle 30, a tool holder 40 with a tool 50 and a measuring device 60 for detecting the running time of the machine tool 1.

 The electric motor 20, which is in the form of a DC motor, AC motor, universal motor or the like, is positioned in the housing 10.

The housing 10 of the machine tool 1 includes a first end 12, a second end 13, a top 14 and a bottom 15.

 At the first end 12 of the housing 10, the handle 30 is positioned. The handle 30 has a first (upper) end 32 and a second (lower) end 33. With the first (upper) end 32 of the handle 30 is attached to the first end 12 of the housing 10. Also at the first (upper) end 32 of the handle 30, an operation switch 35 is positioned. The actuating switch 35 is designed in the form of a potentiometer (potentiometer) and connected via a connecting line 36 to the electric motor 20. Alternatively, however, any other suitable switch can be used. The actuation switch 35 further includes a spring 37, which returns the operation switch 35 when not in operation back to the starting position. By actuating the operation switch 35, i. Pressing the operation switch 35 in the direction A, the electric motor 20 is activated. When the operation switch 35 is no longer actuated, i. the operation switch 35 moves in the direction B due to the spring 37, the electric motor 20 is deactivated. Thus, with the operation switch 35, the electric motor 20 is controlled and finally the tool 50 in rotation (rotational direction C or D) is added.

At the second (lower) end 33 of the handle 30, an accumulator 65 is releasably secured again, ie the accumulator 65 can be connected to the handle 30 and removed again. The accumulator 65 serves to supply power to the machine tool 1 or the electric motor 20. The accumulator 65 may be a lithium-ion accumulator or the like. Alternatively (as already described above), the machine tool 1 can also be supplied with a mains power source (not shown) via a network cable (not shown). This mains power source can be a socket.

At the second end 13 of the housing 10, the tool holder 40 is positioned. The tool holder 40 is configured to have a tool 50, such as a tool 50, e.g. a drill or screwdriver bit to receive and hold is connected via a drive shaft 55 to the electric motor 20. With the aid of the drive shaft 55, a torque generated in the electric motor 20 is transmitted to the tool holder 40 and finally to the tool 50. The rotated tool 50 (rotational direction C or D) allows work to be done in the form of drilling or screwing.

 The measuring device 60 for detecting the running time of the machine tool 1 includes a housing 10, a sensor 70 for detecting a magnetic field, a comparator circuit 80 and a counter 90. The measuring device 60 is connected to the upper side 14 of the housing 10.

 The sensor 70 is designed in the form of a magnetic field sensor or the like and arranged in the housing 10 of the measuring device 60 such that it is capable of detecting the magnetic field or magnetic stray field generated in the electric motor 20.

The comparator circuit 80 is likewise positioned in the housing 10 of the measuring device 60 and connected to the magnetic field sensor 70 via a connecting line 62. The counter 90 contains a runtime counter 92 with a display 94, with which the running time of the machine tool 1 is displayed in seconds and can be read by the user. The counter 90 is connected to the comparator circuit 80 via a connection line 96.

For detecting the running time of the machine tool 1, the magnetic field sensor 70 detects the magnetic field (stray magnetic field) which arises in the electric motor 20 when it is activated (set in rotation). Due to the detection of a magnetic field generated in the electric motor 20, the magnetic field sensor 70 generates a signal in the form of a voltage value and transmits it to the comparator circuit 80. The comparator circuit 80 compares the voltage value generated by the magnetic field sensor 70 with a reference value stored in the measuring device 60. The reference value is realized in the form of a voltage value (in the sense of a voltage divider).

In the event that the voltage value generated by the magnetic field sensor 70 is greater than the stored reference voltage, the runtime counter 92 of the counter 90 is activated. The time counter 92 of the counter 90 detects in time units the running time (ie the Activation phase) of the electric motor 20 and thus the machine tool. 1 The runtime is visible in seconds in the display 94. The time counter 92 of the counter 90 remains activated and counts the time units of use of the machine tool 1 until the voltage value sent from the magnetic field sensor 70 to the comparator circuit 80 due to a magnetic field in the electric motor 20 is no greater than the stored reference voltage. The voltage value generated by the magnetic field sensor 70 is dependent (as described above) on the presence of a magnetic field that arises in each electric motor 20 during its activation. When the electric motor 20 is no longer activated (eg, by non-actuation of the switch or lack of energy in the power supply, such as an empty battery) no magnetic field is generated and consequently the magnetic field sensor 70 can no longer detect a magnetic field. Thus, the voltage value is no longer generated by the magnetic field sensor 70 and the reference value is automatically greater than the generated voltage value. In this case, the time counter 92 of the counter 90 is stopped. The already recorded time of use of the machine tool 1 remains so long in the counter 90 and visible until the display of the display 94 by means of a separate (not shown) reset function (delete function) is deleted.

 As soon as a magnetic field arises in the electric motor 20 as a result of the operation of the electric motor 20, this magnetic field is again detected by the magnetic field sensor 70. The magnetic field sensor 70 then again generates a voltage value for the comparator circuit 80, which again compares this voltage value (as proof of a magnetic field) with the fixed reference voltage. If the voltage value is exceeded again above the reference voltage, the runtime counter 92 of the counter 90 is restarted, and the seconds of use of the machine tool 1 are further counted. With the aid of the invention described above, the actual time of use of a machine tool can be effectively measured, whereby the next maintenance or inspection of the machine tool must take place only when the actual maximum time of use is reached.

Claims

 claims

Measuring device (60) for detecting the running time of a machine tool (1) with an electric motor (20),

marked by

 - At least one sensor (70), with which a in the machine tool (1) generated magnetic field can be detected and with which a signal value in the detection of the magnetic field can be generated;

 - a counter (90) with a timer counter (92); and

 - At least one comparator circuit (80) which is adapted to compare the signal value generated by the sensor (70) with a predetermined reference value, and

 in case the signal value is greater than the reference value, start the run counter (92) of the counter (90) and

 in case the signal value is smaller than the reference value, stop the run counter (92) of the counter (90).

Measuring device (60) according to claim 1,

characterized in that the sensor (70) is realized by a magnetic field sensor.

Measuring device (60) according to claim 1 or 2,

characterized in that the signal value generated by the sensor (70) is realized in the form of a voltage value.

Method for detecting and displaying a running time of a machine tool (1) with an electric motor (20),

characterized by the steps:

 - detecting a magnetic field generated by the electric motor (20);

 Generating a signal value corresponding to the detection of the magnetic field;

 Comparing the signal value with a predetermined reference value;

- starting a runtime counter (92) of a counter (90) in the event that the signal value is greater than the reference value; and - Stopping the running time counter (92) of the counter (90) in the event that the signal value is smaller than the reference value.

 Method according to claim 4

characterized in that the signal value is realized in the form of a voltage value.