KR101385243B1 - Feul flow monitoring apparatus and system - Google Patents

Abstract

A fuel flow monitoring device and a fuel flow monitoring system are provided. According to embodiments of the present invention, it is possible to more reliably monitor the modulation of the pulse signal input from the pulse generator during the fueling operation and the amount of fuel flow rate calculated and displayed from the fueling controller, and through the communication network when the monitoring result is forged or the modulation is confirmed. By real-time reporting to higher certification agencies or direct verification from a short-range portable terminal, real-time monitoring of gas flow tampering is possible, more systematic management can be achieved, and gasoline monitoring and management costs can be reduced.

Description

FEUL FLOW MONITORING APPARATUS AND SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel flow monitoring device and a fuel flow monitoring system. In particular, the fuel flow monitoring implemented to more reliably detect a modulation of a pulse signal and a display modulation of a fuel flow, and transmit the detected result to a higher level engine to prevent subsequent modulation. A device and fuel flow monitoring system.

The lubricator performs the test at the national level with a statutory meter in accordance with the Law on Metering. This test uses a method of measuring the flow rate discharged from the lubricator and comparing it with the value displayed on the display device of the lubricator, or by physically sealing the train control unit that can change the lubrication value according to the standards set by law. Use the method.

In general, the configuration of the lubricator, as shown in Figure 1, is attached to the side of the lubrication main body 16, the line 8 for injecting oil into the fuel tank of the vehicle, and the nozzle 8 has been spaced apart from the nozzle hanger The pump 6 for sucking the oil stored in the underground oil tank through the pipe 13 of the lower end of the lubricator main body 16 receives the rotational force of the motor 15 from the nozzle switch and V belt 14 to detect this when , A flow meter 5 which is installed directly on the top of the pump 6 and discharges the oil sucked by the pump 6 to the hose 12 connected to the nozzle 8 when the nozzle lever 10 is pulled out. And a pulse generator 4 installed at an upper end of the flow meter 5 and connected by a shaft to generate a pulse as the flow meter 5 rotates, and a pulse generator installed at an upper portion of the oil main body 16. The pulse inputted from (4) is counted to increase the amount (\) and the flow rate (ℓ). An arithmetic and control unit 2 for calculating and storing, a money amount and flow rate data output from the arithmetic and controlling unit 2, a display unit 1 for displaying various messages, a power supply unit for supplying power to each component, and various data It consists of a key input device (7) that can set, input and inquire.

In this way, the lubricator is composed of a pulse generator and a lubrication controller that can detect the flow of oil largely, in more detail, the flow meter of the lubricator rotates as the lubrication is performed, the pulse generator is connected to the rotating shaft It consists of an encoder rotary slit that generates pulses while rotating according to the flow of oil, and a transmission driver that transmits the detected pulse signal, and the oil supply controller is configured to calculate the flow rate using the receiver driver and the pulse signal receiving the pulse signal. It is composed of fueling controller (CPU).

Referring to the specific operation of the lubricator having the configuration as described above, when the lubrication is started first, the flow meter is rotated in accordance with the flow of oil, accordingly the encoder rotation slit of the pulse generator connected to the flow meter rotates to detect the pulse signal The detected pulse signal is transmitted to the receiving driver of the fueling controller without any change or modulation by the transmitting driver. The received pulse signal is calculated by the fueling controller (CPU) as the weighing volume and the price and output to the display device.

As such, the signal transmission between the controller of the lubricator and the flow sensor (pulse generator) has a simple structure in which the signal detected by the sensor is simply transmitted. Therefore, a simple device is connected to the flow sensor, the connecting line, or the connecting terminal of the lubrication controller. By inserting, the detected pulse signal can be easily forged or modulated.

In addition, the fueling controller may forge or modulate the oiling amount displayed in such a manner that the oiling amount displayed on the display device of the oiler is larger than the actual oiling amount by inputting an illegal coefficient or modifying a program. On the other hand, in such a case, the upper supervisory authority has a problem that it is difficult to confirm the forgery or tampering.

Accordingly, embodiments of the present invention monitor the display of the pulse signal input from the pulse generator and the fuel flow rate calculated by the fuel oil controller, and compare the actual fuel flow value calculated based on the oil pump's own pulse type and the unique reference volume value. The purpose of the present invention is to provide a gas flow monitoring device and a gas flow monitoring system, which makes it possible to more reliably monitor whether the gas flow is forged or tampered with, and to immediately stop the operation of the gas tanker when the forgery or tamper is confirmed and immediately report it to a higher authority. have.

The fuel flow monitoring apparatus according to an exemplary embodiment of the present invention detects a phase input sequence of a pulse signal generated according to the flow of oil in the lubricator, a number of pulses input per rotation of the encoder rotation slit, and a duty ratio of a pulse waveform, Pulse signal monitoring means for monitoring whether or not the input pulse signal is modulated and a failure of the pulse generator in comparison with a preset reference value; Display monitoring means for monitoring whether or not the display is tampered with by comparing the display of the final discharge oil amount calculated by the controller of the lubricator with the oil amount calculated according to a prestored unique volume per pulse value; Control means for receiving the monitoring results of the pulse signal monitoring means and the display monitoring means and stopping the lubrication operation of the lubricator and recording the corresponding monitoring history information when it is determined that the signal or the display is modulated or the failure of the apparatus; Communication means for transmitting the monitoring history information to an external device via a communication network; .

In one embodiment, the fuel flow monitoring device, the unique ID of the lubricator, the volume value per unique pulse of the lubricator, the inspection history information of the lubricator, the monitoring history information of the pulse signal monitoring means and the display monitoring means time information The storage means for encrypting and storing together with the.

In one embodiment, the control means, if the phase of the pulse signal input to the pulse signal monitoring means includes a z phase, the signal if the number of phases a and b input per one z phase is inconsistent with a predetermined number It is determined that the modulation or the failure of the device, the oiling operation of the lubricator is stopped and corresponding monitoring history information is recorded.

In one embodiment, the control means, if the phase of the pulse signal input to the pulse signal monitoring means does not include a phase z, at least one of the phase a and phase b is the modulation or apparatus of the signal Determination of the failure, characterized in that for stopping the lubrication operation of the lubricator and to record the corresponding monitoring history information.

In one embodiment, the communication means, characterized in that for transmitting the encrypted monitoring history information stored in the storage means to the authenticated external device.

In one embodiment, the fuel flow monitoring device further comprises: an operation monitoring means for monitoring the fueling start and end signals of the lubricator and providing it to the control means, wherein the control means is connected to a signal received from the operation monitoring means. Determine the operation of the fuel flow monitoring device according to the present invention.

In one embodiment, the fuel flow monitoring device, characterized in that it further comprises a connector disconnection monitoring means for monitoring the connection of the connector connecting the lubricator and the fuel flow monitoring device, and recording the separated time when disconnecting the connection. .

In one embodiment, when disconnection of the connector is detected from the connector disconnection monitoring means, the control means stops the oiling operation of the lubricator and records corresponding monitoring history information together with the separated time. .

In one embodiment, the control means, when receiving the monitoring results of the pulse signal monitoring means and the display monitoring means and judges that the signal or display modulation or failure of the device, the oiling operation of the lubricator is stopped and the alarm signal It generates and outputs.

In one embodiment, the fuel flow monitoring device, characterized in that it further comprises an internal power supply means for supplying power to the internal components of the fuel flow monitoring device, when the power applied to the fuel flow monitoring device is cut off.

In addition, the fuel flow monitoring system according to an embodiment of the present invention, a pulse signal generator which is provided between the end of the lubricator hose and the nozzle to generate a pulse signal in accordance with the flow of oil, and receives the detected pulse signal to calculate the discharge lubrication flow rate A lubrication controller including a lubrication controller, an indicator for displaying the discharge lubrication amount calculated by the lubrication controller, and a connector connecting the lubricator and an external device; Connected via the connector, the phase input sequence of the pulse signal input from the pulse signal generator, the number of pulses input per revolution of the encoder, and the duty ratio of the pulse waveform are monitored and inconsistent with a predetermined reference value, or the indication of the indicator A lubricator monitor for generating a control signal for stopping operation of the lubricator and providing it to the lubrication controller when a mismatch with the lubrication amount calculated according to the volume value per intrinsic pulse of the lubricator; And a remote device for receiving the monitoring result of the gasoline monitoring unit and displaying and storing a history of the monitoring result through a communication network.

In one embodiment, the lubricator monitor, if the phase of the input pulse signal includes a z-phase, detects the number of a phase and b phase input per one z phase to stop the operation of the lubricator if it does not match the predetermined number And generating a control signal.

In one embodiment, the lubricator monitor generates a control signal to stop the operation of the lubricator if at least one of a phase and b phase is continuously input if the phase of the input pulse signal does not include a z phase It features.

In an embodiment, the lubricator monitor may include a unique ID of the lubricator, a volume value per unique pulse of the lubricator, calibration information of the lubricator, monitoring results of a pulse signal input from the pulse signal generator, and And a memory for encrypting and storing the display monitoring result together with the time information.

According to the fuel flow monitoring device and the fuel flow monitoring system according to an embodiment of the present invention, it is possible to more reliably monitor the modulation of the pulse signal input from the pulse generator during the fueling operation and the amount of fuel flow rate calculated and displayed by the fuel controller, When reporting forgery or tampering, it is possible to immediately report to the higher certification authority through the communication network or to check directly from a mobile terminal in a short distance, enabling real-time monitoring of gas flow modulation and more systematic management. This has the effect of being saved.

1 is a view showing the configuration of a general lubricator;
2 is a block diagram showing a detailed configuration of a fuel flow monitoring system according to an embodiment of the present invention;
3 is a schematic diagram showing a flow rate calculation and display process of a general lubricator;
4 is a schematic diagram showing a flow rate calculation, display, and monitoring process of the fuel flow monitoring system according to an embodiment of the present invention;
5 is a flowchart illustrating an exemplary operation of a fuel flow monitoring apparatus according to an exemplary embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail the flow measuring system and flow rate data security method of the lubricator according to the embodiments of the present invention.

First, referring to Figure 2, the detailed configuration of the fuel flow monitoring system according to an embodiment of the present invention will be described. The fuel flow monitoring system may include a gas pump 100, a fuel flow monitoring device 200 connected to the fuel pump 100 through one or more connectors, and an external device that performs wired / wireless communication with the fuel flow monitoring device 200 ( 300).

The lubricator 100 is discharged from the lubricator 100 based on the volume generator per pulse and the pulse generator 110 to generate a pulse signal by rotating the encoder rotary slit provided when the lubrication operation is started The controller 130 may calculate a final oil supply amount and a price corresponding thereto, and an indicator 150 for displaying the oil supply amount, the price, and the unit price calculated by the controller. The lubricator 100 is connected to the lubrication flow rate monitoring device 200 through one or more connectors to exchange pulse signals, calculation data, and the like.

The fuel flow rate monitoring apparatus 200 includes a pulse signal monitoring means 210, a display monitoring means 220, a connector disconnecting monitoring means 230, a fueling operation monitoring means 280, a control means 250, and a communication means 270. , Storage means 240 and encryption block 245, and power supply means 290.

The pulse signal monitoring means 210 is a phase input sequence of the pulse signal generated according to the flow of the oil of the lubricator 100, the number of pulses input per rotation of the encoder rotation slit, and the duty of the pulse waveform for the pulse signal Detect rain.

In addition, the pulse signal monitoring means 210 compares the detected phase input order, the number of pulses input per revolution of the encoder rotation slit, and the duty ratio of the pulse waveform with a predetermined reference value, thereby modulating the input pulse signal. And the failure of the pulse generator 110 is monitored. The signal of the monitoring result of the pulse signal monitoring means 210 is transmitted to the control means 250, and the control means 250 finally determines whether the pulse signal is modulated or the device is broken.

The display monitoring means 220 is provided to the control means 250 in accordance with the display of the final discharge oil flow rate calculated by the controller 210 of the oil dispenser 200 and the volume value per pulse unique to the oil dispenser stored in advance. The lubrication flow rate computed is compared with each other. The volume value per pulse unique to the lubricator is pre-encrypted and stored in the storage means 240, and the comparison result of the display monitoring means 220 is transmitted to the control means 250 as data for determining whether or not the display of the fuel oil level is modulated. Is provided.

The connector disconnection monitoring unit 230 monitors the connection of the connector connecting the lubricator 100 and the lubrication flow rate monitoring apparatus 200. In addition, the connector disconnection monitoring means 230 includes a time generator (not shown) for recording the disconnected or disconnected time when the connector is disconnected or disconnected.

The fueling operation monitoring means 280 monitors the fueling start and end signals of the oiler 100 and transmits the start or end signal to the control means 250.

The control means 250 receives a signal of the monitoring result transmitted from the pulse signal monitoring means 210 and / or the display monitoring means 220 to determine whether a device, including a signal or display modulation or a pulse generator, has failed. Final judgment

Specifically, the control means 250 is a case where the phase of the pulse signal input to the pulse signal monitoring means 210 includes a z-phase, the number of phases a and b input per one z phase is inconsistent with the predetermined number of pulses It is determined by the modulation of the pulse signal or the failure of the pulse generator.

 The control means 250 modulates the pulse signal when the phase of the pulse signal input to the pulse signal monitoring means 210 does not include a z phase and at least one of a phase and b phase is continuously input. Alternatively, it is determined that the pulse generator has failed.

The control means 250 stops the lubrication operation of the lubricator 100 and records corresponding monitoring history information when it is determined that the device including the modulation of the signal or the display or the pulse generator has failed.

In addition, the control means 250 determines the operation of the fuel flow monitoring device according to the signal received from the operation monitoring means 280. That is, when the fueling operation start signal is received from the operation monitoring means 280, the control means 250 starts operation of the pulse signal monitoring means 210, the display monitoring means 220, and the connector disconnection monitoring means 230. Send order

The storage means 240 encrypts and stores a unique ID, a unique volume value per pulse, and test history information, which are assigned at the time of manufacturing the lubricator for the lubricator 100. In addition, the storage means 240 encrypts and stores the monitoring history information of the pulse signal monitoring means 210 and the display monitoring means 220 in the encryption block 245 together with the time information.

In addition, when the storage means 240 detects that the connector connecting the lubricator 100 and the lubrication flow rate monitoring device 200 is disconnected by the connector disconnection monitoring means 230, the storage means 240 encrypts the information together with time information. Save it. Here, the encryption method of the encryption block 245 may be an encryption method using, for example, an international standard encryption algorithm of a symmetric key method such as AES (Advanced Encryption Standard), DES (Data Encryption Standard), SEED, and the like.

The storage means 240 may encrypt and store different pulse types, operation switch types, display methods, etc. for each lubricator. In addition, the storage means 240 may encrypt and store a record related to the test at the time of the lubricator test, for example, the date and time of the test, the schedule of re-testing, the person who performed the test, and the like.

The storage means 240 decrypts and stores the encrypted data through the encryption block 245.

In addition, the storage means 240 may be provided outside the fuel flow monitoring device 200. In this case, for example, it may be a nonvolatile memory such as RAM, ROM, Flash Memory, or the like.

The communication means 270 transmits the monitoring history information provided from the control means 250 to an external device through a communication network. In addition, the communication means 270 may transmit encrypted monitoring history information stored in the storage means 240 to an authenticated external device.

Here, the external device 300 may be a system of a higher authority that monitors and supervises a plurality of lubricators 100, and / or may include a mobile terminal. In addition, the external device 300 may be provided with a communication port, the open port can be implemented to communicate only to the external device authorized through an encryption algorithm to protect it.

When the external device 300 is a mobile terminal, for example, when the communication means 270 of the fuel flow monitoring apparatus 200 does not perform a normal operation, it may use short-range wireless communication such as Wi-Fi or Zigbee communication. The encrypted monitoring history information may be received through a mobile terminal (not shown) proximate to the fuel flow monitoring apparatus 200.

In this case, the portable terminal may be a terminal registered in advance or a terminal approved through input of an administrator's authentication number. According to this, even when monitoring history information is not temporarily transmitted to the upper level organization, it is possible to immediately identify which gas station forged or modulated when.

The power supply means 290 supplies power to internal components when the power applied to the gas flow rate monitoring device 200 is cut off. Accordingly, even when power is not supplied to the fuel flow rate monitoring apparatus 200, the operation of the oil pump 100 and the fuel flow rate display may be continuously monitored.

As described above, the fuel flow monitoring system according to the exemplary embodiment of the present invention may monitor the pulse generator and the lubricator controller in real time through a communication network, and may immediately stop the operation of the lubricator when the forgery occurs.

In addition, according to the fuel flow monitoring system, it is possible to immediately report the gas forgery forgery of the fueling machine to the certification management authority through the connected communication network network, and if the communication network is not provided or a failure occurs, the forgery history is immediately transmitted through the portable terminal. You can check it. Accordingly, it is possible to easily perform fair trade and verification management by preventing inherent fraud and tampering in advance and securing a basis for fraud even after the fact.

3 is a flow chart illustrating a flow rate calculation and display process of a general lubricator. The fuel pump of FIG. 3 consists of a fragmentary signal for transmitting a signal between the lubricator controller 130 and the pulse generator 110 to simply transmit the detected signal of the sensor, thereby modulating the signal by inserting a simple device into the connection terminal. It was also possible to modulate the display 150 of the result of the operation by adding a specific variable value to the operation through program change.

On the other hand, Figure 4 shows the flow rate calculation, display, and monitoring process of the fuel flow monitoring system according to an embodiment of the present invention for monitoring the modulation as described above.

When the operation operation switch 170 of the lubricator is turned on and the lubrication operation is started, the lubrication flow rate monitoring apparatus 200 receives the lubrication start signal and recognizes that the lubrication operation is started.

The pulse signal generated from the pulse generator 110 according to the flow of the oil of the lubricator is input to the lubrication flow rate monitoring apparatus 200. The pulse signal may include only a phase and b phase and may include a phase, b phase and z phase depending on the manufacturer or type of lubricator. In the fuel flow monitoring apparatus 200, the number of unique pulses per rotation of the encoder rotation slit of the connected gasoline, the format of the pulse signal, and the pulse waveform are encrypted and stored in advance.

In the case where the phase of the pulse signal input to the fuel flow monitoring apparatus 200 includes the z phase, the number of a phases and b phases input per one z phase is detected to monitor whether or not the number corresponds to a preset number. Moreover, when the phase of the pulse signal input to the fuel flow monitoring apparatus 200 does not contain a z phase, it monitors whether at least any one of a phase and b phase is continuously input. That is, since the a-phase and the b-phase are alternately input to the input pulse signal, when monitoring whether one of the a-phase and the b-phase is continuously inputted, it is determined whether the pulse generator 110 is broken or whether the generated pulse signal is modulated. Able to know. In FIG. 4, a pulse type in which only a and b phases are input is shown as an example.

The controller 130 of the lubricator receives the pulse number of the pulse signal, calculates the discharge lubrication amount calculated based on the volume value per pulse of the lubricator, and calculates the corresponding price. The calculation result is transmitted to the fuel flow rate monitoring apparatus 200 through the connector, and the calculated fuel flow rate and price are displayed on the indicator 150 of the gas pump.

On the other hand, the fuel flow rate monitoring device 200 receives a value calculated by the controller 130 of the lubricator, and based on the number of pulses of the input pulse signal and the volume value per pulse uniquely encrypted and stored in advance, Calculate internally Then, the fuel flow monitoring device 200 compares the value received from the controller 130 of the fueling machine, that is, the fuel flow rate displayed on the display 150 with the value calculated inside the fuel flow monitoring device 200. If the displayed value and the value calculated inside the fuel flow monitoring apparatus 200 do not coincide with each other, it may be determined as forgery or modulation of the fuel flow rate.

As described above, the fuel flow monitoring apparatus 200 receives signals or data transmitted from the pulse generator 110, the controller 130, and the indicator 150 of the fuel tanker, compares the reference value with the reference value, and determines whether to modulate it. During modulation, the fuel flow monitoring apparatus 200 provides the controller 130 with a stop signal of the fueling operation to forcibly stop the operation of the fueling machine. In addition, the fuel flow monitoring apparatus 200 records the modulation and error occurrence details and stores them in an internal memory.

In addition, the fuel flow monitoring apparatus 200 may immediately monitor and report the monitoring result and the history information of the fueling machine to one or more external devices, for example, a higher monitoring organization or a portable terminal in a short distance through a communication network.

In addition, the fuel flow monitoring device 200 encrypts the value of the sold fuel flow rate and time information of the built-in RTC (Real Time Clock, RTC module) every time the fueling is completed, stored in the internal memory and stored information from the external device If there is a request for provision, the encrypted data can be transmitted with the corresponding encryption key.

In addition, the fuel flow monitoring apparatus 200 may perform an automatic notification procedure with information including the contents and the date and time of the modification of the fuel tanker to the upper supervisory authority.

5 is a flowchart illustrating an exemplary operation of a fuel flow monitoring apparatus according to an exemplary embodiment of the present invention.

First, the oil flow rate monitoring apparatus monitors whether an operation start signal of the oil tanker is received, and monitors whether the connector connection with the oil tanker is normal (S10). As lubrication of the lubricator starts, a pulse signal is generated while the encoder rotation slit of the lubricator rotates. The generated pulse signal is input to the fuel flow monitoring device, which continuously monitors the phase input sequence of the input pulse signal, the number of pulses per revolution of the encoder rotating slit, and the duty ratio of the waveform of the pulse signal. (S20).

The phase of the input pulse signal includes a phase, b phase, and z phase, and is implemented to include only a phase and b phase depending on the type of lubricator.

Specifically, when the phase of the input pulse signal includes the z phase, the number of a phases and b phases input per one z phase is detected to monitor whether or not the number corresponds to a preset number. Since the number of pulses per revolution of the encoder rotating slit is predetermined according to the manufacturer of the lubricator, the number of a phase and b phase input per one phase of the z phase can be detected to determine whether the pulse number is manipulated. That is, since the number of a phase and b phase to be input per one phase of z phase has a predetermined value, it is possible to determine whether the number of pulses has been modulated by monitoring whether this value is exceeded.

On the other hand, when the phase of the input pulse signal does not include the z phase, it is monitored whether at least one of the a phase and the b phase is continuously input. That is, when the z phase is not included, since the a phase and the b phase of the pulse signal are always input in sequence, it is possible to determine whether the number of pulses is modulated by monitoring whether one of the a phase and the b phase is continuously input. For example, if a phase is missing or b phase is continuously input in the form of a phase, b phase, a phase, b phase, b phase ...., it is judged as modulation of pulse number or failure of pulse generator. .

In addition, it is possible to monitor the waveform of the input pulse signal to set the pulse period ratio, and to monitor whether the set period ratio is exceeded to determine whether the pulse signal is modulated. For example, when a phase and b phase are input at the same time in the pulse generator of the lubricator without z phase, the duty ratio of the waveform of the pulse signal is monitored, and when the duty ratio of the same waveform exceeds the reference value, it can be determined as modulation of the pulse signal. .

In addition, the fuel flow monitoring apparatus monitors whether or not the display of the fuel flow rate is modulated by comparing the final discharge fuel flow rate displayed on the display of the fueling machine with the fuel flow rate calculated based on a volume value per pulse unique to the fueling machine by the controller of the fueling flow monitoring device (S30). ). In other words, there was no operation on the input pulse signal, but the operation of the lubricator controller calculates the final discharge lubrication flow rate and manipulates a specific variable value or changes the calculation program so that the discharge lubrication amount displayed on the display of the lubricator is displayed more than actually. Watch. To this end, the fuel flow monitoring apparatus may encrypt and store in the internal memory a volume value per pulse unique to the fuel tanker, a unique ID assigned at the time of manufacturing the fuel tanker, which is the basis of the fuel flow rate calculation. In addition, the fuel flow monitoring device may further include a display unit (not shown) for displaying the actual fuel flow rate calculated based on the input pulse signal and the unique volume value per pulse.

As a result of the comparison in step S30, it is determined whether or not the oil level displayed on the indicator of the oil tanker matches the oil level calculated by the oil level monitoring device (S40). Wait for reception. On the other hand, if the determination result (S40) is inconsistent with the fuel flow rate and the fuel flow rate calculated by the fuel flow monitoring device, it is determined that more than the actual fuel flow rate is displayed on the display of the fuel tanker to generate a signal for stopping the fueling operation of the fueling machine and related The history information is stored (S50). The signal can be transmitted to the controller of the lubricator via a connector, whereby the lubrication operation of the lubricator is forcedly stopped. If necessary, an alarm signal for notifying the gas flow rate modulation to the outside may be output through the screen output means or the sound output means. In addition, the history information may include, for example, time information when it is determined to be modulation, related data, past history information, and the like, and the history information is encrypted and stored so as not to be modulated or forged.

As a result of the monitoring and determination performed by the fuel flow monitoring device, history information and the like are transmitted to an external monitoring device through a wired / wireless communication network (S60). In addition, the external monitoring device may directly request the fuel flow monitoring device to transmit such history information, or may retransmit the received history information to another higher monitoring organization.

As described above, according to the fuel flow monitoring device and the fuel flow monitoring system according to the embodiment of the present invention, it is possible to more reliably determine whether the modulation of the pulse signal input from the pulse generator during the fueling operation and the fuel flow rate calculated and displayed by the fuel controller are modulated. It can be monitored in real time and can be directly reported to the upper certification authority through the communication network when the monitoring result is forged or forged. As a result, the cost of monitoring and managing the fueling machine can be reduced. In addition, the fuel flow monitoring device and the fuel flow monitoring system according to an embodiment of the present invention can easily perform the assay management, without the need to change the existing oil tanker or seal the entire product.

As described above, according to the fuel flow monitoring device and the fuel flow monitoring system according to the embodiments of the present invention, it is possible to more accurately determine whether the modulation of the pulse signal input from the pulse generator and the fuel flow rate calculated and displayed by the fuel controller during the fueling operation. Real-time monitoring of gas flow tampering is possible and more systematic management is possible by implementing it so that it can immediately report to the upper certification authority through the communication network or check directly from the mobile terminal in case of monitoring or forgery or forgery of the monitoring result. Lubricator monitoring and management costs can be reduced.

Furthermore, it will be understood by those skilled in the art that the present invention may be implemented in other specific forms without changing the technical spirit or essential features of the present invention. It is therefore to be understood that the above-described embodiments are illustrative and non-restrictive in every respect. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

100-Lubricator 110-Pulse Generator
130-lubrication controller 150-indicator
200-fuel flow monitoring device 210-pulse signal monitoring means
220-indicator monitoring means 230-connector disconnection monitoring means
240-storage means 245-encryption blocks
250 Control means 270 Communication means
280-Oiling motion monitoring means 290-Power supply means
300-external device

Claims (14)

The phase input sequence of the pulse signal generated according to the flow of oil of the lubricator, the number of pulses input per revolution of the encoder rotation slit, the duty ratio of the pulse waveform are detected and compared with a preset reference value to determine the Pulse signal monitoring means for monitoring the modulation and whether the pulse generator has failed;
Display monitoring means for monitoring whether or not the display is modulated by comparing the display of the final discharge fuel flow rate calculated by the controller of the gas tanker with the fuel flow rate calculated according to a prestored unique volume per pulse value;
Control means for stopping the lubrication operation of the lubricator and recording corresponding monitoring history information upon determining that the pulse signal monitoring means and the monitoring result of the display monitoring means are judged to be a signal or display modulation or a failure of the apparatus; And
Communication means for transmitting the monitoring history information to an external device via a communication network; / RTI >
Wherein,
If the number of a phase and b phase of the generated pulse signal is inconsistent with a preset number or if either of the a phase and b phase is input continuously according to the prestored pulse type of the lubricator, and When the a-phase and the b-phase are input at the same time, when the duty ratio of the pulse waveform exceeds the reference value, it is determined that the pulse signal modulation or the failure of the device,
If the communication means does not perform a normal operation, it is possible to receive the encrypted monitoring history information from the portable terminal in close proximity to the lubricator by using short-range wireless communication,
Gas flow monitoring device. The method according to claim 1,
The unique ID of the lubricator, the volume value per unique pulse of the lubricator, the pulse format of the lubricator, the verification history information of the lubricator, and the monitoring history information of the pulse signal monitoring means and the display monitoring means are encrypted and stored together with time information. Further comprising a storage means;
Gas flow monitoring device. delete delete 3. The method of claim 2,
The communication means,
Characterized in that for transmitting the encrypted monitoring history information stored in the storage means to an authenticated external device,
Gas flow monitoring device. The method according to claim 1,
Motion monitoring means for monitoring the fueling start and end signals of the fueling machine and providing them to the control means;
The control means determines the operation of the fuel flow monitoring apparatus according to a signal received from the motion monitoring means,
Gas flow monitoring device. The method according to claim 1,
And a connector disconnection monitoring means for monitoring a connection of a connector connecting the oil supply device to the fuel flow rate monitoring device and recording a time separated when the connection is disconnected.
Gas flow monitoring device. The method of claim 7, wherein
When the disconnection of the connector is detected from the connector disconnection monitoring means, the control means stops the oiling operation of the lubricator and records corresponding monitoring history information together with the separated time,
Gas flow monitoring device. The method according to claim 1,
Wherein,
Receiving the monitoring results of the pulse signal monitoring means and the display monitoring means, if it is determined that the signal or display modulation or failure of the device, it is characterized in that the lubrication operation of the lubricator is stopped and generates and outputs an alarm signal,
Gas flow monitoring device. The method according to claim 1,
When the power applied to the gas flow rate monitoring device is cut off, the internal power supply means for supplying power to the internal components of the gas flow rate monitoring device; characterized in that it further comprises,
Gas flow monitoring device. A pulse signal generator provided between the end of the lubricator hose and the nozzle to generate a pulse signal according to the flow of oil, a lubrication controller for receiving the detected pulse signal and calculating a discharge lubrication amount, and a discharge lubrication amount calculated through the lubrication controller. An lubricator including an indicator for displaying a connector and a connector for connecting a lubricator and an external device;
Connected via the connector, the phase input sequence of the pulse signal input from the pulse signal generator, the number of pulses input per revolution of the encoder rotation slit, and the duty ratio of the pulse waveform are monitored and compared with a preset reference value; The display of the indicator is compared with the fuel flow rate calculated according to the volumetric pulse value of the lubricator, and when it is determined that the signal or the display is modulated or a failure of the device is generated, a control signal for stopping the operation of the lubricator is generated and provided to the lubrication controller. Providing lubricator monitor; And
And a remote device receiving a monitoring result of the gasoline monitoring unit and displaying and storing a history of the monitoring result through a communication network.
The lubricator monitor,
If the number of a phase and b phase of the generated pulse signal is inconsistent with a preset number or if either of the a phase and b phase is input continuously according to the prestored pulse type of the lubricator, and When the a-phase and the b-phase are input at the same time, when the duty ratio of the pulse waveform exceeds the reference value, it is determined that the pulse signal is a modulation or a failure of the device,
If the remote device does not perform a normal operation, it is possible to receive the encrypted monitoring history information from the portable terminal in close proximity to the lubricator using short-range wireless communication,
Fuel flow monitoring system. delete delete The method of claim 11,
The lubricator monitor,
The unique ID of the lubricator, the volume value per unique pulse of the lubricator, the pulse type of the lubricator, the calibration information of the lubricator, the monitoring result of the pulse signal input from the pulse signal generator, and the display monitoring result of the indicator. And a memory for encrypting and storing the time information together.
Fuel flow monitoring system.

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