JP2020118198A - Calibration method of hydrogen filling device - Google Patents

Abstract

To provide a calibration method of a hydrogen filling device in which a fuel-cell-powered vehicle is not necessary to travel and wait until the in-vehicle tank is emptied, and multiple (4-vehicles) fuel cell-powered vehicles are not necessary to be prepared.SOLUTION: A calibration method of a hydrogen filling device of the present invention has: a step of connecting a filling nozzle (41) of a hydrogen filling device (40) to be calibrated to a receptacle (6) of a calibration apparatus (100) having a filling tank (2), a measurement housing (1) having a built-in filling tank (2), and a weighing device (3: scales) for measuring the weight of the measurement housing (1); a step of filling a filling tank (2) with hydrogen gas; a step of determining an amount of hydrogen filled in the filling tank (2) on the basis of a difference between the weight of the measurement housing (1) before filling the hydrogen and the weight of the measurement housing (1) after filling the hydrogen; and a step of releasing the hydrogen filled in the filling tank (2) (to the outside of the calibration apparatus), through an exhaust gas mechanism (11) provided in the calibration apparatus (10).SELECTED DRAWING: Figure 1

Description

The present invention relates to a hydrogen filling device used in a hydrogen station which is a facility for filling a hydrogen automobile or the like with hydrogen, and a technique for calibrating the hydrogen filling device.

In recent years, with the development and popularization of vehicles equipped with fuel cells (fuel cell vehicles: FCVs), it is important to increase the number of installation locations of hydrogen stations (for example, see Patent Document 1).
The hydrogen station is provided with a hydrogen filling device, and the hydrogen filling device fills the vehicle-mounted tank of the vehicle that has arrived at the hydrogen station with hydrogen at a predetermined pressure. Then, in order to safely and accurately fill the hydrogen in the vehicle-mounted tank, the work of calibrating the hydrogen filling device is regularly performed.
The calibration work is performed using, for example, a calibration device of a type in which the weight of the calibration device before and after hydrogen filling is measured and the filling amount is determined from the difference. Then, the actual hydrogen filling amount measured by the calibration device is compared with the filling hydrogen amount measured by the hydrogen filling device to calibrate the hydrogen filling device.
Alternatively, a hydrogen flow rate measuring device (reference flow meter: so-called “master meter”) is installed in the hydrogen filling system (calibration of the hydrogen filling device), and the hydrogen filling system is installed while filling the fuel cell vehicle with hydrogen. The amount of hydrogen actually filled in the fuel cell vehicle may be measured by the hydrogen flow rate measuring device (reference flow meter), and the calibration may be performed by comparing with the amount of filled hydrogen measured by the hydrogen filling device.

According to the current guidelines for hydrogen filling, it is stipulated that “4 kg of hydrogen is filled once and 1 kg of hydrogen is filled three times” when calibrating the hydrogen filling device as described above. According to the guideline, in the calibration of the single hydrogen filling device 40 (see FIG. 8), it is necessary to fill the hydrogen at least four times (4 kg once, 1 kg three times).
However, at the time of calibration, it is necessary to fill hydrogen with the pressure inside the vehicle-mounted tank of the fuel cell vehicle at a predetermined initial pressure (so-called “empty” state). Therefore, at the time of calibration, after filling the fuel cell vehicle with a predetermined amount of hydrogen, the fuel cell vehicle filled with hydrogen is run as indicated by an arrow R in FIG. 8 to consume hydrogen in the vehicle tank, It is necessary to interrupt the calibration work until the pressure in the vehicle tank is reduced to a predetermined initial pressure (so-called “empty”).
In FIG. 8, reference numeral 42 is a filling hose, reference numeral MA is a filling nozzle on the hydrogen flow rate measuring device M side (master meter side), and reference numeral SA is a receptacle on the vehicle S side.

Alternatively, when performing the calibration for measuring the hydrogen amount actually filled in the fuel cell vehicle S by the above-described hydrogen flow rate measuring device M (reference flow meter), it is necessary to calibrate one hydrogen filling device. As shown by 9, it is necessary to prepare a plurality of fuel-electric vehicles S (FCV) in advance (for example, four) in a state where the pressure in the vehicle-mounted tank reaches a predetermined initial pressure (so-called “empty” state). There is.

However, when the fuel cell vehicle is driven until the pressure in the vehicle tank reaches the predetermined initial pressure (so-called “empty”) (FIG. 8), the calibration is interrupted and the waiting time becomes long. A great deal of time will be spent calibrating one hydrogen filling device.
On the other hand, if a plurality of (for example, four) fuel-electric vehicles are prepared for performing the calibration work (in the case of FIG. 9), a large amount of labor and cost are required for the preparation of the calibration work.

JP 2000-166635 A

The present invention has been proposed in view of the above-mentioned problems of the related art, and it is not necessary to drive the fuel cell vehicle to stand by until the vehicle tank becomes empty, and a plurality of (for example, four) fuel cell vehicles are provided. It is an object of the present invention to provide a method for calibrating a hydrogen filling device that does not require the preparation of a fuel cell vehicle (FCV).

The method for calibrating the hydrogen filling device of the present invention is
Receptacle of a calibration device (100) having a filling tank (2), a measurement housing (1) containing the filling tank (2), and a weight measuring device (3: scale) for measuring the weight of the measurement housing (1) ( 6) connecting the filling nozzle (41) of the hydrogen filling device (40) to be calibrated,
Filling the filling tank (2) of the calibration device (100) with hydrogen gas,
The amount of hydrogen filled in the filling tank (2) of the calibration device (100) is determined based on the difference between the weight of the measurement housing (1) before being filled with hydrogen and the weight of the measurement housing (1) after being filled with hydrogen. Process,
Having a step (degassing: pressure adjustment) of opening the hydrogen filled in the filling tank (2) (outside the calibration device) via the exhaust gas mechanism (11) provided in the calibration device (100). It has a feature.
Here, the timing of executing the step of determining the hydrogen amount is not limited to between the step of determining and the step of releasing hydrogen. The timing of executing the step of determining the hydrogen amount can be performed at any timing after the step of filling the hydrogen gas is completed.

In the calibration method of the present invention, the calibration device (100) is mounted on a vehicle (PS: calibration vehicle),
A vehicle (PS) equipped with the calibration device (100) is a vehicle (for example, a bi-fuel vehicle) driven by a plurality of types of fuels containing hydrogen (for example, two types of fuels containing hydrogen),
A path (32: hydrogen supply pipe) for connecting the filling tank (2) of the calibration device (100) and the fuel storage device (31: vehicle tank) of the vehicle (PS: bi-fuel vehicle equipped with the calibration device) An on-off valve (33: flow rate adjusting valve) is installed in the
The on-off valve (33) is closed when the vehicle (PS) is stopped and calibration work is performed, and the on-off valve (33) is opened when the vehicle (PS) is traveling. It is preferable to have a process.

In the present invention, the calibration device (100) is
A receptacle (6) connectable to and removable from the filling nozzle (41) at the tip of the filling hose (42) of the hydrogen filling device (40);
A signal transmission means (18) for transmitting information (pressure information, temperature information) in the filling tank (2) (to the hydrogen filling device 40) is provided.
In the step of filling the filling tank (2) with hydrogen gas, the information in the filling tank (2) is preferably transmitted (communication filling) to the hydrogen filling device (40).

According to the present invention having the above-described configuration, after the calibration is completed, the hydrogen filled in the filling tank (2) is operated by operating the opening/closing mechanism (not shown) of the exhaust gas mechanism (11). It is opened to the outside of the calibration device (100) via 11).
During the time when the hydrogen filled in the filling tank (2) is released to the outside of the calibration device (100) through the exhaust gas mechanism (11), the fuel cell vehicle filled with hydrogen is allowed to run to fill the filling tank (2). It is much shorter than the time spent to reduce (so-called “empty”) the internal pressure to a predetermined initial pressure. Therefore, it is not necessary to run the fuel cell vehicle and wait for the calibration until the pressure of the vehicle tank drops to a predetermined initial pressure, and it is also necessary to prepare a plurality of (for example, four) fuel cell vehicles (FCV) in advance. There is no.
As a result, the time, effort, and cost spent calibrating a single hydrogen filling device (40) is significantly reduced.

According to the calibration method of the present invention, the hydrogen filled in the filling tank (2) is based on the difference between the weight of the measurement housing (1) before being filled with hydrogen and the weight of the measurement housing (1) after being filled with hydrogen. Since the amount can be accurately determined, the determined hydrogen amount is compared with the hydrogen filling amount measured by the flow meter in the hydrogen filling device (40) to be the target of the calibration work. It is possible to accurately and easily confirm whether or not the accuracy of the flow meter of the hydrogen filling device (40) has reached the required level.

Further, in the present invention, when the calibration device (100) is mounted or mounted on a vehicle (PS) and the vehicle (PS) is a bi-fuel vehicle, the filling tank (in the calibration device (100) ( The hydrogen charged in 2) can be consumed as fuel for the vehicle (PS).

Further, in the present invention, at the time of calibration, information (pressure information, temperature information) necessary for filling is measured by a measuring device (pressure sensor, temperature sensor) provided inside the filling tank of the calibrating device, and the information is measured. Is transmitted (communicated) to the filling device (40) via the signal transmission means (18), the so-called "communications filling" is executed even during calibration to fill the actual fuel cell vehicle (FCV). Safe and accurate hydrogen filling can be performed up to the same high pressure.

It is explanatory drawing which shows the outline|summary of 1st Embodiment of this invention. It is explanatory drawing which shows the state which mounted the calibrating device in the vehicle in 1st Embodiment. It is a flow chart which shows a procedure of a 1st embodiment. It is a flowchart which shows the procedure which supplies hydrogen from the tank of the calibration apparatus in a bi-fuel vehicle. It is explanatory drawing which shows the calibration apparatus used by 2nd Embodiment of this invention. It is explanatory drawing which shows the calibration apparatus used by 3rd Embodiment of this invention. It is explanatory drawing which shows the calibration apparatus used by 4th Embodiment of this invention. It is explanatory drawing of a prior art. It is explanatory drawing of the prior art different from FIG.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
First, a first embodiment of the present invention will be described with reference to FIGS.
In FIG. 1, a calibration apparatus indicated by reference numeral 100 as a whole includes a measurement housing 1, a filling tank 2 arranged in the measurement housing 1, a scale 3 for measuring the weight of the measurement housing 1, a measurement housing 1 and a scale 3 (weight measurement). A main body housing 10 for housing a device is provided. The filling tank 2 is placed on the bottom surface of the measurement housing 1 via the pedestal 8.
The weight of the hydrogen gas supplied and filled in the filling tank 2 is determined by measuring the weight of the measurement housing 1 before and after filling the hydrogen gas with the balance 3 and determining the difference in the weight before and after filling the hydrogen gas.
The main body housing 10 for accommodating the measurement housing 1 and the scale 3 is provided with moving means 10A (wheels or the like) on its lower surface, and can move the calibration apparatus 100 to the hydrogen filling apparatus 40 to be configured during calibration.

A receptacle 6 (hydrogen inlet) is provided on the side surface (right side surface in FIG. 1) of the measurement housing 1, and the receptacle 6 is connected to a filling nozzle 41 at the tip of a filling hose 42 of a hydrogen filling device 40 to be calibrated (arrow Y). ) Thus, hydrogen is supplied from the hydrogen filling device 40 to the filling tank 2 in the measurement housing 1.
The hydrogen gas supplied from the receptacle 6 into the measurement housing 1 is filled in the filling tank 2 via the filling gas supply pipe line 7. Reference numeral 2A indicates a filling gas intake portion in the filling tank 2, and reference numeral 9 is a check valve for preventing a backflow of the hydrogen gas supplied to the measurement housing 1 side.

A dry gas pipeline 4 is detachably provided on the side surface (left side surface in FIG. 1) of the measurement housing 1, and dry gas is supplied into the measurement housing 1 from a supply source (not shown).
A dew point meter 5 is detachably provided on the outer surface of the measurement housing 1, and humidity control is performed in the measurement housing 1 based on the measurement result of the dew point meter 5. For example, when the dew point temperature of the dew point meter 5 reaches a predetermined temperature (for example, -20°C: a dew point temperature at which it can be determined that the inside of the measurement housing 1 is sufficiently dry), hydrogen gas (for example, cooled to -40°C) is used. Of hydrogen gas), the amount of dew condensation that occurs in devices such as the filling tank 2, the filling gas supply pipe 7, the receptacle 6 and the like is reduced, and the influence of dew condensation on the weight measurement is sufficiently small.

A gas discharge port 13 is provided on the upper surface of the measurement housing 1, and when the measurement housing 1 is filled with a dry gas, the gas containing water in the measurement housing 1 is discharged from the gas discharge port 13 to the outside of the measurement housing 1. It
Further, a filling gas discharge port 11C is provided on the upper surface of the measurement housing 1, and the charging gas discharge port 11C is connected to the opening/closing mechanism 11A of the filling tank 2 by a filling gas discharge pipe line 11B. The exhaust gas mechanism 11 is configured by the opening/closing mechanism 11A, the discharge pipe line 11B, and the discharge port 11C.
Although not shown, the main body housing 10 is also provided with a gas release mechanism, and the hydrogen filled in the filling tank 2 is calibrated by the calibration device 100 via the exhaust gas mechanism 11 and the gas release mechanism of the main body housing 10. Released to the outside.

The support member 14 for fixing the filling gas supply pipeline 7 to the bottom surface of the measurement housing 1, the support member 15 for fixing the filling gas discharge pipeline 11B to the outer wall of the measurement housing 1, and the pedestal 8 on which the filling tank 2 is mounted are It is made of a material having a heat insulating property (a material having low thermal conductivity: for example, rubber or resin), and the low temperature in the measurement housing 1 is conducted to the measurement housing 1 through the support member 14, the support member 15, and the pedestal 8. This prevents dew condensation on the outer surface.
Further, the measurement housing 1 has a semi-enclosed structure, and it is possible to supply a dry gas into the measurement housing 1 and maintain the inside of the measurement housing 1 in a slightly pressurized state, so that the air containing water is measured. Intrusion into the housing 1 is prevented.

Sensors (pressure sensor, temperature sensor) (not shown) in the filling tank 2 are of a type that outputs a measurement signal as an electric signal, and information (pressure information, temperature information) is transmitted from the sensor to the hydrogen filling device 40 side. Therefore, the calibration device 100 has the communication path 18 (broken line in FIG. 1) as a signal transmission means.
The communication path 18 on the side of the calibration device is an electric communication path formed of a conductor for electric signals, but it may be formed of an optical fiber. When the communication path 18 is an optical communication path, it is possible to incorporate an electric/optical converter (for example, a light emitting device such as an LED) in the calibration device side receptacle 6.
One end of the communication path 18 is connected to a sensor (not shown) in the filling tank 2 via a communication connector (not shown) on the filling tank 2 side, and the other end of the communication path 18 is built in the calibration device side receptacle 6. To the optical communication connector (not shown). An optical communication connector (not shown) built in the calibration device side receptacle 6 converts an electric signal into an optical signal.
When the sensors (pressure sensor, temperature sensor) (not shown) in the filling tank 2 are of a type that outputs a measurement signal as an electric signal, a conversion device (electric/optical converter) is provided on the signal communication path on the calibration device 100 side. ), or a converter (electrical/optical converter) is built in the calibration device side receptacle 6 to convert an electrical signal into an optical signal.

The signal transmission means on the hydrogen filling device 40 side is a communication path 43 configured by an electric signal path for transmitting an electric signal obtained by converting the electric signal, and one end of the communication path 43 is built in the filling nozzle 41 on the filling device side. Is connected to the optical communication connector (not shown), and the other end is connected to the hydrogen filling device 40.
When the filling nozzle 41 is connected to the calibration device side receptacle 6, an optical communication connector (not shown) built in the filling nozzle 41 and an optical communication connector (not shown) built in the calibration device side receptacle 6 are connected to each other, and an optical signal is transmitted. Give and receive. Then, the optical communication connector built in the filling nozzle 41 converts the optical signal transmitted from the calibration device side receptacle 6 into an electrical signal and sends it to the communication path 43. Here, the communication path 43 can be configured as an optical communication path by an optical fiber or the like, and can also be a wireless communication path.
When the filling nozzle 41 and the calibration device side receptacle 6 are disconnected, the optical communication connector (not shown) built in the calibration device 100 side receptacle 6 and the filling device 41 built in the filling device 40 side. The optical communication connector (not shown) is disconnected.

When performing calibration using the calibration device 100 of the first embodiment, as shown in FIG. 1, the filling nozzle 41 of the hydrogen filling device 40 is connected to the receptacle 6 on the calibration device side (arrow Y).
By the connection (arrow Y), the hydrogen filling device 40 is configured such that the optical communication path 43, the optical communication connector of the filling nozzle 41 (not shown), the optical communication connector of the calibration device side (not shown), the calibration device side. Is connected to a sensor (not shown) in the filling tank 2 via the optical communication path 18, the optical communication connector (not shown) in the filling tank 2, and the optical communication path (not shown).

When the fuel cell vehicle (not shown in FIG. 1) is filled (normal hydrogen filling) instead of the filling tank 2 in the calibration device 100, the filling nozzle 41 of the hydrogen filling device 40 is connected to the receptacle of the fuel cell vehicle ( (Not shown).
The (pressure, temperature) measured by a measuring device (pressure sensor, temperature sensor) in a vehicle-mounted tank (not shown) of the fuel cell vehicle is used for optical communication connector (not shown) in the receptacle of the fuel cell vehicle, hydrogen filling device 40. It is transmitted to the hydrogen filling device 40 via the optical communication connector (not shown) built in the filling nozzle 41 of FIG. 1 and the optical communication path 43 on the filling device side, and thus the communication filling is executed.
Here, optical communication is performed between the optical communication connector (not shown) in the receptacle of the fuel cell vehicle and the optical communication connector (not shown) built in the filling nozzle 41 of the hydrogen filling device 40. ..

At the time of calibration, as shown in FIG. 1, the filling tank 2 is filled with hydrogen from the hydrogen filling device 40 through the filling hose 42, the filling nozzle 41, the receptacle 6 on the calibration device side, and the filling gas supply pipe line 7.
At that time, information (pressure information, temperature information) in the filling tank 2 being calibrated is detected by a sensor (not shown) in the filling tank 2, and the detection signal is a communication path (not shown) in the filling tank 2 and a calibration device. Side communication path 18, the optical communication connector (not shown) in the receptacle 6 on the calibration device side, the optical communication connector (not shown) in the filling device side nozzle 41, and the communication path 43 on the filling device side. And is transmitted to the hydrogen filling device 40. Therefore, communication filling is executed even at the time of calibration.

At the time of calibration, in order to obtain the filling amount of the hydrogen gas filled in the filling tank 2, the weight of the measurement housing 1 (including hydrogen and the filling tank 2) before and after filling the hydrogen gas in an environment where dew condensation does not occur. Is measured by a scale 3, the weight of the filled hydrogen gas is obtained from the weight difference before and after the hydrogen gas is filled, and the hydrogen filling amount is determined from the weight of the hydrogen gas.
By comparing the hydrogen filling amount thus determined with the hydrogen filling amount obtained from the measurement result of the flow meter (not shown) inside the hydrogen filling device 40, the hydrogen filling device 40 to be calibrated is compared. It is possible to confirm whether the measured hydrogen filling amount is accurate.

After the calibration is completed, the opening/closing mechanism 11A of the exhaust gas mechanism 11 is opened to allow the hydrogen filled in the filling tank 2 to pass through the discharge pipe line 11B, the discharge port 11C, and the gas discharge mechanism of the main body housing 10 not shown. And is discharged to the outside of the calibration device 100.
The hydrogen in the filling tank 2 is released to the outside of the calibration device 100 via the exhaust gas mechanism 11 of the measurement housing 1 and the gas releasing mechanism (not shown) of the main body housing 10 to fill the same amount of hydrogen. This is a far shorter time than the time spent for reducing the pressure of the vehicle-mounted tank to a predetermined initial pressure by driving the fuel cell vehicle.
Therefore, it is not necessary to interrupt the calibration and wait while the fuel cell vehicle is running as in the prior art of FIG. 8, and a plurality of fuel cell vehicles (for example, four) as in the prior art of FIG. It is not necessary to prepare FCV).
As a result, according to the first embodiment of FIG. 1, the time required for the calibration of the single hydrogen filling device 40 is significantly shortened, and a large amount of labor and cost are not required for the calibration preparation.

Here, as shown in FIG. 2, the calibration device 100 can be mounted or mounted on a vehicle PS (hereinafter referred to as “calibration vehicle”), and a plurality of hydrogen filling devices 40 at separated positions are configured. When necessary, the calibration apparatus 100 can be moved to perform calibration efficiently and safely.
In FIG. 2, the filling tank 2 of the calibration device 100 communicates with the engine 30 of the calibration vehicle PS via the hydrogen supply pipe 32, and the hydrogen supply pipe 32 is provided with the flow rate adjustment valve 33. Here, in FIG. 2, the vehicle PS is provided with an in-vehicle tank 31 (a tank in the vehicle that stores hydrogen to be supplied to the engine 30), and the hydrogen supply pipe 32 communicates with the in-vehicle tank 31. 31 can be omitted. When the vehicle-mounted tank 31 is omitted, the hydrogen supply pipe communicates with the engine 30.
Although not clearly shown, a tank for storing a fuel (bi-fuel) other than hydrogen that can be supplied to the engine 30 may be separately provided. The hydrogen supply pipe 32 does not communicate with a tank that stores other fuel.

If the vehicle PS equipped with the calibration device 100 is a bi-fuel vehicle of the type driven by hydrogen and other fuels, when the calibration vehicle PS is stopped and calibration work is being performed, the flow rate adjustment valve 33 The (open/close valve) is closed, and when the calibration vehicle PS is traveling, the flow rate adjusting valve 33 (open/close valve) is opened. As a result, hydrogen can be supplied from the filling tank 2 of the calibration device 100 to the engine 30 of the calibration vehicle PS when the vehicle PS is running, and the supplied hydrogen can be used as fuel for the calibration vehicle PS.
If the vehicle of FIG. 2 is not a hydrogen vehicle such as a bi-fuel vehicle, it is not necessary to provide the hydrogen supply pipe 32 and the hydrogen flow rate adjusting valve 33.

Next, the procedure of the calibration work according to the first embodiment will be described mainly with reference to FIG.
In the flowchart of FIG. 3, before the step S1 and subsequent steps are performed, first, the scale 3 of the calibration device 100 is configured with a reference weight. This is for correcting gravity acceleration, air density (temperature, humidity) and the like.
Then, in step S1, it is determined whether or not the calibration work is performed. If it is determined in step S1 that the calibration work is to be performed (step S1 is "Yes"), the process proceeds to step S2. If it is determined that the calibration work is not to be performed (step S1 is "No"), step S1 is repeated.

In step S2, initial conditions are checked when performing the calibration work.
Various parameters are set as the initial condition, and it is confirmed whether or not the initial condition is satisfied corresponding to each parameter. Then, the process proceeds to step S3.
In step S3, it is determined whether or not the pressure in the filling tank 2 is a predetermined filling start pressure (initial pressure: pressure corresponding to so-called "empty"). The determination in step S3 is made by measuring the pressure in the filling tank 2 with the pressure sensor in step S2 and comparing it with a predetermined initial pressure set in advance.
In step S3, when the pressure in the filling tank 2 is the predetermined initial pressure (step S3 is “Yes”), the process proceeds to step S4, and the pressure in the filling tank 4 is not the predetermined initial pressure. In that case (step S3 is "No"), the process proceeds to step S5.

In step S4, the scale 3 is reset (so-called "tare subtraction") prior to connecting the filling nozzle. Then, to fill with hydrogen, the filling nozzle 41 (FIG. 1) of the hydrogen filling device 40 is connected to the receptacle 6 of the calibration device 100. Then, the process proceeds to step S6. Although not clearly shown in the flow chart of FIG. 3, in the state where the filling nozzle 41, the dry gas pipe line 4, and the dew point meter 5 are not connected (before step S4), the measurement housing 1 before being filled with hydrogen gas is The weight is measured by the scale 3.
On the other hand, in step S5, the exhaust gas mechanism 11 (FIG. 1) of the filling tank 2 is operated so as to reduce the pressure in the filling tank 2 to a predetermined initial pressure, and the pressure is reduced by the opening/closing mechanism (pressure reducing valve). At that time, it is performed while monitoring the pressure and temperature in the filling tank 2. After step S5, the process returns to step S2.
In step S6, hydrogen is metered from the hydrogen filling device 40 into the filling tank 2 of the calibration device 100. Communication fill is performed as described above with reference to FIG.
Although not explicitly shown in FIG. 3, prior to the hydrogen filling in step S6, the measurement housing 1 is filled with the dry gas through the dry gas pipeline 4 (FIG. 1), and a gas containing water is discharged through the gas outlet. It can also be discharged from the measurement housing 1 from 13 (FIG. 1).

In step S7, the amount of hydrogen filling the filling tank 2 of the calibration device 100 is confirmed based on the output of the flow meter built in the hydrogen filling device 40. Then, the process proceeds to step S8.
In step S8, it is determined whether or not the hydrogen filling amount in the filling tank 2 of the calibration device 100 has reached a predetermined hydrogen filling amount, and it is determined whether or not the hydrogen filling in the calibration device 100 is completed. When it is determined in step S8 that the hydrogen filling in the calibration device 100 is completed (step S8 is “Yes”), the process proceeds to step S9. On the other hand, if it is determined that the hydrogen filling is not completed (step S8 is "No"), the process returns to step S6 to continue the filling.

In step S9, it is determined whether or not the depressurization is completed in the filling nozzle 41 on the filling device side, and it is determined whether or not the filling nozzle can be safely removed. The determination is performed by comparing the pressure inside the filling nozzle 41 with the pressure determined by the safety standard.
As a result of the determination in step S9, when it is determined that the depressurization of the portion of the filling nozzle 41 is completed and the filling nozzle can be safely removed (step S9 is “Yes”), the process proceeds to step S10, and the filling nozzle 41 When it is determined that the depressurization of the portion is not completed (No in step S9), the process proceeds to step S11.
In step S10, the filling nozzle 41 of the hydrogen filling device 40 is removed from the receptacle 6 on the calibration device 100 side. Then, the process proceeds to step S12.
In step S11, depressurization of the portion of the filling nozzle 41 is continued, and the process returns to step S9.

In step S12, the weight of the hydrogen gas filled in the filling tank 2 in the measurement housing 1 from the hydrogen filling device 40 (the weight of the measurement housing 1 after hydrogen gas filling) is measured by the scale 3. During the measurement, the dry gas pipeline 4 and the dew point meter 5 are removed from the measurement housing 1 in advance.
In step S13, the exhaust gas mechanism 11 (opening/closing mechanism 11A, discharge pipeline 11B, discharge port 11C, FIG. 1) provided in the filling tank 2 is operated to open the hydrogen filled in the filling tank 2 ( (Outside the calibration device 100) (outgassing: pressure adjustment).
In step S13, the pressure in the filling tank 2 is measured with the pressure sensor, and the pressure in the filling tank 2 is set to the initial condition in the calibration executed thereafter.

In step S14, it is confirmed whether or not all the scheduled calibrations have been completed. Here, all the calibrations may mean, for example, all the calibration work to be performed by one hydrogen filling device 40 to be calibrated (for example, calibration with a hydrogen filling amount of 4 kg is performed once and 1 kg is performed). 3 times, a total of 4 times), or a calibration to be executed for all of the plurality of hydrogen filling devices 40 installed in the gas station (for example, 4 times/1 unit×the number of hydrogen filling devices 40). In some cases.
In step S14, if all the calibrations are completed (step S14 is "Yes"), the process proceeds to step S15. If all calibrations are not completed (step S14 is "No"), the process returns to step S2. , Continue to calibrate.

In step S15, the difference (weight difference) in the measurement results of the weight of the measurement housing 1 before and after filling with hydrogen gas is determined. Then, the filling amount of the hydrogen gas filled in the filling tank 2 of the calibration device 100 is determined from the weight difference (the weight difference of the measurement housing 1 before and after the hydrogen gas filling).
In step S16, the hydrogen filling amount determined by the calibration device 100 side (by step S15) and the hydrogen filling amount measured by the hydrogen filling device 40 side are compared for each of the performed calibration operations.
Here, the step of determining the hydrogen filling amount on the calibration device 100 side (step S15), the process of comparing the hydrogen filling amount decided on the calibration device 100 side with the hydrogen filling amount measured on the hydrogen filling device 40 side (step S16). ) Is not limited to being performed at the stage shown in the flowchart of FIG. 3, and can be executed at any stage after the end of hydrogen filling (step S8).
In step S17, a calibration result is created. For example, the hydrogen filling amount determined on the calibration device 100 side is compared with the hydrogen filling amount measured on the hydrogen filling device 40 side (step S16), and from the comparison result, the hydrogen filling device 40 to be calibrated is built in. The accuracy of the flow meter to be used or the accuracy of hydrogen measurement is made quantitatively comparable, and the suitability of the hydrogen filling device 40 is determined. Then, the calibration is completed.
In FIG. 3, when a plurality of hydrogen filling devices 100 are provided, after the processes of steps S1 to S14 are completed for all the hydrogen filling devices, the plurality of hydrogen filling devices 100 are collectively executed to perform the processes of steps S15 to S17. However, each time the calibration of each hydrogen filling device 100 is completed, the steps S15 to S17 can be executed for each hydrogen filling device 100 whose calibration is completed at the stage immediately before step S14.

Here, FIG. 4 shows a procedure for supplying hydrogen to the bi-fuel vehicle PS.
This is the procedure when the calibration device 100 is mounted or mounted on the calibration vehicle PS as shown in FIG.
In the flowchart of FIG. 4, in step S21, it is determined whether the vehicle PS is a hydrogen-fueled vehicle (whether it is a bi-fuel vehicle). In step S21, if the calibration vehicle PS is a bi-fuel vehicle (step S21 is "Yes"), the process proceeds to step S22. If the calibration vehicle PS is not a bi-fuel vehicle (step S21 is "No"). Proceeds to step S24.

In step S22 (when the calibration vehicle PS is a bi-fuel vehicle), it is determined whether the calibration vehicle PS is in the traveling mode or stopped and in the calibration work mode. In step S22, if the calibration vehicle PS is in the traveling mode, the process proceeds to step S23, and if the calibration vehicle PS is in the calibration work mode, the process proceeds to step S24.
In step S23, the on-off valve 33 (FIG. 2) provided in the hydrogen supply pipe 32 (FIG. 2) of the calibration vehicle PS is opened, and the hydrogen in the filling tank 2 is supplied to the engine of the vehicle PS via the hydrogen supply pipe 32. 30 (FIG. 2).
On the other hand, in step S24, it is determined that the calibration vehicle PS is not a bi-fuel vehicle or the calibration vehicle PS is in the calibration work mode, and the on-off valve 33 of the hydrogen supply pipe 32 in the calibration vehicle PS is closed and the filling is completed. The tank 2 and the engine 30 (FIG. 2) of the vehicle PS are shut off.

In the flowchart of FIG. 4, steps S21 to S24 can all be executed by a worker who manually determines or operates.
However, it is also possible to execute steps S21 to S24 by automatic control by a control unit (not shown). For example, the determination in step S21 can be performed by supplying information of the vehicle PS to the control unit in advance, and the determination in steps S22 and S24 and the opening/closing control in step S23 can also be performed by the control unit.

In the first embodiment described with reference to FIGS. 1 to 4, the calibration work is performed using the calibration device 100 as shown in FIGS.
On the other hand, in the second embodiment shown in FIG. 5, the hydrogen filling amount is determined based on the weight difference before and after hydrogen filling as in FIGS. 1 and 2, but the calibration device 100 of FIGS. A calibration device 100-1 different from the above is used. Hereinafter, in the second embodiment of FIG. 5, the points different from those of FIGS. 1 and 2 will be mainly described.
5 to 7, in order to avoid complication, devices such as the measurement housing 1, the filling tank 2, the scale 3, the receptacle 6, the filling gas supply pipeline 7, the exhaust gas mechanism 11 are the same as those in FIGS. 1 and 2. Is attached.

In the second embodiment shown in FIG. 5, the calibration device 100-1 as a whole places a weight 26 for adjusting the span on the upper surface of the measurement housing 1 and in the vicinity of the upper part of the center of the scale 3. A weight placing portion 1A is provided.
Every time the weight of the filling gas is measured or the measuring place changes, the weight 26 having the traceability of measurement is placed on the weight placing part 1A, and the span adjustment (variation range adjustment) of the scale 3 is performed. )I do. Thus, even if there is a temperature change, an atmospheric pressure change, or a change in altitude or latitude at the measurement location, the influence thereof can be eliminated and highly accurate weight measurement by the scale 3 can be performed.

The calibration device 100-1 according to the second embodiment is different from the calibration device 100 of FIGS. 1 and 2 in that the support member 14 (14A, 14B) that fixes the filling gas supply pipeline 7 to the bottom surface of the measurement housing 1 is used. , 14C) has increased to three. Further, the support member 15 for fixing the filling gas discharge conduit 11B to the outer wall portion of the measurement housing 1 is upsized.
In FIG. 5, members R1, R2, and R3 represent rigid members, and strengthen the fixing of the receptacle 6, the filling gas supply conduit 7, and the dry gas conduit 4 to the measurement housing 1, respectively.

In FIG. 5, the scale 3 is installed on the bottom of the main body housing 10 by the installation member 12. The installation member 12 is configured by a lock mechanism 12B, and the lock mechanism 12B fixes the foot portion 12A and the foot portion 12A supporting the balance pedestal portion 3A of the balance 3 to the bottom portion 10B of the main body housing 10.
When the calibration device 100-1 is stored or moved, the foot portion 12A is fixed to the bottom portion 10B by the lock mechanism 12B, and the scale 3 is securely fixed to the main body housing 10.
On the other hand, at the time of measuring the weight of the filling gas, the lock mechanism 12B is unlocked so that the installation member 12 is not fixed to the main body housing 10 (so-called "free" state), and the scale 3 is thus fixed. Free from 10. When the scale 3 is freed from the main body housing 10, strain and bending of the main body housing 10 and thermal expansion and contraction due to temperature change are not transmitted to the scale 3 via the installation portion 12 when measuring the weight, and the weight is measured. This is because there is no error in the result of.

In FIG. 5, a fixing device 15 is provided on the peripheral portion of the scale 3, and the fixing device 15 has an action of unloading the scale 3 during measurement and securely and safely fixing the measurement housing 1. The fixing device 15 includes a horizontally extending pin-shaped member 151 and an L-shaped member 152. The L-shaped member 152 is fixed to the bottom portion 10B, and the pin-shaped member 151 has a through hole ( It is configured so as to be movable in the horizontal direction (direction of arrow H) through a not shown).
Although not shown, the fixing device 15 can also be provided in the calibration devices 100, 100-2, 100-3 shown in FIGS. 1, 2, 6, and 7.
Although not clearly shown in FIG. 5, three adjustment support members (not shown) are provided below the installation member of the scale 3, and the adjustment support member and the level not shown should be used together. Is configured so that the level of the scale 3 can be quickly and accurately obtained.

In the calibration device 100-1 as well, as in the calibration device 100 of the first embodiment shown in FIGS. 1 and 2, hydrogen gas is supplied from the hydrogen filling device (not shown in FIG. 5) to the filling tank 2 of the calibration device 100-1. Communication filling is performed when filling. In order to transmit the output signal (pressure information, temperature information) of the sensor (not shown) in the filling tank 2 to the hydrogen filling side, the calibration device 100-1 has a communication path 18-1 as a signal transmitting means. ing.
The communication path 18-1 on the side of the calibration device is composed of a conductor for an electric signal, and an electric signal obtained by converting an optical signal is transmitted. However, the communication path 18-1 may be configured by an optical fiber as an optical communication path. I can. One end of the communication path 18-1 is connected to the sensor in the filling tank 2 via an optical communication connector (not shown), and the other end is connected to an optical communication connector (not shown) built in the calibration device side receptacle 6. There is.

When the calibration device side receptacle 6 and the filling nozzle (not shown) of the hydrogen filling device are connected at the time of calibration, the communication path 18-1 is provided with an unillustrated optical communication connector built in the calibration device side receptacle 6. , Is connected to a communication path (not shown) on the filling device side via an optical communication connector (not shown) on the filling nozzle side. As a result, the output signal of the sensor in the filling tank 2 is transmitted to the hydrogen filling device (not shown in FIG. 5), and the communication filling is performed. Here, when the filling nozzle 41 is connected to the calibration device side receptacle 6, the optical communication connector (not shown) built in the filling nozzle 41 and the optical communication connector (not shown) built in the calibration device side receptacle 6 are connected. , Exchanges optical signals (optical communication).
Also in the second embodiment, as in the case shown in FIG. 2, the calibration device 100-1 can be mounted or mounted on the calibration vehicle PS.
Other configurations and operational effects of the second embodiment of FIG. 5 are similar to those of the first embodiment of FIGS.

In the third embodiment shown in FIG. 6, a calibration device different from that in FIG. 5 is used.
Hereinafter, in the third embodiment of FIG. 6, points different from the calibration device shown in FIGS. 1 to 5 will be mainly described.
In the calibration device 100-2 used in the third embodiment of FIG. 6, the measurement housing 1 is formed of a polycarbonate resin having an antistatic function. Polycarbonate resin is a high-strength transparent material, so that the inside of the measurement housing 1 is visible from the outside. Further, even if the wall thickness of the measurement housing 1 is reduced to reduce the weight, the measurement housing 1 can have a predetermined strength. Furthermore, since it is made of polycarbonate resin with antistatic function, it can prevent the generation of static electricity and ensure the safety as a device that handles hydrogen gas.

In FIG. 6, a thermometer 19 and a pressure gauge 20 are installed in the filling gas supply pipe 7 as a supply gas state monitoring device, and a temperature transmitter 21, a pressure transmitter 22 and a flowmeter 23 are also installed. Has been done.
The temperature transmitter 21 transmits the measurement data of the thermometer 19 to a location separated from the measurement housing 1 (for example, an information processing device of a hydrogen station office: not shown) wirelessly or by wire, and the pressure transmitter 22 transmits the pressure gauge 20. The measurement data of 1 is transmitted to a location separated from the measurement housing 1 wirelessly or by wire.

The measurement results of the thermometer 19 and the pressure gauge 20 can be visually confirmed by the site worker through the measurement housing 1 made of polycarbonate resin having an antistatic function and visible from the outside. The administrator can confirm the temperature transmitter 21, the pressure transmitter 22, and the flow meter 23 at a remote place apart from the site.
Each of the temperature transmitter 21, the pressure transmitter 22, and the flow meter 23 is provided with a conventionally known alarm means (not shown), and when an abnormal value is detected in each measurement result, an alarm sound etc. is given to an operator in the field. It is possible to notify the administrator and the like stationed at a place away from the site by an alarm sound or the like.

Further, in the calibration device 100-2 of the third embodiment of FIG. 6, the exhaust gas mechanism 11 is different as compared with the embodiments of FIGS. 1 to 5.
In FIG. 6, a branch portion 7A is provided in the filling gas supply pipeline 7, and a pressure reducing valve 16 is provided in the filling gas release pipeline 11B that connects the branch portion 7A and the shutoff valve 17. The shutoff valve 17 arranged on the side surface portion (right side surface in FIG. 1) of the measurement housing 1 is shut off when the filling tank 2 is filled with hydrogen gas, and is opened when the hydrogen gas is discharged from the filling tank 2.

After the calibration is completed, the hydrogen filled in the filling tank 2 is opened by opening the opening/closing mechanism 11A of the exhaust gas mechanism 11, so that the filling gas supply pipe line 7, the branch portion 7A, the filling gas discharge pipe line 11B, and the pressure reducing valve. The gas is discharged to the outside of the calibration device 100 via 16, the shutoff valve 17, the external discharge pipe 24, and the gas discharge mechanism of the main body housing 10 (not shown). At that time, the released hydrogen gas is decompressed to a low pressure (for example, less than 1 MPa) by the decompression valve 16. Reference numeral 25 is a pressure gauge for measuring the pressure of the passing hydrogen gas.
At the time of hydrogen gas release, even if the hydrogen gas tries to flow from the branch portion 7A of the filling gas supply pipeline 7 toward the receptacle 6, it is blocked by the check valve 9 and prevented from being released (leaked) to the receptacle 6 side. It

Even in the calibration device 100-2 of FIG. 6, communication filling is performed when the filling tank 2 is filled with hydrogen gas.
The calibration device 100-2 has a communication path 18-2 as a signal transmission means for transmitting an output signal of a sensor (pressure sensor, temperature sensor) not shown in the filling tank 2 to the hydrogen filling device. The communication path 18-2 is the same as that described with reference to FIGS.
The calibration device 100-2 of FIG. 6 can also be mounted or mounted on the calibration vehicle PS (FIG. 2) as shown in FIG.
Other configurations and operational effects of the third embodiment of FIG. 6 are similar to those of the respective embodiments of FIGS.

In the fourth embodiment shown in FIG. 7, a calibration device different from that in FIG. 6 is used.
Hereinafter, in the fourth embodiment of FIG. 7, differences from the calibration devices 100, 100-1, 100-2 used in the embodiments of FIGS. 1 to 6 will be mainly described.
The calibration device 100-3 of FIG. 7 is equipped with a control unit CU, and the control unit CU controls to eliminate the error caused by the fluctuation of the buoyancy of gas (dry air, nitrogen) in the measurement housing 1 before and after filling with hydrogen gas. Is doing. The control unit CU is connected to the scale 3 by an input signal line ISL1 and is connected to the temperature sensor T by an input signal line ISL2. The temperature sensor T is installed near the surface of the filling tank 2.

When the error is eliminated, the control unit CU obtains a fluctuation amount ΔF in which the buoyancy of the gas in the measurement housing 1 changes before and after the hydrogen gas filling, and corrects the hydrogen filling amount ΔW (weight) by the fluctuation amount ΔF to correct it. The subsequent filling amount ΔWt (weight) is calculated.
That is, ΔWt=ΔW−ΔF.
The fluctuation amount ΔF is the sum of the volumes Q (solid volume) of the devices (the filling tank 2, the scale 3, the pedestal 8, the filling gas supply pipe 7, etc.) housed in the measurement housing 1, and the temperature after the filling. It is calculated by the following formula by multiplying the difference between the gas density ρ(t2) at t2 and the gas density ρ(t1) at the temperature t1 before filling. The temperatures t1 and t2 are measured by the temperature sensor T.
ΔF=Q·{ρ(t2)−ρ(t1)}
The solid volume Q is obtained by measuring the weight of the measurement housing 1 while changing the temperature from ta to tb in the closed space and changing the gas density from ρ(ta) to ρ(tb). That is, if the measurement results of the weight of the measurement housing 1 are Wta and Wtb, the solid volume Q is calculated by the following equation.
Q=(Wtb-Wta)/{ρ(tb)-ρ(ta)}

In the calibration device 100-3 of FIG. 7 as well, as in the calibration devices 100, 100-1 and 100-2 used in FIGS. 1 to 6, from the hydrogen filling device (not shown) to the filling tank 2 of the calibration device 100-3. When filling hydrogen gas, communication filling is performed.
The calibration device 100-3 has a communication path 18-3 in order to transmit the output signals of the sensors (pressure sensor, temperature sensor) not shown in the filling tank 2 to the hydrogen filling device. The configuration of the communication path 18-3 and the aspect of communication filling are the same as those in the respective embodiments of FIGS. 1 to 6.
Also in the calibration device 100-3 of FIG. 7, the calibration device 100-3 can be mounted or mounted on the calibration vehicle PS, as in the case of FIG. 2.
Other configurations and operational effects of the fourth embodiment of FIG. 7 are the same as those of the respective embodiments of FIGS.

It should be added that the illustrated embodiment is merely an example and is not intended to limit the technical scope of the present invention.

1...Measuring housing 2 Filling tank 3 Scale (weight measuring device)
6... Receptacle 11... Exhaust gas mechanism 18... Calibration device side communication path (signal transmission means)
31... In-vehicle tank (fuel storage device for calibration vehicle)
32... Hydrogen supply pipe 33... Open/close valve (flow rate adjusting valve)
40... Hydrogen filling device 41... Filling nozzle 42... Filling hose 100... Calibration device PS... Calibration vehicle

Claims (4)

A step of connecting a filling tank, a measuring housing containing the filling tank, and a filling nozzle of a hydrogen filling device to be calibrated to a receptacle of a calibration device having a weight measuring device for measuring the weight of the measuring housing;
Filling the filling tank of the calibration device with hydrogen gas,
Determining the amount of hydrogen filled in the filling tank of the calibration device based on the difference between the weight of the measurement housing before hydrogen filling and the weight of the measurement housing after hydrogen filling;
A method for calibrating a hydrogen filling device, comprising the step of releasing hydrogen filled in a filling tank via an exhaust gas mechanism provided in the calibrating device. The calibration method according to claim 1, wherein the step of determining the hydrogen amount can be performed after the step of filling the hydrogen gas is completed. The calibration device is installed in the vehicle,
A vehicle equipped with a calibration device is a vehicle that is driven by multiple types of fuel including hydrogen,
An opening/closing valve is provided in a path connecting the filling tank of the calibration device and the fuel storage device of the vehicle.
3. The method according to claim 1, further comprising the step of closing the opening/closing valve when the vehicle is stopped and performing a calibration operation, and opening the opening/closing valve when the vehicle is traveling. The calibration method described. The calibration device is
It is equipped with a receptacle that can be connected to and removed from the filling nozzle at the tip of the filling hose of the hydrogen filling device, and a signal transmission means for transmitting information in the filling tank.
The calibration method according to claim 1, wherein in the step of filling the filling tank with hydrogen gas, the information in the filling tank is transmitted to a hydrogen filling device.

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