DE29909200U1 - Operating hours counter for a working device which emits vibrations or vibrations during operation, in particular a manual working device driven by an internal combustion engine - Google Patents

Description

Operating hour counter for a working device that emits vibrations or oscillations during operation, in particular a hand-held tool powered by an internal combustion engine

The present invention relates to the field of machine monitoring. It relates to an operating hour counter for a working device that emits vibrations or oscillations during operation, in particular a hand-held tool driven by an internal combustion engine.

In order to assess assemblies or components of combustion engine-driven work equipment in practical use with regard to wear, fatigue strength, etc., it is necessary to know the service life of the work equipment. This is also important in connection with warranty claims and with the exhaust gas problem in certain countries such as the USA (exhaust gas

relevant parts), the assessment of machine running time plays an important role. In automotive engineering, for example, systems for recording running times are well known. However, these systems are mainly controlled electrically or mechanically.

Currently, the running times of devices powered by combustion engines are determined by estimating the number of tank fills or by using operating hour counters that are electrically controlled by the device's ignition system. However, electrically controlled counters are currently only used in the development process (practical use) of such a device. The disadvantage of electrically controlled counters is that there must be a constant connection to the high-voltage part of the ignition coil. The user can easily intervene and manipulate the counting of the operating time.

It is therefore an object of the invention to provide an operating hour counter which determines the operating time of, for example, a chainsaw in a simple and safe manner without the user being able to intervene in an uncontrolled manner.

The object is achieved by the totality of the features of claim 1. The core of the invention consists in controlling the operating hours counter by means of a contactor in a vibration-excited manner and in firmly connecting the operating hours counter or the controlling contactor to the working device or its motor drive unit. This practically excludes any manipulation by the user. The arrangement of the operating hours counter on the device can be flexibly adapted to the respective requirements (device type, device geometry, etc.).

A first preferred embodiment of the operating hour counter according to the invention, which is designed to be particularly simple and functionally reliable on the sensor side, is characterized in that the contact sensor comprises a pair of contacts which are elastically suspended and contact each other in a swinging manner.

A very safe and, in terms of evaluability, convenient operating hour counter is obtained if, according to a second preferred embodiment, the counting circuit comprises a microcontroller which is supplied with operating voltage from a battery integrated in the operating hour counter and is operated with a fixed clock frequency, and if the clock frequency of the microcontroller is determined by an oscillating quartz.

A preferred development of this embodiment is characterized in that the microcontroller has a detection input, that the contactor is connected to the detection input in such a way that when the contactor switches from one contact state to the other contact state, the logic level at the detection input of the microcontroller changes, and that the microcontroller is programmed in such a way that when the logic level at the detection input changes, it is woken up from a standby state and continues counting in real time for a predetermined period of time, and after this period of time has elapsed, it queries the detection input again to see whether there is a level change and continues counting if there is such a change, or falls back to the standby state if there is no such change. The microcontroller is preferably operated with a clock frequency of several kHz, preferably 32.768 kHz, and the time period between two queries of the detection input is several seconds, preferably about 5 seconds.

A simple and tamper-proof evaluation of the operating hours counter is achieved if, according to another embodiment of the invention, the operating hours counter is permanently connected to the work device, a device is provided for querying the current status of the counting circuit, the counting circuit or the microcontroller has an input which can be controlled by the query device, and by entering a specific data sequence into the input, the counting circuit or the microcontroller can be requested to pass the counting result to the query device.

The security against manipulation is further increased if, according to an advantageous further development, the serial number of the work tool to which the operating hour counter is attached is stored in a readable manner in the counting circuit or the microcontroller, and the counter content and, if applicable, the stored serial number are protected against overwriting or deletion by an unauthorized person.

Further embodiments emerge from the dependent claims.

The invention will be explained in more detail below using an embodiment in conjunction with the drawings. The single figure shows the electrical circuit of an operating hour counter according to a preferred embodiment of the invention. The basic idea for the proposed system is that the implement to be monitored emits oscillations or vibrations during operation, which are detected by a sensor. These oscillations are mainly over 10 g in motor operation. These oscillations are therefore normally different from individual shocks, such as those that occur during transport or storage of the implement. A suitably designed sensor can therefore distinguish between motor operation and "interference oscillations".

In addition, a calibration option can be provided for the operating hour counter.

The electrical structure of the system is shown in the figure. In the operating hour counter 10 shown, detection is achieved by an arrangement of elastically suspended contacts 12, 13, which together form a contactor 11. If the two contacts 12, 13 are exposed to the vibrations of the working device, they oscillate against each other. If mechanical vibrations of a corresponding magnitude are reached, contacting the contacts 12, 13 briefly closes an electrical circuit, which triggers a counting process in a counting circuit 18 connected to the contactor 11. The sensitivity of the contactor 11 is influenced or determined by the free oscillation length of the contacts 12, 13. The contactor 11 is connected to a detection input GP3 of the counting circuit. A parallel capacitor C3 serves to suppress interference in the contactor 11. A resistor R6 forms the working resistance, which sets the detection input GP3 to the positive potential of a connected battery 16 via the resistor R4 when the contactor 11 is open. If the contactor 11 is closed, the detection input GP3 is set to zero potential.

The so-called heart of the operating hours counter 10 or the counting circuit 18 is a special microcontroller 14 (e.g. type PIC12C672 from Microchip Technology Inc.). This processor operates at a clock frequency of 32.768 kHz. This is achieved by an oscillating quartz 15. The two capacitors C1 and C2 serve to improve the oscillation behavior. The master clear is programmed internally. This means that additional components that would be required for external wiring can be avoided. This means that only low component costs arise for the autonomous operation of the microcontroller 14.

The operating hour counter 10 is powered by a battery 16 with a capacity of 50 mAh. With a power consumption of approximately 300 nA in the stand-by state and approximately 15 μα in the activated state, the service life of the operating hour counter 10 is significantly longer than that of the motor unit of the implement.

As already mentioned, when the logic level at the detection input GP3 changes, the circuit is woken up and then counts a predefined time in real time, e.g. 5 seconds. After this time has elapsed, the detection input GP3 is again checked by the microcontroller 14 to see whether a detection has occurred. If a detection has occurred, i.e. the contactor 11 is closed again (due to vibrations in the motor operation), the counting process begins again; otherwise the circuit falls back into the standby state.

At the same time, it is possible to wake up the microcontroller 14 via another GPO input. Here, a data transfer (via a special converter) is then initiated via a connection socket 17 attached to the operating hours counter 10 using a plugged-in reader, whereby the GPO input can both receive and send data. A special signal sequence or a special data sequence ensures that the operating time already counted is read out safely. In addition, the serial number of the monitored work device can be read out for this operating time; this is stored in the microcontroller 14 for security reasons. If a security bit has been set in the circuit by the device manufacturer's initial programmer, the circuit can no longer be overwritten. This means that external interventions in the operating hours counter 10 are ineffective.

Overall, the invention results in an operating hour meter that is simple and reliable, can be easily read electronically, and is characterized by a high level of security against manipulation.

LIST OF DESIGNATIONS

10 Operating hour counter 11 Contactor 12 upper contact 13 lower contact 14 Microcontroller 15 Quartz oscillator 16 battery 17 Connection socket 18 Counter circuit GPO Input (data in/out) GP3 Detection input

Claims (12)

1. Operating hour counter ( 10 ) for a working device which emits vibrations or oscillations during operation, in particular a hand-held tool driven by an internal combustion engine, such as a chainsaw, characterized in that the operating hour counter ( 10 ) comprises a contactor ( 11 ) which is permanently attached to the working device and responds to the emitted vibrations, as well as a counting circuit ( 18 ) which is connected to the contactor ( 11 ) and counts at predetermined time intervals when the contactor ( 11 ) detects operating vibrations of the working device. 2. Operating hour meter according to claim 1, characterized in that the contactor ( 11 ) comprises a pair of contacts ( 12 , 13 ) which are elastically suspended and contact each other in a swinging manner. 3. Operating hour counter according to one of claims 1 and 2, characterized in that the counting circuit ( 18 ) comprises a microcontroller ( 14 ) which is supplied with operating voltage from a battery ( 16 ) integrated in the operating hour counter ( 10 ) and is operated with a fixed predetermined clock frequency. 4. Operating hour counter according to claim 3, characterized in that the clock frequency of the microcontroller ( 14 ) is determined by a quartz oscillator ( 15 ). 5. Operating hour meter according to one of claims 3 and 4, characterized in that the microcontroller ( 14 ) has a detection input (GP3), and that the contactor ( 11 ) is connected to the detection input (GP3) in such a way that when the contactor ( 11 ) switches from one contact state to the other contact state, the logic level at the detection input (GP3) of the microcontroller ( 14 ) changes. 6. Operating hours counter according to claim 5, characterized in that the microcontroller ( 14 ) is programmed in such a way that it is woken up from a stand-by state when the logic level at the detection input (GP3) changes and continues to count in real time for a predetermined period of time, and after this period of time has elapsed, it queries the detection input (GP3) again to see whether there is a level change and reports if there is such a change or falls back into the stand-by state if there is no such change. 7. Operating hour meter according to claim 6, characterized in that the microcontroller ( 14 ) is operated with a clock frequency of several kHz, preferably 32.768 kHz, and that the time period between two queries of the detection input (GP3) is several seconds, preferably about 5 seconds. 8. Operating hour counter according to one of claims 1 to 7, characterized in that the operating hour counter ( 10 ) is firmly connected to the working device, and that a device ( 17 ) is provided for querying the current status of the counting circuit ( 18 ). 9. Operating hours counter according to claim 8, characterized in that the counting circuit ( 18 ) or the microcontroller ( 14 ) has an input (GP0) which can be controlled by the query device ( 17 ), and that by entering a specific data sequence into the input (GP0) the counting circuit ( 18 ) or the microcontroller ( 14 ) can be requested to pass on the counting result to the query device ( 17 ). 10. Operating hour counter according to one of claims 8 and 9, characterized in that the query device is designed as a connection socket ( 18 ) which is integrated in the operating hour counter ( 10 ) and is connected to the counting circuit ( 18 ) or the microcontroller ( 14 ). 11. Operating hour counter according to one of claims 8 to 10, characterized in that the serial number of the working device to which the operating hour counter is attached is stored in a readable manner in the counting circuit ( 18 ) or the microcontroller ( 14 ). 12. Operating hour meter according to one of claims 8 to 11, characterized in that the counter content and, if applicable, the stored serial number are protected against overwriting or deletion by an unauthorized person.