FR2635894A1 - Time counter for vibrating appliances - Google Patents

Abstract

This counter comprises: a vibration detector of the piezoelectric type 10, a shaping circuit 12, a microprocessor 15, a time base 20, a display means 24. Preferably, the counter also comprises a means 32 for manual control of the display. This counter displays the number of hours of operation of the equipment to which it is fixed. Application to the measurement of the operating time of equipment fitted with a motor (petrol or diesel) of boats (fishing or pleasure) of outboard engines, of generators, motor-driven pumps, agricultural equipment, aircraft, etc.

Description

HOUR METER FOR VIBRATORY DEVICES
DESCRIPTION
The present invention relates to an hour meter for vibrating devices. It finds an application each time one wants to measure the operating time of a device likely to be the seat of vibrations, whether it is a vehicle equipped with an explosion engine, a diesel engine or electric motor, regardless of the vehicle on which this engine is mounted: outboard, fishing or pleasure boat, light aircraft, forklift, tiller, tractor, or whether it is still a generator, a generator, a refrigerator, a compressor, a motor pump, ctc.

This measurement of the operating time is necessary to determine the expediency of carrying out various checks, adjustments, oil changes, etc. or to invoice
Rentals made by duration.

 Today there is no simple, robust and inexpensive way to measure the operating time of a device. Naturally, it is always possible to produce a device connected to a supply means or to the ignition circuit of an engine, to carry out this measurement. But such a device is irremovable, bulky, not autonomous and difficult to install.

 The object of the present invention is precisely to propose an apparatus which overcomes these drawbacks.

To this end, the invention provides an hour meter for a vibrating device, this meter being characterized by the fact that it comprises - a vibration detector of piezoelectric type, - a shaping circuit having a connected input
to the detector, - a microprocessor having a repair input
of operation, this input being connected to the
output from the shaping circuit, this
microprocessor being able to count the
time, this microprocessor having at least one
memory for storing the cumulative result of this
counting with the cumulative counting result
previous, - a time base connected to the microprocessor, - a display means connected to the microprocessor for
display of the cumulative result stored in the
memory, - a power supply battery.

 The shaping circuit can be an alogic circuit.

 The counter of the invention may include a manual control means of the display, connected to the microprocessor.

 Preferably, the display means comprises a liquid crystal display screen. However, the other known display means are not excluded (light-emitting diodes, plasma, etc.).

 The microprocessor may include a second memory for storing the result of a partial count. The counter is also provided with a manual means for resetting the content of this second memory to zero.

 More preferably, all of the counter means are molded from a block of impervious material, for example a polymer.

In any case, the characteristics and advantages of the invention will appear better in the light of the description which follows. This description relates to exemplary embodiments given by way of explanation and in no way limiting, and it refers to the attached drawings in which:
FIG. 1 represents the block diagram of the counter of the invention,
FIG. 2 illustrates a particular node for realizing this counter,
FIG. 3 shows a node for making the vibration detector,
FIG. 4 shows the external appearance of a counter according to the invention,
- Figure 5 shows the appearance of the display screen in various situations.

The device shown in FIG. 1 comprises a counter 8 in accordance with the invention fixed on an apparatus 9 capable of vibrating when it is in operation. The counter 8 comprises a piezoelectric type vibration detector 10, a shaping circuit 12 having an input 13 and an output 14,
The input 13 being connected to the detector 10. This circuit 12 is capable of delivering an appropriate signal, for example a logic signal, on the output 14 When iL receives on its input 13 an electrical signal corresponding to the electrical charges generated by the means piezoelectric 10 when it is subjected to vibrations from the device whose operating time is to be counted. The device shown also comprises a microprocessor 15 having three inputs 16, 17 and 18 and an output 19. The input 16 is an input for reconditioning of operation (in English terminology "reset"). A time base 20, constituted for example by a quartz oscillator or RC, is connected to the input 18 of the microprocessor 15.

A push button 32 is connected to the input 17 of the microprocessor 15.

 The device also comprises a display means 24 connected to the output 19 of the microprocessor 15.

This means comprises for example a display control circuit 26 and a display screen 28, which is, for example, of the liquid crystal and seven segment type.

 The operation of this hour meter is as follows. The vibrations of the device 9 are translated into electrical signals by the detector 10 and transmitted to the circuit 12. The latter generates a signal of suitable form which is applied to the input 16 ("reset") of the microprocessor. , which is normally in a standby state, is awakened by the signal applied to the "reset" input. The microprocessor 15, which receives clock pulses from the oscillator 20, counts the time for as long that it is kept in working order, that is to say as long as there are vibrations.

 The result of this counting can be displayed directly on the display 28 or displayed on command by pressing the push button 32. The time counted, during each start-up, is accumulated in a memory, which is an integral part of the microprocessor and is kept energized. By pressing button 32, the cumulative running time of the engine with which the counter is associated is therefore displayed.

The battery 30 can be a lithium battery of which
The lifespan is several thousand hours.

 The resonator 20 can be between a ceramic or quartz resonator operating for example at 262,144 Hz or at 32,768 Hz.

By way of nonlimiting example, FIG. 2 represents a particular embodiment of an hour meter according to the invention. In Figure 2, we find elements that have already been represented on
Figure 1 and which, for this reason, the same references.

 Figure 2 shows the connections to be made with the microprocessor which is, in the illustrated case, The microprocessor type PD 7754 or 64 sold by The firm NEC. You can find, on the commercial sheet relating to this product, all the characteristics of the microprocessor.

The liquid crystal display can be of the LC 241440 type sold by the company RTC. It can be controlled by a control circuit of the type
PCF 2112 marketed by La Société RTC.

In the case illustrated in FIG. 2, the shaping circuit 12 is a logic circuit which includes four NAND type gates ("NAND" in English terminology) referenced P1, P2, P3 and
P4. The doors P1 and P2 are mounted on an RS flip-flop.

This flip-flop changes state under the control of signals coming either from the antenna by connection a or from the microprocessor by connection b. door P4 reverses the logic signal delivered by door P3.

When a logic signal "O" is applied to
The input "reset" of the microprocessor, it leaves its standby state and starts counting. The flip-flop changes state periodically under the control of the microprocessor, via connection b but resumes its state if charges continue to be delivered by the piezoelectric detector. Thus, the Logical level "O" remains applied to input 1, reset "and the microprocessor continues to count.

Action on push button 32 causes
The appearance of an "O" on one of the door entrances
P3, where an "O" is applied to the other input from the flip-flop; then P3 gives a "1" and
P4 an "O", which triggers the microprocessor. Furthermore, the output of the flip-flop is connected by a connection c to the microprocessor which selects either
The display of the counted time if the Logical state of the connection is "1", or you count if the state of the connection is "O".

 This logic shaping circuit can optionally be integrated into the microprocessor.

 Other shaping means could be used, such as for example a rectifying diode and a storage capacitor, the voltage resulting from the storage of the charges coming from the piezoelectric detector determining the duration of the counting.

 FIG. 3 shows an embodiment of the detector 10.

 In the variant illustrated, the detector comprises a piezoelectric patch 50 disposed on a metal disc 52 and covered with an electrode 54. A counterweight 56 is in contact with the assembly.

The disc 52 is provided with three feet 58 which come to bear on the apparatus 9.

 The disc 52 is electrically connected to ground. The electrode 54 is connected to the input 13 of the circuit 12, a resistor R, for example of 1 m, being connected between the input 13 and the ground.

 When the device 9 is in operation, its vibrations are communicated to the device 10 and the piezoelectric pad 50 is subjected to voltages which cause electrical charges to appear on its faces.

 The piezoelectric pellet 50 can be barium or pLomb titanate, or barium zirconite or pLomb, or a mixture of titanate and zirconate, or any other material known for its piezoelectric properties.

By way of illustration only, it may be indicated that it is possible, to constitute the detector 10, to use a device from the firm
MURATA MFG, Co, LTD, called "Shock Sensor PKS1-4A1.

 Such a system is sensitive to vibrations ranging from 10 Hz to 1 kHz.

 FIG. 4 shows an exemplary embodiment of a counter according to the invention. All the means described in FIG. 2 are soft in a material 40 which is, for example, a flexible anti-shock and anti-vibration polymer which guarantees total tightness up to 10 meters in depth and resistance to marine atmosphere. FIG. 4 also shows the display screen 28 and the push button 32 on which the operator can act to cause the display of the number of hours of operation of the device.

 The illustrated device also includes a fixing lug 42 and it may have a rear face coated with an adhesive layer 43. The fixing of such an apparatus is therefore immediate.

Finally, Figure 5 shows the display screen 28 in three situations a) - The engine is stopped no indication
does not appear on the screen, b) - The engine is running: an "on" (or "run") signal
or any other) signals this operation, c) - the meter reading is carried out: a number
appears on the screen (in this case 3825) which
corresponds to the number of operating hours of
The device. In this case, the device can be
stopped or in operation.

 The display can be done by four digits with a height of 6.8 miLimeters. The dimensions of such a shoemaker can be 70x50x25 mm.

The autonomy of the counter of the invention is considerable and can exceed several thousand hours.

Claims (9)

 1. Hour meter for vibrating devices, characterized in that it comprises: - a vibration detector (10) of piezoelectric type, - a shaping circuit (12) having an input  (13) connected to the detector (10), - a microprocessor (15) having an input (16) of  return to operational condition, this input being  connected to the output (14) of the shaping circuit  (12), this microprocessor (15) being able to perform  a tempo count, this microprocessor having at  minus a memory for the storage of the cumulative  result of this count with the cumulative result of  previous counts, - a time base (20) connected to the microprocessor  (15), - a display means (24) connected to the microprocessor  to display the cumulative result stored in the  memory, - a power supply battery (30).  2. Hour meter according to claim 1, characterized in that the shaping circuit (12) is a logic circuit.  3. Hour meter according to claim 2, characterized in that the logic circuit comprises an RS type flip-flop with two control inputs, One connected to the detector (10) and the other to the microprocessor (15).  4. Hour meter according to claim 1, characterized in that it comprises means (32) for manual control of the display, connected to the microprocessor (15).  5. Hour meter according to claim 1, characterized in that the display means (24) comprises a liquid crystal display screen (28).  6. Hour meter according to claim 1, characterized in that the vibration detector (10) comprises a piezoelectric pad (50) disposed between two electrodes (52, 54), one of which (54) is connected to the input (13) of the shaping circuit (12).  7. Hour meter according to Claim 1, characterized in that the microprocessor (15) comprises a second memory for storing the result of a partial counting and in that it also comprises a manual means for resetting the zero contents of this second memory.  8. Hour meter according to one queLconque of claims 1 to 7, characterized in that all the means of the counter are molded in a bLoc of waterproof material (40).  9. Hour meter according to claim 8, characterized in that the material in which the counter means are molded is a polymer.