JP2006027659A - Fuel supply system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fuel supply system which detects operator's touching a static eliminating sheet and allows liquid feeding. <P>SOLUTION: In the fuel supply system 10, a fuel feeding request signal is put out to a fuel feeding work monitor 20 under the condition that the removal of a fuel feeding nozzle from a nozzle hook is detected and operator's touching the static eliminating sheet is detected via a static eliminating detection switch as well. This prevents such a trouble that a fuel feeder 16 does not feeds fuel despite of output of a liquid feeding permission signal. The supply system 10 maintains conventional signal exchange between a POS device 21 and the fuel feeder 16 as it is, allowing newly devised operation to be executed without changing the conventional structure of the POS device 21. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a fuel supply system, and in particular, the fuel supply is prohibited when an operator who supplies fuel operates in a statically charged state, and the fuel is supplied when the operator performs an operation for removing static electricity. Relates to a fuel supply system configured to be permitted.

  For example, in a fuel supply system that supplies fuel such as gasoline to a fuel tank of an automobile, there is a tendency to install a self-service type liquid feeder (fuel supply machine including a meter and a setting device). In such a self-service liquid supply station, the driver himself is the operator who performs the liquid supply operation. Therefore, after the vehicle is stopped in the liquid supply area, the driver gets out of the driver's seat and supplies water. Remove the nozzle from the nozzle hook of the liquid machine and insert it into the fuel tank's liquid supply port. When a liquid supply (supply) request signal is output from the liquid supply machine to the POS device installed in the office of the liquid supply station, the staff in the office checks the monitor of the surveillance camera and the liquid supply A liquid supply (supply) permission signal is output to the machine. As a result, the pump of the liquid feeder that has output the liquid supply request signal is activated to supply liquid by the nozzle (for example, see Patent Document 1).

  Before inserting the nozzle of the liquid feeder into the liquid supply port, the cap that closes the liquid tank's liquid supply port will be removed, but if the operator is charged with static electricity, the cap is removed from the liquid supply port. Since there is a possibility of igniting vapor (oil vapor) ejected from the liquid supply port when removed, the operator needs to remove static electricity before operation. In particular, in the case of the self-service method, when the driver gets out of the driver's seat, clothes are likely to be rubbed against the driver's seat and become charged with static electricity, so the driver must be careful about removing static electricity.

Therefore, when the driver touches the static electricity removal sheet provided on the liquid feeder, the applicant can input the liquid supply information by the setting device, and the driver does not touch the static electricity removal sheet. In some cases, a fuel supply system has been proposed that does not accept liquid supply information input operations and does not allow liquid supply (see, for example, Patent Document 2).
JP 2000-168900 A Japanese Patent Application No. 2002-368368

  In the fuel supply system described in Patent Document 1, the signals exchanged between the POS device and the liquid feeder are (1) a fuel supply request signal, (2) a fuel supply permission signal, and (3) a fuel supply data signal. Since there are three types, when the static electricity removal sheet described in Patent Document 2 is combined with the fuel supply system described in Patent Document 1, the following problems may occur.

  That is, when the technique of the above-mentioned patent document 2 is simply combined with the technique of the above-mentioned patent document 1, when the nozzle is taken from the liquid feeder, a liquid feed request signal is output from the liquid feeder to the POS device, The POS device is configured to output a liquid supply permission signal in response to the input of this signal. Therefore, if the operator (driver) who supplies liquid removes the nozzle from the nozzle hook without touching the static electricity removing sheet, a supply permission signal is output from the POS device even though the static electricity removing sheet is not touched. Will be.

  However, in the fuel supply system described in Patent Document 2, since the static electricity removing sheet is not touched, the pump of the liquid feeder is not started and fuel supply cannot be performed. On the other hand, on the POS device side, although the liquid supply permission signal is output to the liquid feeder, fuel supply cannot be performed in the liquid feeder because the input operation by the setting device cannot be performed. Become. For this reason, the staff operating the POS device cannot understand why the fuel cannot be supplied.

  Accordingly, an object of the present invention is to provide a fuel supply system that solves the above problems.

The invention described in claim 1 is a nozzle inserted into a supply port of a fuel supply body to which fuel is supplied, a nozzle storage portion in which the nozzle is stored when the nozzle is not used, and the nozzle is stored in the nozzle. A nozzle storage detecting means for detecting whether or not the fuel has been removed from the part, a fuel supply means for supplying the fuel to the fuel supply body through the nozzle, and the nozzle being removed by the nozzle storage detection means. Is detected, a supply request signal output means for outputting a supply request signal for starting fuel from the nozzle, and the supply means is driven by the input of the supply permission signal to supply the fuel to be supplied from the nozzle. A fuel supply machine comprising: control means for enabling supply of fuel to the body; and supply amount measuring means for measuring the supply amount of fuel supplied from the nozzle and outputting the supply amount
Connected to the fuel supply unit via a communication line, obtains information on the fuel supplied by the fuel supply unit from the fuel supply unit, performs tabulation management, and supplies it from a supply request signal output unit of the fuel supply unit A POS device that outputs a supply permission signal to permit fuel supply from the nozzle when a request signal is input;
A fuel supply system comprising:
Static electricity removing means provided in the fuel supply machine for removing static electricity charged to an operator who supplies fuel, and static electricity removing detecting means for detecting that the operator has contacted the static electricity removing means. The supply request signal output means detects that the nozzle has been removed by the nozzle storage detection means, and has detected that the operator has touched the static electricity removal means by the static electricity removal detection means. The supply request signal is output on condition that this is the case.

According to a second aspect of the present invention, a nozzle inserted into a supply port of a fuel-supplied supply body to which fuel is supplied, a nozzle storage portion in which the nozzle is stored when the nozzle is not used, and the nozzle is stored in the nozzle A nozzle storage detecting means for detecting whether or not the fuel has been removed from the part, a fuel supply means for supplying the fuel to the fuel supply body through the nozzle, and the nozzle being removed by the nozzle storage detection means. Is detected, a supply request signal output means for outputting a supply request signal for starting fuel from the nozzle, and the supply means is driven by the input of the supply permission signal to supply the fuel to be supplied from the nozzle. A fuel supply machine comprising: control means for enabling supply of fuel to the body; and supply amount measuring means for measuring the supply amount of fuel supplied from the nozzle and outputting the supply amount
Connected to the fuel supply unit via a communication line, obtains information on the fuel supplied by the fuel supply unit from the fuel supply unit, performs tabulation management, and supplies it from a supply request signal output unit of the fuel supply unit A POS device that outputs a supply permission signal to permit fuel supply from the nozzle when a request signal is input;
A display unit provided between the fuel supply unit and the POS device, for displaying an operating status of the fuel supply unit, and a supply permission switch operated when permitting fuel supply to the fuel supply unit; And a supply permission signal for permitting the supply of fuel from the nozzle to the fuel supply body, provided that a supply permission signal is input from the POS device when the supply permission switch is operated. A second supply permitting means, and a supply work monitoring device comprising:
A fuel supply system comprising:
The fuel supply machine detects the contact of the operator with the static electricity removing means for removing the static electricity charged to the operator when the operator who supplies the fuel contacts, and monitors the supply work. Static electricity removal detection means for outputting a static electricity removal signal to the apparatus, wherein the supply request signal output means is a supply request signal when the nozzle storage detection means detects that the nozzle has been removed. When the static electricity removal signal is output from the fuel supply device, the supply work monitoring device displays that the static electricity has been removed on the display means, and the supply permission switch is operated. A supply request signal is output from the fuel supply unit, a static electricity removal signal is output from the static electricity removal means, and a supply permission signal is output from the POS device. In the conditions, characterized in that for outputting a supply permission signal to the fuel supply device in order to supply the fuel from the nozzle.

  According to the first aspect of the present invention, on condition that the nozzle removal detecting means detects that the nozzle has been removed, and the static electricity removal detecting means detects that the operator has touched the static electricity removing means. Since the supply request signal is output, it is possible to prevent the fuel supply unit from supplying fuel despite the supply permission signal being output, and the conventional POS device and the fuel supply unit can be prevented from being supplied. Since there is no change in signal exchange, it can be carried out without changing the configuration of the conventional POS apparatus.

  According to the second aspect of the present invention, when the static electricity removal signal is output from the fuel supply device to the supply work monitoring device, the display means displays that the static electricity has been removed. The person in charge of the POS device and the supply work monitoring device can easily grasp whether or not the cause of the failure is that static electricity has not been removed. In addition, since the signal exchange between the POS device and the fuel supply device that has been conventionally performed is not changed, the configuration of the conventional POS device can be implemented without changing.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of a fuel supply system according to the present invention. In this embodiment, in order to describe the case of supplying the oil liquid, hereinafter, supplying the fuel is referred to as “liquid supply”.
As shown in FIG. 1, the fuel supply system 10 is installed in a change machine 14 installed in a liquid supply area 12, a plurality of fuel supply machines 16 (16 _{1 to} 16 _n ), and an office 18. It has a liquid supply (supply) work monitoring device 20 and a POS device 21 connected to the liquid supply work monitoring device 20. The liquid supply operation monitoring device 20 includes a touch panel type monitor 20a. The change machine 14 is, for example, a device for paying a difference (change) between a deposit amount and a liquid supply amount after completion of the liquid supply operation.

The storage device 22 of the liquid supply operation monitoring device 20 has a control program for managing each fuel supply device 16 (16 _{1 to} 16 _n ) and each fuel supply device 16 (16 on the display surface of the touch panel monitor 20a. _{1 to} 16 _n ) are stored.

The fuel supply machine 16 includes a self-service liquid supply type weighing machine 24, a setting device 26 mounted on the weighing machine 24, and an automatic payment machine (payment machine) 28 for paying charges on the spot. In addition, the change machine 14 and the plurality of fuel supply machines 16 (16 _{1 to} 16 _n ) are connected to the liquid supply work monitoring device 20 via a communication line (for example, SS-LAN) 30.

The liquid supply area 12 is provided with monitoring cameras 32 _{1 to} 32 _n for monitoring the periphery of the fuel supply machine 16 (16 _{1 to} 16 _n ). The monitoring cameras 32 _{1 to} 32 _n are connected to the camera dividing unit 34, and images captured by the monitoring cameras 32 _{1 to} 32 _n are transferred to the monitoring monitor 36 via the camera dividing unit 34. The monitoring monitor 36 simultaneously divides and displays a plurality of images taken by the monitoring cameras 32 _{1 to} 32 _n .

FIG. 2 is a front view of the fuel supply device 16.
As shown in FIG. 2, the fuel supply machine 16 includes an apparatus main body 42, an operation panel 44 disposed above the apparatus main body 42, a front panel 46 disposed below the operation panel 44, and an apparatus main body 42. The support pillars 47 and 48 that stand on both sides of the support pillars 47 and the hose support portions 50 that are horizontally mounted between the upper parts of the support pillars 47 and 48 are provided.

  Inside the apparatus main body 42, each device such as a solenoid valve of each liquid supply system, a liquid supply pump, and a flow meter, which will be described later, is provided.

  The operation panel 44 includes a static elimination sheet (static elimination means) 54, a flow rate indicator 56 disposed above the static elimination sheet 54, a card insertion portion 58, a setting device 26, and a setting device 26. A human detection sensor 62 is provided. The static electricity removing sheet 54 is a plate made of a conductive material, and is connected to a ground wire 63.

  For example, a palm mark and a message “please touch before supplying liquid” are printed on the surface of the static electricity removing sheet 54. Further, the human detection sensor 62 uses an optical sensor or an image sensor, and detects that the operator who performs the liquid supply operation stands in front of the setting device 26 and outputs the detection signal.

FIG. 3 is a longitudinal sectional view showing the static electricity removal sheet 54 and the static electricity removal detection switch 64.
As shown in FIG. 3, a static electricity removal detection switch (static electricity removal detection means) 64 that is turned on when the operator presses is attached to the inside of the static electricity removal sheet 54. The static electricity removal detection switch 64 outputs a detection signal when the operator places a hand on the static electricity removal sheet 54 and performs a pressing operation. In this embodiment, the touch of the static eliminator sheet 54 by the operator is detected by the static eliminator detection switch (static eliminator detecting means) 64. However, the operator touches the static eliminator sheet. The configuration for detection is not limited to this. For example, an operator who performs a liquid supply operation touches the static electricity removing sheet 54 using an optical sensor or an image sensor in the same manner as the human detection sensor 62 described above. A detection signal may be output when detected by a sensor.

  Again, referring back to FIG. When a prepaid card issued by a liquid supply station or a credit card is inserted, the card insertion unit 58 reads information stored in the card. The setting device 26 includes a touch panel type monitor, and can select an oil type (light oil, regular gasoline, high-octane gasoline) according to a setting input screen displayed on the monitor, and can perform an operation of inputting a supply amount.

  The front panel 46 is provided with nozzle hooks (nozzle housing portions) 69 to 71 for hooking the liquid supply nozzles 66 to 68. The liquid supply nozzles 66 to 68 are connected in communication with liquid supply hoses 72 to 74 for supplying different oil types.

FIG. 4 is a block diagram showing the configuration of each device of the fuel supply apparatus 10.
As shown in FIG. 4, the control circuit (control means) 80 of the fuel supply machine 16 includes an electromagnetic valve 82, a liquid supply pump 84, a flow meter 86, a flow rate indicator 56, a person provided in each liquid supply path. Detection sensor 62, nozzle switch (nozzle storage detection means) 88 provided in nozzle hooks 69 to 71, static electricity removal detection switch 64, setting device 26, card R / W 90 provided in card insertion portion 58, voice alarm 92 And are connected.

  The control circuit 80 causes the voice notification device 92 to output a voice message so as to remove static electricity from the voice alarm 92 based on the detection signal from the human detection sensor 62. Further, the static electricity removal detection switch 64 is turned on when the operator presses the static electricity removal sheet 54 and outputs a detection signal to the control circuit 80.

Here, the control process executed by the control circuit 80 of the fuel supplier 16 and the POS device 21 will be described.
FIG. 5 is a flowchart for explaining the control process of the first embodiment executed by the control circuit 80 of the fuel supply machine 16.

  As shown in FIG. 5, the control circuit 80 checks whether or not the human detection sensor 62 has an operator (driver) in front of the setting device 26 in S <b> 11. In S11, when the human detection sensor 62 detects the presence of the operator and outputs the detection signal, the process proceeds to S12, and a voice notification such as “Please touch the static electricity removing sheet before setting operation” is performed. Directs static electricity removal by message.

  Subsequently, in S13, it is confirmed whether or not a detection signal is output from the static electricity removal detection switch 64. When the operator is not pressing the static electricity removal sheet 54, the static electricity removal detection switch 64 is off. Therefore, the process proceeds to S14, and whether any of the liquid supply nozzles 66 to 68 is removed from the nozzle hooks 69 to 71. Confirm. In S14, when any of the nozzle switches 88 provided on the nozzle hooks 69 to 71 is turned off, it is determined that the operator has lifted any of the liquid supply nozzles 66 to 68 from the nozzle hooks 69 to 71. To do. Then, the process proceeds to S15, and the static electricity removal instruction by the voice message is again performed from the voice alarm 92.

  In S14, when all of the nozzle switches 88 provided on the nozzle hooks 69 to 71 remain on, the liquid supply nozzles 66 to 68 remain hooked on the nozzle hooks 69 to 71. Return to S13. Therefore, after the operator is detected by the human detection sensor 62, when nothing is done, the process enters a standby state in which the processes of S13 and S14 are repeated.

  Further, after S15, the process proceeds to S16, and it is confirmed whether or not a detection signal is output from the static electricity removal detection switch 64. In S16, when the static electricity removal detection switch 64 is off, it is determined that the operator has not pressed the static electricity removal sheet 54, and the process returns to S13.

  In S13 or S16, when a detection signal is output from the static electricity removal detection switch 64, it is determined that the operator has pressed the static electricity removal sheet 54, and the process proceeds to S17. In S17, it is confirmed whether any of the liquid supply nozzles 66 to 68 is removed from the nozzle hooks 69 to 71. In S17, when all of the nozzle switches 88 provided on the nozzle hooks 69 to 71 remain on, the liquid supply nozzles 66 to 68 remain hooked on the nozzle hooks 69 to 71, so Transition. In S18, it is confirmed whether or not a predetermined time set in advance has elapsed. In S18, the process returns to S17 until the predetermined time elapses, and the processes in S17 and S18 are repeated. In S18, if any of the liquid supply nozzles 66 to 68 is not removed from the nozzle hook in S17 even after a predetermined time has elapsed, the process returns to S13, and the processes from S13 onward are repeated.

  When any of the liquid supply nozzles 66 to 68 is removed from the nozzle hooks 69 to 71 in S17, the process proceeds to S19, and a liquid supply request signal is output to the liquid supply operation monitoring device 20. As described above, in S19 as the supply request signal output means, it is detected by the nozzle switch 88 as the nozzle storage detection means that one of the liquid supply nozzles 66 to 68 has been removed, and the static electricity removal as the static electricity removal detection means. A supply request signal is output on condition that the removal detection switch 64 detects that the operator has touched the static electricity removal sheet 54 as static electricity removal means. As a result, even if the operator removes the liquid supply nozzles 66 to 68 from the nozzle hooks 69 to 71 without touching the static electricity removing sheet 54, the liquid supply request signal is not output. In spite of the fact that the liquid supply permission signal is output as in the prior art, there is no situation in which liquid supply cannot be performed because the operator does not touch the static electricity removing sheet 54.

  In next S20, it is confirmed whether or not a liquid supply permission signal is input from the liquid supply work monitoring apparatus 20. In S20, when a liquid supply permission signal is input from the liquid supply work monitoring device 20, the process proceeds to S21, and the liquid supply pump 84 is activated. As a result, the operator inserts any of the liquid supply nozzles 66 to 68 into the liquid supply port (supply port) of the automobile, and then rotates the nozzle lever (not shown) to open the main valve. As a result, the fuel sent by the liquid supply pump 84 can be supplied to the fuel tank (fuel supply body) of the automobile.

  In the next S22, a liquid supply process is performed. That is, the supply amount (liquid supply amount) supplied to the fuel tank by the flow meter 86 is measured, and the integrated flow rate measured by the flow meter 86 is displayed on the flow rate display 86. Subsequently, in S23, it is checked whether the nozzle that has supplied the liquid is returned to the nozzle hook. That is, it is checked whether or not the nozzle switch 88 that has been turned off for the liquid supply operation is turned on. For example, when full liquid supply is performed, the operator detects that the liquid supply nozzles 66 to 68 during supply of liquid have risen in the liquid level of the fuel tank, and the automatic valve closing mechanism operates to close the main valve. It can be confirmed that the liquid supply is stopped at the time and the count-up of the flow rate display 86 is stopped and the numerical value is reached.

  When the full tank liquid supply is completed in this manner, the operator returns the nozzle lever to the valve closing position, extracts the supplied liquid supply nozzles 66 to 68 from the liquid supply port, and returns them to the nozzle hooks 69 to 71.

  If the nozzle that has supplied the liquid in S23 is returned to the nozzle hook, it is determined that the liquid supply has been completed, and the flow proceeds to S24 to supply liquid information (oil type supplied, liquid supply amount, measuring machine number). Etc.) to the liquid supply work monitoring device 20. Next, in S25, the pump drive signal output is stopped and the feed pump 84 is stopped.

FIG. 6 is a flowchart for explaining a control process executed by the POS device 21.
As shown in FIG. 6, the POS device 21 checks whether or not a liquid supply request signal is input from the fuel supply device 16 via the liquid supply operation monitoring device 20 in S31. When the liquid supply request signal (see S19 above) is not input in S31, the process proceeds to S32, and it is checked whether or not liquid supply information (see S24 above) is input from the fuel supply machine 16 via the liquid supply work monitoring device 20. To do. And when liquid supply information is not input by S32, it will return to the process of said S31 and will be in the standby state which repeats the process of S31 and S32.

  In S31, when a liquid supply request signal is input from the fuel supply unit 16, the process proceeds to S33, where a staff member at the liquid supply station confirms the state of the fuel supply unit 16 displayed on the monitoring monitor 36, and the permission button. By turning on (not shown), a liquid supply permission signal is output to the requested fuel supply machine 16 (corresponding to the process of S20 above).

  In S32, when the liquid supply information is input from the fuel supply unit 16, the process proceeds to S34, and the type of liquid supplied and the amount of liquid supply are stored together with the number of the fuel supply unit 16 for which supply has ended. To do.

  As described above, in the fuel supply system 10, it is detected that the liquid supply nozzles 66 to 68 are removed by the nozzle switches 88 of the nozzle hooks 69 to 71, and the operator removes the static electricity removal sheet 54 by the static electricity removal detection switch 64. In order to output a liquid supply (supply) request signal to the liquid supply operation monitoring device 20 on the condition that it has been detected that it has touched the fuel, the fuel supply is performed even though the liquid supply (supply) permission signal is output Since it is possible to prevent the fuel from being supplied from the machine 16 and the conventional signal exchange between the POS device 21 and the fuel supply machine 16 is not changed, the configuration of the conventional POS device 21 is changed. Can be implemented without any problem. Therefore, a liquid supply permission request signal can be output only when static electricity is removed by adding the liquid supply operation monitoring apparatus 20 to the existing equipment having the POS device 21 and the fuel supply unit 16. Become.

FIG. 7 is a flowchart for explaining a control process according to the second embodiment, which is executed by the control circuit 80 of the fuel supplier 16.
As shown in FIG. 7, the control circuit 80 checks whether the human detection sensor 62 has an operator (driver) in front of the setting device 26 in S <b> 41. In S41, when the human detection sensor 62 detects the presence of the operator and outputs the detection signal, the process proceeds to S42, and a voice notification such as “Please touch the static elimination sheet before performing the setting operation” is sent from the voice alarm 92. A static electricity removal instruction is given by a message, and a static electricity removal waiting signal is output to the liquid supply work monitoring device 20.

  Subsequent processes in S43 to S46 are the same as those in S13 to S16 of the first embodiment described above, and a description thereof will be omitted.

  If a detection signal is output from the static electricity removal detection switch 64 in S46, it is determined that the operator has pressed the static electricity removal sheet 54, and the process proceeds to S47. In S47, a static electricity removal signal is output to the liquid supply operation monitoring device 20. After this, the process proceeds to S49.

  In S43, when a detection signal is output from the static electricity removal detection switch 64, it is determined that the operator has pressed the static electricity removal sheet 54, and the process proceeds to S48. In S48, a static electricity removal signal is output to the liquid supply work monitoring device 20, and the process proceeds to S49.

  In S49, it is confirmed whether any of the liquid supply nozzles 66 to 68 is removed from the nozzle hooks 69 to 71. In S49, when all of the nozzle switches 88 provided in the nozzle hooks 69 to 71 remain on, the liquid supply nozzles 66 to 68 remain hooked on the nozzle hooks 69 to 71. Migrate to

  In S50, it is confirmed whether a predetermined time set in advance has elapsed. In S50, the process returns to S49 until the predetermined time elapses, and the processes in S49 and S50 are repeated. In S50, if any of the liquid supply nozzles 66 to 68 is not removed from the nozzle hook in S49 even after a predetermined time has elapsed, even if the operator presses the static electricity removing sheet 54 in S43, Since there is a possibility that the operator is charged with static electricity over time, the process proceeds to S 51, and a static electricity removal incomplete signal is output to the liquid supply work monitoring device 20. And it returns to said S43 and performs the process after S43 again.

  Further, when any of the liquid supply nozzles 66 to 68 is removed from the nozzle hooks 69 to 71 in S49, the processes of S52 to S58 are executed. Note that the processing of S52 to S58 is the same as S19 to S25 shown in FIG.

  Also in the second embodiment, the POS process by the POS device 21 is the same process as S31 to S34 shown in FIG.

FIG. 8 is a flowchart for explaining processing executed by the liquid supply work monitoring device 20.
As shown in FIG. 8, the liquid supply operation monitoring device 20 checks whether or not a static electricity removal waiting signal is input in S <b> 61. In S61, when the static electricity removal waiting signal is not inputted, the process proceeds to S62, and it is checked whether or not the static electricity removal signal is inputted from the fuel supply unit 16. When the static electricity removal signal is not input in S62, the process proceeds to S63 and it is checked whether or not the static electricity removal incomplete signal is inputted from the fuel supply unit 16.

  When the static electricity removal incomplete signal is not input in S63, the process proceeds to S64, and it is checked whether or not the liquid supply request signal is input from the fuel supply unit 16. When the liquid supply request signal is not input in S64, the process proceeds to S65, and it is checked whether or not a liquid supply permission instruction has been performed. In S65, when there is no liquid supply permission instruction, the process returns to S61 and enters a standby state in which the processes of S61 to S65 are repeated.

  In this standby state, a standby screen 100 shown in FIG. 9A is displayed on the monitor 20a. Further, in the standby screen 100, liquid supply points are provided on both sides of the four fuel supply units 16, and it is displayed that all the liquid supply points are on standby.

  In S61, when the static electricity removal waiting signal is input (by the process in S42), the process proceeds to S66, and the monitor 20a displays that the fuel supply unit 16 is waiting for static electricity removal. In S67, the storage device 22 is displayed. The fact that the fuel supply unit 16 is waiting for static electricity removal is stored. Thus, when the static electricity removal waiting signal is input, as shown in FIG. 9B, the display area 102 of the second liquid supply point that outputs the static electricity removal waiting signal is displayed in, for example, green. “Electrostatic waiting” is displayed in the display area 102 of the liquid supply point. As a result, the staff in the office can easily confirm that the second liquid supply point is waiting for static electricity removal.

  In S62, when the operator presses the static elimination sheet 54 and a static elimination signal is input from the fuel supply unit 16 (by the processing in S47 or S48), the static elimination is performed on the monitor 20a in S68. The static electricity removal is stored in the storage device 22 in S69. Thus, when the static electricity removal signal is input, “Static completed” is displayed in the display area 102 of the second liquid supply point that has output the static electricity removal signal, as shown in FIG. 9C. Thereby, the staff in the office can easily confirm that the second liquid supply point is in a state where static electricity has been removed.

  In S63, if the liquid supply nozzle is not removed from the nozzle hook even after a predetermined time has elapsed after the operator presses the static electricity removal sheet 54, a static electricity removal incomplete signal is input from the fuel supply device 16 ( In step S70, the monitor 20a displays the static electricity removal waiting, and in step S71, the static electricity removal memory stored in the storage device 22 is deleted. In this way, when the static electricity removal incomplete signal is input, as shown in FIG. 9B, “static waiting” is displayed in the display area 102 of the second liquid supply point that outputs the static electricity removal incomplete signal. indicate. Thereby, the staff in the office can easily confirm that the second liquid supply point has returned to the static electricity removal waiting state.

  In S64, when the liquid supply request signal is input (by the process of S52), the process proceeds to S72, and the monitor 20a displays that the fuel supply unit 16 is waiting for the liquid supply permission. In this way, when the liquid supply request signal is input, as shown in FIG. 9D, “liquid supply waiting” is displayed in the display area 102 of the second liquid supply point that has output the liquid supply request signal. . Thereby, the staff in the office can easily confirm that the second liquid supply point is in the liquid supply permission waiting state.

  Then, when a staff member in the office confirms the monitoring monitor 36 and touches the display area 102 of the liquid supply point, a thick line frame 106 is displayed to indicate that the display area 102 has been selected.

  In S65, when the clerk operates to turn on the permission button 104 displayed on the monitor 20a, it is determined that the liquid supply permission is instructed, and the process proceeds to S73. It is checked whether it is stored in 22. In S73, when the removal of static electricity at the liquid supply point is stored, the process proceeds to S74, and a liquid supply permission signal is output to the fuel supply unit 16 (processing corresponding to S53 above). Then, the process proceeds to S75, and the monitor 20a displays that the fuel supply unit 16 is supplying liquid. In this way, when the liquid supply permission signal is output, as shown in FIG. 9E, the supply area indicating “liquid supply” is displayed in the display area 102 of the second liquid supply point that has output the liquid supply permission signal. A submerged mark 108 is displayed. Thereby, the staff in the office can easily confirm that the liquid supply permission signal is output to the second liquid supply point and the liquid supply state is entered.

  In S73, when the removal of static electricity at the liquid supply point is stored, since the static electricity removal memory is erased in S71, the processing of S74 and S75 is not executed and the static electricity removal operation is performed again. It will be.

  As described above, when the static electricity removal signal is output from the fuel supply device 16 to the liquid supply operation monitoring device 20, the monitor 20a as the display means displays that the static electricity has been removed (see FIG. 9C). The person in charge can easily grasp whether or not the reason why the fuel cannot be supplied from the fuel supply unit 16 is that the static electricity is not removed. Further, since there is no change in the signal exchange between the POS device 21 and the fuel supply device 16 that has been conventionally performed, the configuration of the conventional POS device 21 can be performed without change. Therefore, a liquid supply permission request signal can be output only when static electricity is removed by adding the liquid supply operation monitoring apparatus 20 to the existing equipment having the POS device 21 and the fuel supply unit 16. Become.

FIG. 10 is a block diagram showing Embodiment 3 of the fuel supply system.
As shown in FIG. 10, the fuel supply system 110 according to the third embodiment is a full service system in which a staff member at a liquid supply station performs a liquid supply operation, and the work monitoring device 20 and the monitoring camera 32 _{1 have the} configuration shown in FIG. 32 _n , the camera dividing unit 34 and the monitoring monitor 36 are eliminated, and the POS device 21 and the fuel supply unit 16 are configured.

  Therefore, in Example 3, the liquid supply operation is performed after the staff at the liquid supply station touches the static electricity removal sheet 54. Then, the control circuit 80 of the fuel supplier 16 performs the control process shown in FIG. 5 as in the first embodiment, and confirms that the static electricity removal detection switch 64 is turned on in S13 or S16. In S17, when any of the liquid supply nozzles 66 to 68 is removed from the nozzle hooks 69 to 71, the process proceeds to S19, and a liquid supply request signal is output to the POS device 21.

  In the POS device 21, the control process shown in FIG. 6 is executed. When the liquid supply request signal is input from the fuel supply unit 16 in S31, the process proceeds to S33, and the fuel supply unit 16 is not used. In this case, a liquid supply permission signal is output to the fuel supplier 16 that has made a liquid supply request.

  As described above, even in the full-service fuel supply system 110, the liquid supply request signal is output to the POS device 21 on the condition that the staff at the liquid supply station touches the static electricity removal sheet 54. Although the signal is output, it is possible to prevent the fuel supply unit 16 from supplying fuel, and the conventional signal exchange between the POS device 21 and the fuel supply unit 16 is different. Therefore, it can be implemented without changing the configuration of the conventional POS device 21.

  In the above-described embodiment, the case where an oil liquid such as gasoline is supplied to a fuel tank of an automobile has been described. However, the present invention is not limited to this, and the present invention is also applied to a fuel supply system that supplies fuel other than gasoline. Of course, the present invention can be applied to a fuel supply system that supplies fuel to a tank or a container other than the fuel tank of an automobile.

It is a block diagram which shows one Example of the fuel supply system which becomes this invention. 2 is a front view of a fuel supply device 16. FIG. It is a longitudinal cross-sectional view which shows the static elimination sheet 54 and the static elimination detection switch 64. FIG. 2 is a block diagram showing a configuration of each device of the fuel supply device 10. FIG. 4 is a flowchart for explaining a control process of the first embodiment, which is executed by a control circuit 80 of the fuel supplier 16. 4 is a flowchart for explaining a control process executed by the POS device 21. 6 is a flowchart for explaining a control process of a second embodiment executed by a control circuit 80 of the fuel supply unit 16. It is a flowchart for demonstrating the process which the liquid supply operation | work monitoring apparatus 20 performs. It is a figure which shows the example of a display of the monitor of the liquid supply operation | work monitoring apparatus. It is a block diagram which shows Example 3 of a fuel supply system.

Explanation of symbols

10,110 fuel supply system 12 liquid feed area 16 fuel supplier 18 office 20 supply fluid working monitor 20a monitors 21 POS device 22 storage device 24 the weighing machine 26 setter 28 ATM 30 communication line ₃₂ 1 to 32 _n Monitoring Camera 34 Camera division unit 36 Monitoring monitor 54 Static electricity removal sheet 56 Flow rate indicator 62 Human detection sensor 64 Static electricity removal detection switches 66 to 68 Liquid supply nozzles 69 to 71 Nozzle hooks 72 to 74 Liquid supply hose 80 Control circuit 84 Liquid supply pump 86 Flow meter 88 Nozzle switch 92 Voice alarm 100 Standby screen 102 Display area 104 Permission button 106 Thick line frame 108 Liquid supply mark

Claims (2)

A nozzle inserted into a supply port of a fuel supply body to which fuel is supplied;
A nozzle storage portion in which the nozzle is stored when the nozzle is not used;
Nozzle storage detection means for detecting whether the nozzle is removed from the nozzle storage portion;
Fuel supply means for supplying the fuel to the fuel supply body through the nozzle;
A supply request signal output means for outputting a supply request signal to start fuel from the nozzle when the nozzle storage detection means detects that the nozzle has been removed;
Control means for driving the supply means in response to an input of the supply permission signal to enable fuel to be supplied from the nozzle to the fuel supply body;
A supply amount measuring means for measuring the supply amount of the fuel supplied from the nozzle and outputting the supply amount;
A fuel supply machine having
Connected to the fuel supply unit via a communication line, obtains information on the fuel supplied by the fuel supply unit from the fuel supply unit, performs tabulation management, and supplies it from a supply request signal output unit of the fuel supply unit A POS device that outputs a supply permission signal to permit fuel supply from the nozzle when a request signal is input;
A fuel supply system comprising:
Static electricity removing means provided in the fuel supply machine for removing static electricity charged to an operator who supplies fuel,
Static electricity removal detecting means for detecting that the operator has contacted the static electricity removing means;
Have
The supply request signal output means detects that the nozzle has been removed by the nozzle storage detection means, and has detected that the operator has touched the static electricity removal means by the static electricity removal detection means. The fuel supply system outputs the supply request signal on condition of A nozzle inserted into a supply port of a fuel supply body to which fuel is supplied;
A nozzle storage portion in which the nozzle is stored when the nozzle is not used;
Nozzle storage detection means for detecting whether the nozzle is removed from the nozzle storage portion;
Fuel supply means for supplying the fuel to the fuel supply body through the nozzle;
A supply request signal output means for outputting a supply request signal to start fuel from the nozzle when the nozzle storage detection means detects that the nozzle has been removed;
Control means for driving the supply means in response to an input of the supply permission signal to enable fuel to be supplied from the nozzle to the fuel supply body;
A supply amount measuring means for measuring the supply amount of the fuel supplied from the nozzle and outputting the supply amount;
A fuel supply machine having
Connected to the fuel supply unit via a communication line, obtains information on the fuel supplied by the fuel supply unit from the fuel supply unit, performs tabulation management, and supplies it from a supply request signal output unit of the fuel supply unit A POS device that outputs a supply permission signal to permit fuel supply from the nozzle when a request signal is input;
A display unit provided between the fuel supply unit and the POS device, for displaying an operating status of the fuel supply unit, and a supply permission switch operated when permitting fuel supply to the fuel supply unit; And a supply permission signal for permitting the supply of fuel from the nozzle to the fuel supply body, provided that a supply permission signal is input from the POS device when the supply permission switch is operated. A second supply permitting means, and a supply work monitoring device comprising:
A fuel supply system comprising:
The fuel supply machine is
Static electricity removing means for removing static electricity charged to the operator when the operator who supplies the fuel contacts,
Detecting the contact of the operator with the static electricity removing means, and outputting the static electricity removing signal to the supply work monitoring device;
Have
The supply request signal output means outputs a supply request signal when the nozzle storage detection means detects that the nozzle has been removed,
The supply work monitoring device includes:
When a static electricity removal signal is output from the fuel supply machine, the display means displays that static electricity has been removed, and when the supply permission switch is operated, a supply request signal is output from the fuel supply machine. On the condition that a static electricity removal signal is outputted from the static electricity removing means and a supply permission signal is outputted from the POS device, the fuel is supplied to the fuel feeder to supply fuel from the nozzle. A fuel supply system that outputs a permission signal.

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