HU188275B - Method and apparatus for measuring selecticed parameters of any process and in particular case for intervention as well as for storing and processing - Google Patents

Abstract

THE OBJECT AND OBJECT OF THE INVENTION IS TO OBTAIN A DEVICE FOR MEASURING CERTAIN PARAMETERS OF ANY PROCESSES THAT CONTAIN THE BENEFITS OF THE PROGRAMMED AND THE PROGRAMMED EQUIPMENT. THE TASK IS ESTABLISHED THAT THE DEVICE HAS AT LEAST ONE GALVANIC AND / OR NON-GALVANIC FACILITY BY MEANS OF AT LEAST ONE INPUT AND ON AN INTEGRATED CONNECTING DEVICE WITH A DINING AREA, PARAMETERS SUBMITTED TO SIGNALING DEVICES, PREFERRED WITH A ROUTE TRANSMITTER AND A BRAKE SIGNAL PROVIDER. FURTHERMORE, THE EQUIPMENT OF AN ACTIVE UNIT FOR MEASURING ANY PARAMETERS, INCLUDING FUEL CONSUMPTION, LOADING, SPEED TWO-SIDED.

Description

it is provided with a suitable connection to a further data processing system. Programmable measuring, data acquisition and actuator devices can be connected to a stable computer. ₍

The present invention relates to a method and apparatus for measuring and, if necessary, interfering with selected characteristics of any process and for storing and processing data.

Novelties and advantages of using the method and circuit arrangement of the present invention will be described in greater detail by way of example in the automotive application, but it will be emphasized that beyond this example, the invention may also provide significant advantages in any application.

Referred to in connection with Examples include better understanding of the invention, the use of the subject motor vehicle, that as known, the regulations require that a particular type must be equipped with two gépjármüve- ² tachograph which, however, mainly provide data highway end. However, it would be in the interest of haulage companies to implement a vehicle performance measurement and recording system ² which would allow the automated measurement of the performance data of the transport data and the processing of the measured data and, if necessary, intervention during the vehicle operation.

To the best of our knowledge, there is no apparatus ³¹ capable of satisfying the above requirements, namely, with measuring accuracy and reliability which, for example, is accurate. provide the necessary information with the accuracy and certification ³¹ required by the accounting and billing requirements of transport companies.

In order to partially solve the above-described tasks, several solutions have become known in the field of transport, some of which are described in the literature: ^{41, No.} 4,067,061. US Patent No. 4,198,115, issued to Ontario, discloses a so-called on-board computer for motor vehicles, the function of which is to measure vehicle parameters, taking into account time-speed-fuel consumption, and to measure data. fasten the case. According to this solution, sensors are connected to a pulse generator for measuring certain parameters of the vehicle. The pulse generator is connected to a counter and in this way the signals are set in parallel, 5! stored in a temporary storage facility. A counter is connected to this repository, which is also connected to a serial to parallel converter. The intermittent storage is coupled to a sequence switch and decoder to read the stored signals Fi, which are read out in a specified sequence with a start signal. The apparatus also has an input code register which is connected to the sequence switch and decoder to receive parallel signals, and a drive stage is connected to the code register which also produces parallel signals.

The drive stage is connected to a manually adjustable counter to generate fuel consumption signals. The equipment is a scam

It also has 275 permanent storage devices, the control of which is connected to the temporary storage and the sequence switch, as well as to the decoder. ve. From the temporary storage, the overflow signals are transmitted to the permanent storage ¹ .

No. 4084,241. The apparatus described in U.S. Patent No. 5,123,121 is used to determine the exact position of vehicles while in motion. Its most important application is eg. the task of cartographic surveys. The device comprises a first and a second independently movable wheel, which are mounted on both sides of the vehicle in the direction of movement. These are the body. they create blue time pulses within the word 'period'. The organs connected to the two wheels produce pulses proportional to the two organs. The apparatus shall have an organ which generates time - value signals at specified periods,. based on which the speed of the vehicle can be determined separately for each wheel. The velocity data obtained is integrated and the difference in velocity between the two velocity values over a given time period is determined, which is the trigonometric equation. with tees. As a result, high accuracy can be obtained in determining the moving position of the moving vehicle.

No. 4083,052. U.S. Pat. No. 4,124,195 also relates to motor vehicles and also discloses an electric tachograph. According to this solution, the distance traveled is recorded as a function of speed. They produce distance pulses and time pulses (clock signals). These impulses are evaluated together. The object of the device is to replace the mechanical unit of known mechanical tachographs by electronic switching.

The Hungarian 174,798 l. The apparatus described in U.S. Pat. The measurement is performed with an electronic force meter cell weight sensor.

Several other patents have become known for measuring the driving parameters of motor vehicles. Of these, mention is made of the solutions described in U.S. Patent Nos. 2,255,960, 2,113,307, and 2,230,923, ⁵ which have the common feature of replacing previously used mechanical tachometers with structures formed by electrical circuits, in particular inductive circuits. For measuring ⁵ speeds of motor vehicles, U.S. Patent Nos. 2,529,275 and 2,346,556 have become known, where essentially the absolute speed of a motor vehicle is measured by sensing it from another vehicle. These solutions have also become known as "trafipax"> mcretcssc

The solutions according to German Patent Nos. 2,754,035, 2,601,800, 2,616,972, 2,618,970, and 2,619,215 are also fork-type switches for measuring the speed of vehicles and the distance traveled, while the solution described in German Patent No. 2,346,670. describes the electrical tachometer circuit used to control the speed of the vehicle.

In connection with the subject matter of the present invention, it is known in applications other than motor vehicles

Among the many solutions for detecting, evaluating and storing 188,275 received signals, reference is made to Hungarian Patent No. 174,090, which discloses a measuring apparatus suitable for any periodic motion ordination. This measuring device measures alternating voltages during the measuring period and performs the measurement in relation to the rotational speeds. The principle of measurement is to determine the distance between positive and negative half-waves of the AC voltage signal.

The apparatus of Hungarian Patent No. 173,811 is a multichannel recorder whose function is to transmit, amplify and record signals on 48 adjacent channels.

The device according to Hungarian Patent No. 170,852, which is intended to solve different measurement and control tasks by changing the stored program, is also suitable for performing any measurement and / or control task. The apparatus has a measuring and / or controlling microprocessor and is provided with a memory connected to a central unit. The novelty of said apparatus is that the input-output units connected to the central unit have an address register to which a selection unit and a decoder are connected. The output of the selection unit is connected to the inputs of the input and output units, and the outputs of the decoding unit are connected to the selection input of the input and output units. The point of using the equipment is that the channels can be used for measuring and control purposes at all times in accordance with the variable program. However, this equipment cannot solve dynamic program switching.

The German Patent Publication Nos. 2 644 180, 2 707 783, 2 707 800, 2 707 820 disclose devices of any application having central units or peripherals. Transceivers are used between central units and peripherals for the secure communication and transmission of data between transmitters and receivers.

The apparatus described in German Patent Publication No. 2 845 218 is a microprogram controlled record reader device and method for recording and reading operations, which is intended to measure, evaluate, and intervene in a central processing unit the parameters sensed on a serial production line. The purpose of the equipment is to improve the quality of production. The equipment is characterized by a stable construction.

There are many similar types of microprogram-controlled equipment of the latter, for example, in the machine tool industry for program-controlled computer control and actuation equipment, which are programmed to control the machine, detect machining parameters during operations, transmit data to the central computer, and programmed values. interference with microprocessor circuits by comparing the values to the values, or modifying the machining parameters accordingly. These devices are also characterized by a stable build, the task of which is to carry out operations corresponding to a predetermined program with strict tolerance by means of modern automated tools.

The solutions of the aforementioned patents, which are intended to detect and evaluate parameters both in the automotive industry and in general use, are not suitable for the following needs.

- to measure process characteristics such as the driving characteristics of each vehicle (road, time, speed, etc.), and at the same time

- to qualify the measured characteristics on the basis of administrative and management comparisons with a given program, and at the same time

- the qualification of the measured characteristics (eg from a traffic safety perspective)

- statistical aggregation and categorization of the qualities of measurement series obtained in the same application (eg selected vehicle groups),

- recording and storing specific data on processes grouped by arbitrary aspects and process management (eg motor vehicles and drivers),

- providing a continuous data supply to support operational organization, planning and management,

- evaluating any process (human activity, mechanized technological process, biological process, etc.) and providing for the possibility of intervention where necessary.

In summary, to the best of our knowledge, none of the types of state-of-the-art fixed measurement and freely programmable equipment of the prior art are capable of providing a practically economical solution to all of the above tasks with the required accuracy. Fixed-programmed devices are fixed services, their programs cannot be changed flexibly and dynamically, whereas freely-programmed devices are not goal-oriented and programming requires considerable expertise.

It is an object of the present invention to further develop known methods and apparatus so that all the services listed in the common drawbacks of known solutions can be bi-linked using the method and apparatus of the invention.

It has been discovered that the above requirements can be met in the most economical way by the hybrid apparatus which carries the advantages of both fixed and freely programmable devices, the method according to the invention and the circuit arrangement.

The apparatus for carrying out the method of the present invention is constructed using a single, stable, centralized, programmable computer known per se, associated with any number of units applicable to the measuring or intervention site, which units are represented by a program corresponding to the computer-defined function.

-3188 ?? and can be operated accordingly by sensing, evaluating and displaying or intervening as desired parameters.

The present invention provides a method for measuring the characteristics of any process, comparing the measured data with pre-programmed values, and interfering with the process according to a predetermined program based on the result of the comparison, storing the allowed extreme values of selected process characteristics in a data memory; this data is continuously compared to the actual values of the process characteristics and, in the event of unauthorized discrepancies, the process is intervened according to a predefined program.

The essence of the method according to the invention is to load the predetermined program and the permissible extremes of the process into a storage of a mobile device by a central computer; and converting the current process parameters into signal values stored in the mobile device by a signal generator which are stored in the mobile device, and simultaneously comparing the preprogrammed values with the actual values and then, in the case of unauthorized values, the mobile device control device (e.g., microprocessor) we intervene according to the prescribed program. If necessary, the centralized computer is used to summarize and evaluate the measurement results and / or the recorded values of the interventions.

The method according to the invention may also be carried out by storing the actual measured values in the mobile device memory grouped according to selected operating state characteristics (e.g., operating time - down time).

The apparatus for carrying out the process of the present invention is for measuring and, if necessary, interfering with selected characteristics of any process and for storing and processing data. The stable computer of the equipment is equipped with a display, a keyboard and, if applicable, a mass storage device, a printer and a connection to another data processing system. The stable computer can be connected to a programmable measuring, data acquisition and intervention mobile device. The object of the invention is that the programmable measuring, data acquisition and actuating mobile device is known per se through an adapter that converts the actual characteristics of the process into galvanic and / or non-galvanic (e.g., magnetic, inductive, optical, acoustic, etc.) signals. it has the power supply of the equipment, transducers measuring the given parameters, eg. with traffic signal, brake signal, etc. and other quantities are bidirectional, e.g. fuel consumption, load, speed, etc. measuring and intervening unit.

The apparatus of the present invention may be configured such that a programmable measuring, data acquisition, and actuating mobile device is comprised of a microprocessor circuit having an oscillator and a dividing circuit connected to each of its be4 threads. The output of the oscillator is connected to the input of the divider circuit. The microprocessor is bidirectionally interfaced with a program memory, a memory, a data memory, and a gateway circuit. A further switching input is connected to the further input of the data memory, while the switching input is connected to an internal voltage source, if appropriate. One of the outputs of the container is connected via a display to a transducer (eg optical). The other output of the container is also connected to a display. The display input is connected to the positive stabilizer corner. The encoder input is also connected to the positive stabilizer corner. The gating circuit has one or more inputs. The stabilizer input is connected to the unit's power supply and, in the case of vehicles, to the vehicle battery. The positive corner that forms the stabilizer output is connected to the oscillator, divider, storage, gating circuit, program memory, microprocessor, and switching power supply input.

The gate circuit according to the invention can be formed with three inputs, the first and second inputs of which are connected to the gating circuit via a signal receiver (e.g., a transistor), and the third input of the gating circuit is a breakable conductor connected to the positive corner of the stabilizer.

The process according to the invention and the exemplary embodiment of the apparatus for carrying it out will be described in greater detail with reference to the drawings in connection with the use in motor vehicles. In the exemplary embodiment, the data of the performance programs made for a select group of vehicles is detected, measured, stored and, if necessary, displayed by a stable computer programmable mobile device, and finally the stored data is processed by connecting the mobile device to the stable computer.

Figure 1 is a block diagram of a stable computer, associated with a tachograph temporarily connected to the stable computer for programming or evaluation of stored values.

Figure 2 illustrates a block diagram of mobile devices in a location of a measurement process, such as in a vehicle, showing directions of data flow.

Figure 3 is a block diagram illustrating the circuitry of the recording equipment of a mobile device.

As shown in FIG. 1, one of the inputs of the stable computer 1 is connected to the keyboard output 4 and the other input to the mass storage device 5 via bidirectional communication. An additional input of the stable computer 1 is also connected to the interface 7 via bidirectional connection, which is always galvanic or galvanically unattached to any device of any number of mobile recording equipment 2 (e.g. magnetic, inductive, optical, acoustic, etc.). it is bidirectional.

Figure 1 does not illustrate an embodiment in which multiple interfaces 7 and thus several recording equipment can be connected to the stable computer 1 simultaneously.

188 275

One output of the stable computer 1 is connected to the display 3 and the other output is connected to the printer 6. The stable computer 1 has an additional output which is connected to the input of the further data processing system 28. The circuit of Figure 1 does not necessarily include the mass storage 5, the printer 6, and the connection 28 to the further data processing system. The application of these units always depends on the services you want.

FIG. 2 illustrates mobile device devices with arrows indicating data flow directions. The tachograph mobile device 2 itself is known to have a galvanic and / or non-galvanic connection (e.g., magnetic, inductive, optical, acoustic, etc.) to the power supply 9 (which in the present embodiment) battery), with one-way communication with the transducer 10, with the brake transducer 11, and two-way communication with other encoder and / or actuators 12 (e.g. . Figure 3 is a block diagram illustrating the circuitry of the recording equipment of a mobile device.

At one of the inputs of the microprocessor 13 of the mobile device, the oscillator 16 and the dividing circuit 17 are connected. The output of the oscillator 16 is connected to the input of the distribution circuit 17. The microprocessor 13 is bidirectionally connected to program memory 14, storage 18, data memory 15, and gate circuit 19. A further input of the data memory 15 is connected to the switching output 26, while the switching input 26 is connected to an internal voltage source 25. One of the outputs of the container 18 is connected via a display 22 to a encoder 23 (e.g., an optical encoder). The other output of the container 18 is also connected to a display 22 (e.g., an optical display). The display input 22 is connected to the U + positive corner of the stabilizer 24. The input of the encoder 23 is also connected to the U + corner of the stabilizer 24. The gate circuit 19 has one or more, but preferably three, inputs. The first and second inputs are connected to the gate circuit 19 via the transceiver 20, while the third input of the gate circuit 19 is connected to a switch 21 which is connected to the positive terminal U + of the stabilizer 24. The inlet 24a of the stabilizer 24 is connected to the vehicle's power supply, optionally a battery. The U + positive corner of the power supply constituting the output of the stabilizer 24 is connected to the input of an oscillator 17, a dividing circuit 17, a storage 18, a gate circuit 19, a program memory 14, a microprocessor 13 and a switching power supply 26.

The process of carrying out the circuit arrangement according to the present invention is illustrated by the following example:

Referring now to Figure 1, with respect to the mode of operation of the device, it is shown that the recording device 2 is inserted into the receiving portion of the interface 7. The two-way connections already mentioned between the tachograph mobile device 2 and the interface device 7 allow two-way connections between the interface 7 and the stable computer 1 to fill the data memory 15 of the tachograph mobile device 2 (see FIG. 3) and When using the tachograph mobile device 2, the data stored in its data memory 15 can be retrieved via the stable computer 1.

On the display 3 connected to the stable computer 1, the operating mode selector of the device is displayed. Based on this, the operator selects the desired mode using the 4 keypad. The available operating modes for this embodiment are:

- accurate time setting

- filling of the recording equipment

- reading the recording equipment

- operational management functions

- equipment tests.

Setting the exact time essentially entails entering the current time into the stable computer 1. As a result, the internal clock of the stable computer 1 assigns all data to this current time until the next time setting.

When selecting the mode for uploading the tachograph 2 mobile device, the operator will fill in the form shown on the display 3 with the keypad 4. The form contains the identification data and measurement instructions required for the application of the tachograph mobile device 2. Formal and content-based verification of these data and measurement instructions is performed by a stable computer 1 using a database created on the mass storage device 5. This database contains data specific to the vehicles being tested, the personal data of the drivers being tested, and finally data specific to the groups of vehicles to be tested (eg fuel consumption, downtime, driving hours, kilometers traveled, etc.). After selecting the mode of querying the tachograph mobile device 2, the stable computer 1 reads through the interface 7 the data stored in the data memory 15 of the tachograph mobile device 2. Based on this data, the stable computer 1 performs calculations and evaluations according to the desired mode of operation and displays them on the display 3. At the instruction of the operator, this data may also be displayed on the printer 6, stored in the mass storage device 5 and transmitted to the further data processing system 28.

By selecting the operational control function, it is possible to modify the contents of the database on the mass storage 5 and to retrieve information in the database.

When selecting the device test mode, the stable computer 1 automatically checks the reliability of the associated devices and its operation. This control activity is carried out in a manner known per se.

According to the circuit diagram shown in the figure, the operation of the devices of the mobile device proceeds as follows:

The operation of the mobile device starts when the driver places the tachograph 2 mobile devices in the vehicle and fixed

-5188 275 fixed 8 adapters that convert the current process characteristics to the signal form of the stored signals. Thereafter, the recording device 2 continuously records the signals of the transducer 10, the brake transducer 11 and the unit 12, which signals are transmitted to the data memory 15 of the recording device 2 via the adapter 8. The recording device 2 classifies the incoming data according to the measurement instructions stored in the data storage 15. As a result of the certification, in the cases defined by the measurement instructions, the mobile recording device 2 may provide signals to the driver, either through the unit 12 or through the displays 22 (see Figure 3).

Referring to Figure 3, the operation of the tachograph mobile device 2 is described in detail:

The basic program for operating the tachograph mobile device 2 is contained in the program memory 14 and the data memory 15. Program memory 14 includes a basic program for operating the tachograph 2 mobile device. This basic program can be influenced by a wide range of measurement instructions loaded into the data memory 15 by the stable computer 1. The tachograph 2 mobile device groups the measured and qualified data according to the technological modes (for example, tapping, idling, loading, waiting, etc.). The current technological mode is entered by the driver in the data memory 15 of the tachograph mobile device 2 via the switch 21 via the gate circuit 19. By means of the transponders 20, it can be ensured that the transducer 10, the brake transducer 11 and the a. The signals of the transducers of the unit 12 are detected by the microprocessor 13 via the gate circuit 19. The microprocessor 13 evaluates, qualifies, and groups the signals thus obtained in the program memory 14 and the data memory 15 in group memory 15. The 13 microprocessors are also capable of performing comparative tasks. If the values of the received signals deviate from the measurement values in the measurement instructions stored in the data memory 15, the microprocessor 13 may provide signals to the driver via the storage 18 via the displays 22 and the transmitter 23. The oscillator 16 provides the microprocessor 13 with a basic clock signal for its operation, and the clock signals fed to the dividing circuit 17 make the microprocessor 13 suitable for timing. The stabilizer 24 feeds the electronic circuits of the tachograph mobile device 2. The data stored in the data memory 15 is protected by an internal voltage source 25 via a switch 26 upon termination of the voltage at the U + positive corner of the power supply 24.

The apparatus described above in connection with the above embodiment and the method of operation thereof are used for recording, checking, evaluating and intervening (issuing alarms) of a vehicle's performance data for a particular task.

The method according to the invention and the apparatus according to the invention are illustrated in Figs

However, the construction shown in Figure 3 is within the scope of our claims for both continuous evaluation (human activity, mechanized technological tasks, biological processes, etc.) and the ability to intervene as required. To accomplish such tasks, the outlined circuit arrangement is adapted by modifying the operating program of the stable computer 1 or other suitable software. Of course, for applications other than the above embodiment, the program memory 14 of the tachograph mobile device 2 also needs to be modified accordingly.

The exemplary application outlined above illustrates one of the possible uses in the automotive industry. For applications other than the automotive industry, the following examples are briefly mentioned.

The purpose of the water flow gauge buoy system is the management of processes under the Water Management and Environmental Program and the computerized evaluation of process management.

Similarly to the previous example, the computer programmed mobile device 2 compares the preprogrammed and actual measured values on site and performs the necessary interventions without human intervention.

Another example of application in agriculture is the operation of seed drills, i.e. row spacing, grain spacing, and seed drilling. monitoring the required values of sowing uniformity and intervening as necessary.

Claims (4)

Patent claims 1. A method of measuring selected characteristics of any process, comparing the measured data with pre-programmed values, and interfering with the process according to a predetermined program based on the result of the comparison, storing in the data memory the allowable extreme values of the selected process characteristics. continuously comparing the current values of the process characteristics and, in the event of unauthorized discrepancies, performing an intervention corresponding to a predefined program, characterized in that the predefined program and the permissible extremes of the process are loaded into a mobile device storage by a central computer; converting the current process parameters to a signal corresponding to the values stored in the mobile device by a signal former, storing these signals in the mobile device and simultaneously comparing the preprogrammed values with the actual values and then, in case of unauthorized values, using the control device of the mobile device program intervention in accordance with the program; and optionally, using a central computer, to summarize and evaluate the measurement results and / or recorded values of the interventions. 2. A method according to claim 1, wherein the current measured values are stored in the mobile device memory grouped according to selected operating state characteristics (e.g., downtime). -6188 2 / j 3. An apparatus for any process chosen characteristics of the measurement comparison and optionally with pre-programmed values of the measured data to interference, and for storing and processing data, said central stable ^and computer display, with a keyboard, and optionally background storage, printer and suitable for further data processing system in connection is equipped; furthermore, a programmable measuring, data acquisition and actuation device ¹⁰ can be connected to a stable computer, a galvanic and / or non-galvanic adapter via a known adapter for converting the actual characteristics of the process into a waveform of stored signals. (eg. magnetic, tendon ¹⁵ reductive optical, acoustic, etc.) is connected to the device power supply of said (eg. road encoder fékjeladóval, wherein measuring the characteristics of process transmitters that the mobile device has other quantities (2) two-way communication, eg. ²⁰ fuel consumption, load, speed, etc. meter and able also to interfere unit (12), the programmable measuring, data acquisition and impact mobile device (2) is a microprocessor circuit having an input of ősz- ²⁵ cillátor (16) and a splitting circuit (17) connected, the output of the oscillator (16) connected to an input of the splitting circuit (17), the microprocessor (13) is bidirectionally connected to a program memory (14), a memory (18), a data memory (15) and a gating circuit (19); a further input of the data memory (15) being connected to an output of a switch (20), the input of said switch (26) being optionally connected to an internal voltage source (25); one output of the container (18) being connected to a transducer (23) via a display (22), while the other output of the container (18) is also connected to a display (16); the input of the display (22) being connected to the positive corner (U +) of the stabilizer (24); the input of the transmitter (23) is also connected to the positive corner (U +) of the stabilizer (24); the gating circuit (19) having one or more inputs and the inlet (24a) of the stabilizer (24) being connected to the power supply of the apparatus; and the positive angle (U +) of the stabilizer (24), the oscillator (16), the splitter (17), the storage (18), the gating circuit (19), the program memory (14), the microprocessor (13) and the switch. (26) is connected to its power supply inputs. Apparatus according to claim 3, characterized in that the first and second inputs of the gating circuit (19) are connected to the gating circuit (19) via a signal receiver (20), while the third input of the gating circuit (19) can be interrupted by a switch (21). a wire connected to the positive corner (U +) of the stabilizer (24).