JP2012086853A - Oil feeding apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an oil feeding apparatus which can prevent the danger of the leakage of a fuel oil resulting from the deterioration of an oil feeding hose from occurring by determining that the degree of the deterioration of the oil feeding hose, and by replacing the deteriorated oil the feeding hose at a proper timing.SOLUTION: The oil feeding apparatus includes: an oil feeding pump (5) for feeding the fuel oil to the oil feeding hose (8); a motor (4) for driving the oil feeding pump (5); a nozzle switch (11) for controlling the driving of the motor (4) for driving; and a deterioration determining section (31) for determining the hose deterioration conforming to the counted value from a flowmeter within a specified period of time conforming to the ON signal of the oil feeding pump (5).

Description

  The present invention relates to an oil supply device for supplying fuel oil to an automobile, and more particularly to an oil supply device having a function of determining the degree of deterioration of an oil supply hose.

An oil supply device that supplies fuel oil to an automobile is provided with an oil supply pump, a solenoid valve, and a flow meter in the middle of an oil supply pipe that communicates with an underground tank, and an oil supply nozzle provided at the tip of an oil supply hose connected to the oil supply pipe. Yes.
A nozzle switch is provided in the nozzle hook for hooking the fuel nozzle. When the oil nozzle is removed from the nozzle hook and an ON signal is output from the nozzle switch, the fuel pump is driven and the solenoid valve is opened to allow the fuel to be supplied.
Then, when the fueling nozzle is inserted into the fueling port of the automobile and the valve of the fueling nozzle is opened, fueling is started.

Here, the oil supply hose expands due to the pressure of the fuel oil pumped by the oil supply pump after the oil supply pump is activated and after the oil supply pump is activated until the start of the oil supply. Even though fuel oil is not discharged from the fuel supply nozzle, a phenomenon that the amount of oil corresponding to the expansion of the fuel supply hose is measured by the flow meter, that is, a so-called “jumping phenomenon” occurs.
At the time when the jumping phenomenon occurs, the value measured by the flow meter at the so-called jumping time, that is, at the time when the oil pump is operating but the valve of the oil nozzle is not open (no oil is supplied from the oil nozzle) Although the oil supply hose expands and is measured by the flow meter, the so-called “jumping amount” becomes larger as the oil supply hose deteriorates and becomes softer.
The applicant can display the flow rate measured by the flowmeter even if the “jumping phenomenon” occurs by driving the oil pump for a short time before the display returns to zero by the first operation at the time of opening the store. An oil supply device that does not increase (see Patent Document 1) is proposed.

This proposal is effective, but due to pressure deterioration due to repeated refueling pressure and long-term deterioration due to long-term use, the oil hose deteriorates and the rubber becomes soft, the amount of expansion of the oil hose increases, and the jumping amount increases. It cannot be prevented.
In addition, the rubber of the oil supply hose becomes brittle with long-term use, and the possibility of deterioration and breakage of the oil supply hose increases. In the above-described conventional technique (Patent Document 1), such a problem cannot be solved.

JP 58-216594 A

  The present invention has been proposed in view of the above-described problems of the prior art, and determines the degree of deterioration of the oil supply hose, replaces the deteriorated oil supply hose at an appropriate time, and thereby deteriorates the oil supply hose. An object of the present invention is to provide a fueling device that can prevent the risk of leakage of fuel oil due to fuel.

  The fueling device (1) of the present invention includes a fueling pump (5) for feeding fuel oil from an underground tank (15) to a fueling hose (8) via a flow meter (7), and the fueling pump (5). A predetermined time (jumping time) based on a drive motor (4) to be driven, a nozzle switch (11) for controlling the drive of the drive motor (4), and an operation start signal (ON signal) of the oil pump (5). Deterioration determination means (degradation determination unit 31) for determining hose deterioration based on a count value (a parameter for measuring the jumping amount: for example, the number of pulses) from the flow meter within a sufficiently long time). It is a feature.

And the said deterioration judgment part (31)
A prescribed amount storage means (32) for storing a numerical value (threshold value: for example, a threshold value of the number of pulses corresponding to the jumping amount) as a criterion for judging deterioration
A time-counting means (33) for measuring time (jumping time) in response to an operation start signal (ON signal) of the oil pump (5);
Counting means (27) for counting the flow rate signal of the flow meter (7) (counting the number of pulses as a parameter corresponding to the jumping amount);
The number of pulses of the flow rate signal (jumping amount) measured by the counting means (27) during the elapse of a predetermined time (a time sufficiently longer than the jumping time) after the operation start signal (ON signal) of the oil pump (5) is generated. And the numerical value (threshold value of the pulse number corresponding to the jumping amount) stored in the specified amount storage means (32) is compared to determine the deterioration of the oil supply hose (8). Hose deterioration judging means (34) having a function;
It is preferable that an error storage means (35) for storing the determination result of the hose deterioration determination means (34) is provided.

  Furthermore, it is preferable that the deterioration determination unit (31) has a function of outputting a signal for stopping the drive motor (4) based on the abnormality determination result.

According to the present invention having the above-described configuration, during the refueling operation, the oil supply pump (5) is operated, but the oil supply nozzle (9) is not refueled (the automobile or the like) is not refueled. Nevertheless, whether or not the oil supply hose (8) has deteriorated based on the amount of oil (so-called jumping amount) that the oil supply hose (8) expands and is measured by the flow meter (7). Can be judged.
When the oil supply hose (8) is deteriorated, it becomes more flexible than an undegraded (new) oil supply hose (8), and is easily expanded by the pressure (internal pressure) of the oil flowing through the oil supply hose (8). Become.
When the oil supply hose 8 is deteriorated and easily expands, the oil supply hose (8) expands when the oil supply nozzle (9) does not supply oil after receiving the ON signal of the oil supply pump (5). The amount of oil that is measured by the flow meter (7) (so-called jumping amount) increases as compared with an undegraded (new) oil supply hose. In other words, when the oil supply hose (8) deteriorates, the jumping amount increases.

In the present invention, when the oil supply hose (8) is deteriorated, the oil hose (8) is easily expanded, and the amount of oil measured by the oil supply hose (8) expanding after receiving the operation start signal (ON signal) of the oil supply pump (5). The phenomenon of increasing (jumping amount) is used to determine the deterioration of the oil supply hose.
Specifically, the flow rate signal measured by the counting means (27) during the elapse of a predetermined time (a time sufficiently longer than the jumping time) after the oil supply start signal (ON signal) of the oil supply pump (5) is generated. Measure the number of pulses (number of pulses corresponding to the jumping amount) and the number of pulses corresponding to the amount of jumping in the non-deteriorated hose (threshold value or set value pulse number) for each refueling and compare To do.
Since the deteriorated oil supply hose (8) is easily expanded, the oil supply hose (8) expands when no oil is supplied from the oil supply nozzle (9) after receiving the ON signal of the oil supply pump (5). As a result, the amount of oil (jumping amount) measured by the flow meter (7) becomes longer, and the number of pulses corresponding to the jumping amount increases.
Therefore, when the number of pulses measured by the counting means (27) (the number of pulses corresponding to the jumping amount) is larger than the threshold number (set value), the oil supply hose 8 is likely to expand. Therefore, it can be determined that “deteriorated”.

Thus, according to the present invention, it is possible to easily and accurately determine the deterioration of the oil supply hose based on the jumping amount. As a result, it is possible to determine at the stage before the crack is generated that the oil supply hose whose deterioration has progressed before the crack is generated is deteriorated.
As a result, it is possible to prevent the risk of performing a refueling operation with a cracked refueling hose.

In addition, according to the present invention, the deterioration determination of the oil supply hose is performed based on the jumping amount, so the deterioration determination can be performed every time the oil supply is performed.
Therefore, the determination result of the deterioration determination is stored for each refueling, and the progress of deterioration can be grasped. And it is prevented from continuing using the deteriorated oil supply hose, and the oil supply hose can be replaced at an appropriate timing.

Further, it is possible to determine whether or not the deterioration of the oil supply hose has progressed and the fuel supply hose can be cracked based on the determination result of the deterioration of the oil supply hose. And if it has deteriorated to the state where the oil supply hose can be cracked, it is possible to make the oil supply operation impossible.
Thereby, the danger of performing the oil supply work with the oil supply hose in which the crack has occurred can be avoided.

It is a schematic diagram of the oil supply apparatus of this invention. It is a figure which shows the gas station which installed the oil supply apparatus of this invention. It is a block diagram of the oil supply control apparatus of an oil supply apparatus. It is a flowchart which shows the control in oil supply of a fuel supply apparatus. It is a flowchart which shows control of the deterioration determination of an oil supply hose. It is a figure which shows the operation timing of each apparatus of a fueling apparatus.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
In FIG. 1, an oil supply apparatus according to the present invention generally indicated by reference numeral 1 has an oil supply pipe 3 disposed in a housing 2 thereof.
The oil supply pipe 3 is provided with an oil supply pump 5 driven by a drive motor 4, an electromagnetic valve 6 that opens and closes the flow path of the oil supply pipe 3, and a flow meter 7 that measures the amount of oil supply. An oil supply hose 8 is connected to the tip.
An oil supply nozzle 9 is attached to the tip of the oil supply hose 8.

A nozzle hook 10 for hooking and locking the oil supply nozzle 9 is provided on the side surface of the housing 2.
The nozzle hook 10 is provided with a nozzle switch 11. The nozzle switch 11 has a function of detecting whether the fuel nozzle 9 is locked (whether the fuel nozzle 9 is hooked: OFF) or whether the lock is released (whether the fuel nozzle 9 is hooked: ON). ing.

The flow rate signal of the flow meter 7, the ON / OFF signal of the nozzle switch 11, and the operation start signal (ON signal) from the oil supply pump 5 are input to the oil supply control device 12.
As will be described later with reference to FIG. 3, when the flow signal of the flow meter 7 and the ON / OFF signal of the nozzle switch 11 are input to the fuel supply control device 12, the fuel supply control device 12 drives the drive motor 4. A stop signal is output, an open / close signal is output to the electromagnetic valve 6, a display signal is output to the display device 13, and an operation / stop signal is output to the alarm device 14. When a drive signal is output to the drive motor 4, an operation start signal (ON signal) is input from the oil supply pump 5 to the oil supply control device 12.

Here, in FIG. 2 which shows the whole fueling station, a plurality of fueling apparatuses 1, 1... Are installed in the fueling station, and the fueling pipe 3 of each fueling apparatus 1 is connected to an underground tank 15. .
In FIG. 2, the gas station is provided with a car wash machine 16 for washing the customer's car, a liquid amount management device 17 for managing fuel oil in the underground tank 15, and an outdoor data input / output device 18 for inputting / outputting data to / from each device. It has been.

A control device built in each of these devices (1, 15 to 18) is connected to the POS 20 via the transmission / reception device 19.
Furthermore, the transmission / reception device 19 includes a computer 21 (general headquarters computer) of a general headquarters (not shown) that supervises the gas station via a communication line, and a computer 22 of a maintenance company (not shown) of the gas station. (Maintenance company computer), connected to the device status server 23.

In FIG. 3, the ON / OFF signal of the nozzle switch 11, the flow rate signal of the flow meter 7, and the ON signal from the oil pump 5 are input to the oil supply control device 12 in the oil supply device 1.
From the fuel supply control device 12, a drive / stop signal is output to the drive motor 4, an open / close signal is output to the solenoid valve 6, a fuel supply amount display signal is output to the display 13, and the alarm 14 An operation / stop signal is output to the transmitter / receiver 19, and various data signals are output to the transmitter / receiver 19.
Here, all the events that occurred in the gas station are reported to the general headquarters computer 21 shown in FIG. 2, and the countermeasures for the reported events are returned, so that they are output to the transmission / reception device 19. The various data signals mean signals corresponding to all events occurring in the gas station.

In FIG. 3, the oil supply control device 12 has a motor driving means 25, a valve driving means 26, a counting means 27, a pulse monitoring means 28, a gate means 29, a display driving means 30, an alarm operating means 36, and a transmitting / receiving means 37. ing.
Here, when the fuel supply control means 12 is configured by a single information processing apparatus (computer), the various devices shown in FIG. 3 show so-called “functional blocks”.

In FIG. 3, the motor drive means 25 outputs a drive signal to the oil supply motor 4 when receiving an ON signal from the nozzle switch 11, and outputs a stop signal to the oil supply motor 4 when receiving an OFF signal from the nozzle switch 11 (or The drive signal to the drive motor 4 is de-energized). When a drive signal is output to the oil supply motor 4, the oil supply pump 4 is operated, and an ON signal is output from the oil supply pump 4 to the oil supply control device 12.
The valve driving means 26 outputs an open signal to the electromagnetic valve 6 when receiving an ON signal from the nozzle switch 11 and outputs a close signal to the electromagnetic valve 6 when receiving an OFF signal from the nozzle switch 11 (or to the electromagnetic valve 6). Turn off the open signal).

The counting means 27 counts the flow rate signal of the flow meter 7 (more specifically, the number of pulses corresponding to the flow rate), and after a predetermined time has elapsed since receiving the ON signal of the fuel pump 5, It has a function to return to zero.
Here, the “predetermined time” is an appropriately set time that is sufficiently longer than the time during which the jumping phenomenon occurs (jumping time). In the illustrated embodiment, the “predetermined time” is set from the viewpoint that the expansion of the oil supply hose 8 ends during the “predetermined time” and no jumping phenomenon occurs after the “predetermined time” elapses. For example, 1 second (1000 msec.) Is set as the predetermined time. In the illustrated embodiment, as the “predetermined time”, a time sufficiently longer than the time (jumping time) in which the jumping phenomenon occurs is set. Therefore, when the “predetermined time” has elapsed, It is determined that the expansion has ended.
Note that whether or not the expansion of the refueling hose 8 has ended (whether the so-called jumping time has elapsed) can also be determined by a conventionally known technique. For example, by monitoring the pressure in the fuel supply hose 8, it is possible to determine whether the fuel supply hose 8 has expanded or has expanded.

The pulse monitoring means 28 has a function of transmitting an open signal to the gate means 29 when the count value of the counting means 27 exceeds a certain value.
When the open signal from the pulse monitoring unit 28 is not transmitted, the gate unit 29 blocks transmission of the coefficient value from the counting unit 27 to the display driving unit 30 and opens the signal from the pulse monitoring unit 28. When the signal is transmitted, it has a function of transmitting the coefficient value from the counting means 27 to the display driving means 30.

The display drive means 30 sends an operation signal to the display 13 in order to display the amount of oil supply on the display 13 based on the count value of the counting means 27 transmitted through the gate means 29.
The alarm device operating means 36 has a function of receiving an operation signal from the hose deterioration determining means 34 described later and outputting the operation signal to the alarm device 14. This is because when it is determined that the hose has deteriorated, that fact is immediately notified, and the operator of the gas station is informed of the necessity of hose replacement.
The transmission / reception means 37 outputs various data in the refueling control device 12 (data corresponding to an event occurring in the fueling station) to the transmission / reception device 19, and receives various data input from the transmission / reception device 19 (for response measures for the event). (Corresponding data) is transmitted to each device in the fuel supply control device 12.

In FIG. 3, the fuel supply control device 12 includes a deterioration determination unit 31, and the deterioration determination unit 31 includes a specified amount storage unit 32, a time measuring unit 33, a hose deterioration determination unit 34, and an error storage unit 35.
The specified amount storage means 32 has a numerical value as a basis for determining the deterioration of the oil supply hose 8, the number of pulses corresponding to the so-called jumping amount, and “pulse as a threshold value (setting value) for determining the deterioration of the oil supply hose”. Number "is stored.
As described above, the jumping amount is determined by the fuel hose pumped by the fuel oil pumped by the fuel pump 5 when the fuel pump 5 is operating but the valve of the fuel nozzle is not open (no fuel is supplied from the fuel nozzle). 8 is an amount of oil that is measured by the flow meter 7 even though fuel oil is not discharged from the fuel supply nozzle 9 because 8 swells.
The time measuring means 33 has a function of measuring whether or not a predetermined time has elapsed after receiving the ON signal of the fuel pump 5. As described above, the predetermined time is appropriately set to a time sufficiently longer than the time when the jumping phenomenon occurs (jumping time). For example, it is set to 1 second (1000 msec.). In the illustrated embodiment, the “predetermined time” is set to a time sufficiently longer than the time when the jumping phenomenon occurs (jumping time). Judge that it is finished.

The hose deterioration determining means 34 is a count value (measured number of pulses) of the counting means 27 when the time measuring means 33 measures a predetermined time, and a numerical value (threshold value) stored in the specified amount storage means 32. The number of pulses) is compared to have a function of judging deterioration of the oil supply hose 8.
Here, “the count value of the counting means 27 when the timing means 33 counts a predetermined time” is the number of pulses measured while the oil supply hose 8 is expanding. The “numerical value (number of pulses that is a threshold value) stored in the prescribed amount storage means 32” is the maximum value of the number of pulses when it is determined that the fuel supply hose 8 has not deteriorated.

The hose deterioration determination means 34 also has a function of outputting the result of deterioration determination of the fuel supply hose 8 to the error storage means 35.
The error storage unit 35 stores the deterioration determination result in the hose deterioration determination unit 34.
When the determination result of the hose deterioration determination unit 34 is “deterioration (or abnormality)”, an operation signal is output from the deterioration determination unit 31 to the alarm operation unit 36. Then, the alarm device 14 is activated to notify that “the oil supply hose has deteriorated (or there is an abnormality in the oil supply hose)”.
By this notification, it is possible to grasp that it is necessary to replace the oil hose at the gas station or its headquarters.
Details of the hose deterioration determination means 34 determining whether or not the fuel supply hose 8 has deteriorated will be described later with reference to FIG.

When it is determined that deterioration of the oil supply hose 8 has progressed and there is a possibility that a serious situation such as a crack will occur, the deterioration determination unit 31 causes the motor drive means 25 to stop the drive motor 4. A signal (or a deactivation signal for deactivating the drive signal to the drive motor 4) is output. At the same time, the closing signal for the electromagnetic valve 6 (or the deactivation signal for deactivating the open signal to the electromagnetic valve 6) is output from the deterioration determination unit 31 to the valve driving means 26.
A stop signal for the drive motor 4 (or a deactivation signal for deactivating the drive signal to the drive motor 4), a close signal for the electromagnetic valve 6 (or a deactivation signal for deactivating the open signal to the electromagnetic valve 6) Is output, if the hose deterioration determining means 34 determines that the oil supply hose has deteriorated (or the oil supply hose is abnormal), the drive motor 4 is stopped and the solenoid valve 6 is closed. As a result, refueling becomes impossible.
The determination as to whether or not “the deterioration of the oil supply hose 8 has progressed and a serious situation such as a crack may occur” is, for example, the deterioration determination result stored in the error storage means 35. It is possible to make a determination by automatic control by the crisis situation server 23 or a control device (not shown) in the general headquarters 21 based on the above data.

Next, the operation and control of the fueling device described with reference to FIGS. 1 to 3 will be described with reference to FIGS.
In FIG. 4, in order to supply oil to the automobile, when the oil supply nozzle 9 is removed from the nozzle hook 10 and an ON signal is input from the nozzle switch 11 to the oil supply control device 12 (step ST1 is “Y”), the oil supply control device 12 A drive signal is output from the motor drive means 25 to the drive motor 4, the oil supply pump 5 is driven by the drive motor 4, and an open signal is output from the valve drive means 26 of the oil supply control device 12 to the electromagnetic valve 6, The solenoid valve 6 is opened (step ST2 in FIG. 4).
In the state of step ST2 in FIG. 4, that is, the nozzle switch 11 outputs an ON signal, the oil supply pump 5 is driven to output an ON signal (to the oil supply control device 12), and an open signal is output to the solenoid valve 6. The opened state is the time point “a” on the horizontal axis of the timing chart of FIG. 6.

  When the electromagnetic valve 6 is opened, the fuel oil in the underground tank 15 is pumped up by the oil supply pump 5 and is pumped into the oil supply hose 8 through the electromagnetic valve 6 and the flow meter 7. At that time, the flow rate signal of the flow meter 7 is counted by the counting means 27. Then, it is determined whether or not a predetermined time (a time sufficient for the refueling hose 8 to expand or a time sufficiently longer than the jumping time) has elapsed (step ST3). When the predetermined time has elapsed (step ST3), the counting means 27 Returned to zero (step ST4, “B” in FIG. 6).

In the illustrated embodiment, the deterioration determination is performed as to whether or not the oil supply hose 8 has deteriorated based on the number of pulses in the flow rate signal measured (counted) by the coefficient means 27 in the predetermined time in step ST3. The control in determining the deterioration is shown in FIG.
First, the principle of deterioration determination in the illustrated embodiment will be described.
When the oil supply hose 8 is deteriorated, the oil supply hose 8 becomes softer than the undegraded (new) oil supply hose 8 and is easily expanded by the pressure (internal pressure) of the oil flowing through the oil supply hose 8.
When the oil supply hose 8 is deteriorated, the oil supply hose 8 is easily expanded by the pressure (internal pressure) of the oil flowing through the oil supply hose 8, so that the expansion amount (or jumping amount) of the oil supply hose 8 is not deteriorated (new). Increase compared to the hose 8.

In the illustrated embodiment, the deterioration determination of the oil supply hose 8 is performed using such a phenomenon (a phenomenon in which the jumping amount increases when the oil supply hose 8 deteriorates).
In the illustrated embodiment, when the oil supply nozzle 5 is not supplying oil, the counting means 27 is operated while a predetermined time (a time sufficiently longer than the jumping time) elapses after the ON signal of the oil supply pump 5 is generated. The number of pulses of the measured flow rate signal (the number of pulses corresponding to the jumping amount) is measured, and the number of pulses that are determined not to be deteriorated (threshold number or set value pulse number) is measured for each refueling. When the measured number of pulses is greater than the threshold number (set value), the oil supply hose 8 is likely to expand. It is determined that it has deteriorated.

Deterioration judgment of the oil supply hose 8 in the illustrated embodiment will be described with reference to FIG. Here, in the fueling apparatus 1, the control routine shown in FIG. 5 operates separately from the control routine shown in FIG.
In FIG. 5, an ON signal is input from the oil supply pump (5) (step ST21, time point of “a” in FIG. 6), and a predetermined time (a time sufficiently longer than the time required for the oil supply hose 8 to expand: for example, It is determined whether or not 1 second has elapsed (step ST22). As described above, if the “predetermined time” has elapsed, it can be determined that the expansion of the oil supply hose 8 has ended.
When the predetermined time has elapsed (step ST22 is “Y”), the hose deterioration determination unit 34 takes in the count value of the counting means 27 (the number of pulses in the flow rate signal of the flow meter 7) and is set in the specified amount storage means 32. It is compared with a numerical value (pulse number threshold) (step ST23).
Whether or not the count value of the counting means 27 (the number of pulses in the flow rate signal of the flow meter 7 generated at a predetermined time) is equal to or less than the numerical value (pulse number threshold value) set in the specified amount storage means 32. Is determined (step ST24).

If the count value of the counting means 27 (the number of pulses in the flow rate signal of the flow meter 7 generated at a predetermined time) is less than or equal to the numerical value (threshold value of the number of pulses) set in the specified amount storage means 32 (step ST24). "Y"), "the oil hose is not deteriorated (the oil hose is normal)". Then, the process proceeds to step ST28.
On the other hand, when the count value of the counting means 27 (the number of pulses in the flow rate signal of the flowmeter 7 generated at a predetermined time) is larger than the numerical value (threshold value of the number of pulses) set in the specified amount storage means 32. ("N" in step ST24), it is determined that "oil supply hose has deteriorated (oil supply hose abnormality)", and an operation signal is output to the alarm operating means 36 (step ST26). Then, the process proceeds to step ST28.

In step ST28, the determination result in step ST25 or step ST26 is stored in the error storage means 35 (step ST25).
According to the control shown in FIG. 5, when the oil supply hose 8 deteriorates and the expansion amount of the oil supply hose 8 increases, it is determined that the oil supply hose has deteriorated (abnormality of the oil supply hose), and the alarm operating means 36 Since the operation signal is output (step ST26), the operator who operates the fueling device 1 can grasp that the time to replace the fueling hose 8 has arrived.
For example, after the business hours of the filling station are completed, the replacement work of the filling hose 8 can be performed.

Although not clearly shown, when the degree of deterioration of the oil supply hose 8 is serious, for example, when it is determined that the soup reaches a level at which the oil supply hose 8 may crack, the drive motor 4 can be stopped and the solenoid valve 6 can be closed so that the refueling operation is not performed.
Such control can be executed by a control routine different from the control shown in FIGS. 4 and 5, for example.

In FIG. 4 again, a predetermined time has passed (step ST3 is “Y”), and the counting means 27 returns to zero (step ST4, “B” in FIG. 6). By returning to zero, when the oil pump is operating but the valve of the oil nozzle is not open (no oil is supplied from the oil nozzle), the oil hose will The amount of oil (jumping amount) that expands and is measured by the flow meter is prevented from being displayed as the “oil supply amount”.
When the predetermined time has elapsed and the counting means 27 has returned to zero (when step ST3 is “Y”), the drive motor 4 has already been driven and the electromagnetic valve 6 has been opened. In this state, the fuel nozzle 9 is inserted into the fuel filler port of the automobile, and the valve of the fuel nozzle 9 is opened, so that the fuel oil in the underground tank 15 flows through the fuel pipe 3, and the pump 5, solenoid valve 6, and flow meter 7 and the oil supply nozzle 9 through the oil supply hose 8.
Then, the flow rate signal of the flow meter 7 is input (step ST5 is “Y”, “c” in FIG. 6), and the counting means 27 counts (step ST6).

When the count value exceeds a certain value (step ST7 is “Y”), the gate means 29 is opened by the pulse monitoring means 28, and the count value of the counting means 27 is transmitted to the display driving means 30 via the gate means 29, and fueling is performed. The amount is displayed on the display 14 (step ST8, “d” in FIG. 6).
By performing so-called “masking” in which the display is started after the count value reaches a certain amount or more in this way, in the illustrated embodiment, an unnatural refueling amount display before opening the valve of the refueling nozzle 9 is displayed. It is preventing.
When refueling is continued and a flow rate signal is input from the flow meter 7 (step ST9 is “Y”), the refueling amount is displayed on the display 14 (step ST8).

After refueling is completed, no flow signal is input from the flow meter 7 (step ST9 is “N”), the valve of the refueling nozzle 9 is closed (e in FIG. 6), the refueling nozzle 9 is hung on the nozzle hook 10 and the nozzle switch 11 When an OFF signal is input (step ST10 is “Y”: “F” in FIG. 6), a stop signal of the motor drive means 25 (a signal for deactivating the drive signal) and a valve close signal (valve open) of the valve drive means 26 A signal for deactivating the signal is transmitted, the drive motor 4 is stopped, the electromagnetic valve 6 is closed, and the gate means 29 is closed (step ST11).
Then, the deterioration determination result of the refueling data and the error storage means 35 is sent to the transmission / reception device 19 by the transmission / reception means 37 (step ST12).

  The transmission / reception device 19 selects the data sent from the fuel supply device 1 and transmits it to the POS 20, the computer 21 of the headquarters, the computer 22 of the maintenance company, the device status server 23, and the like. These data received at each place are used as management data for the gas station.

According to the illustrated embodiment, it is possible to easily and accurately determine the deterioration of the oil supply hose by utilizing the phenomenon that the jumping amount increases when the oil supply hose 8 deteriorates.
Thereby, it is possible to grasp the appropriate replacement time of the fuel hose and contribute to the improvement of safety and management efficiency at the gas station.

It should be noted that the illustrated embodiment is merely an example, and is not a description to limit the technical scope of the present invention.
For example, in the illustrated embodiment, the display is combined with a system that starts displaying after a count value exceeds a certain amount (so-called “masking”), but such a system (a system that performs so-called “masking”). It is also possible not to combine with.

DESCRIPTION OF SYMBOLS 1 ... Oil supply apparatus 2 ... Housing 3 ... Oil supply pipe 4 ... Drive motor 5 ... Oil supply pump 6 ... Solenoid valve 7 ... Flow meter 8 ... Oil supply hose 9 .... Refueling nozzle 10 ... Nozzle hook 11 ... Nozzle switch 12 ... Refueling control device 13 ... Display 14 ... Indicator 15 ... Underground tank 16 ... Car wash machine 17 ...・ Liquid quantity management device 18 ... Outdoor data input / output device 19 ... Transmission / reception device 20 ... POS
21 ... Computer headquarters computer 22 ... Maintenance company computer 23 ... Device status server 25 ... Motor drive means 26 ... Valve drive means 27 ... Counting means 28 ... Pulse monitoring means 29. ··· Gate means 30 ··· Display drive means 31 ··· Degradation judgment unit 32 ··· Predetermined amount storage means 33 ··· Timing means 34 ··· Hose deterioration judgment means 35 ··· Error storage means ..Indicator operating means 37 ... transmitting / receiving means

Claims (3)

An oil supply pump for sending fuel oil from an underground tank to an oil supply hose via a flow meter, a drive motor for driving the oil supply pump, a nozzle switch for controlling the drive of the drive motor, and an operation of the oil supply pump An oil supply apparatus comprising: a deterioration determining means for determining hose deterioration based on a count value from a flow meter within a predetermined time based on a signal. The degradation determination unit
A prescribed amount storage means for storing a numerical value as a criterion for deterioration;
A timing means for timing the oil pump in response to the operation start signal;
Counting means for counting the flow rate signal of the flow meter;
Compare the number of pulses of the flow rate signal measured by the counting means during the lapse of a predetermined time after the oil pump activation start signal is generated with the numerical value stored in the specified amount storage means to determine the deterioration of the oil hose. Hose deterioration judging means having a function of judging;
The oil supply device according to claim 1, further comprising an error storage unit that stores a determination result of the hose deterioration determination unit. The oil supply device according to claim 1, wherein the deterioration determination unit has a function of outputting a signal for stopping the drive motor based on the abnormality determination result.

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