JP2007024152A - Gas supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To correct a pressure difference in a gas filling hose after supplying gas while considering volume expansion with the temperature rise of the gas. <P>SOLUTION: The gas supply device comprises a control device 16 which consists of a before-supply gas amount computing means for computing the amount of gas on the downstream side of a gas supply on-off valve 22 in a gas supply passage 18 before supplying the gas, in accordance with the capacity of the gas supply passage 18 downstream of the gas supply on-off valve 22, a temperature value detected by a temperature sensor 27 and a pressure value detected by a pressure sensor 30, an after-supply gas amount computing means for computing the amount of gas on the downstream side of the gas supply on-off valve 22 in the gas supply passage 18 after supplying the gas, in accordance with the capacity of the gas supply passage 18 downstream of the gas supply on-off valve 22, a temperature value detected by a temperature sensor 47 and a pressure value detected by the pressure sensor 30, and a filling amount computing means for computing a gas amount difference between a before-supply gas amount and an after-supply gas amount and subtracting the gas amount difference from a supply amount measured by a flow meter 26 to compute the amount of the gas supplied to a fuel tank 12. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a gas supply device, and more particularly to a gas supply device configured to accurately calculate a supply amount of a gas supplied to a supply target.

  In the gas supply device, the compressed gas is stored in the gas accumulator, the connection coupling of the gas filling hose is connected to the connection coupling on the supply side, and the three-way valve communicated with the tip of the gas filling hose For example, the fuel stored in the gas accumulator is filled in a fuel tank (supplied body) of an automobile (see, for example, Patent Document 1).

In the above gas supply device, the pressure difference between the pressure value before starting gas filling measured by the pressure sensor and the gas filling end pressure value at the end of filling is obtained, and the gas supply line and the filling downstream of the flow meter are used for this pressure difference. The filling correction value is calculated by multiplying the volume of the hose. Then, by subtracting the calculated filling correction amount from the total filling amount, by correcting the flow rate error due to the difference in the residual pressure of the filling hose, it depends on the pressure difference between the gas filling start pressure value and the gas filling end pressure value. The error is eliminated.
JP 2004-257525 A

  However, in the above conventional gas supply device, when correcting the error due to the pressure difference between the gas filling start pressure value and the gas filling end pressure value, the volume of the gas expands due to the temperature rise accompanying the pressure rise during gas filling. The amount of increase due to thermal expansion due to the temperature difference between the gas temperature before the start of gas filling and the gas temperature at the end of gas filling cannot be accurately corrected, and the measured gas filling amount is corrected accordingly. There was a problem that an error occurred in the gas supply amount value.

  Then, an object of this invention is to provide the gas supply apparatus which solved the said subject.

  In order to solve the above problems, the present invention has the following means.

The present invention includes a filling coupling provided at a downstream end of a gas supply path for supplying compressed gas;
A valve provided in the gas supply path;
A flow rate measuring unit for measuring a supply amount flowing through the gas supply path by opening the valve;
A pressure measurement unit that is provided on the downstream side of the position where the valve is provided in the gas supply path, and measures the pressure of the gas in the gas supply path;
Control means for closing the valve when the supply amount measured by the flow rate measurement unit or the pressure measured by the pressure measurement unit reaches a predetermined target value for completion of filling;
In a gas supply device having
Temperature measuring means for measuring the temperature of the gas flowing through the gas supply path;
The amount of gas downstream from the valve in the gas supply path before supplying gas to the supply target, the volume of the gas supply path downstream from the valve, and temperature data measured by the temperature measuring means, A pre-supply gas amount calculating means for calculating based on the pressure value measured by the pressure measuring unit;
Temperature data measured by the temperature measuring means and the volume of the gas supply path downstream of the valve and the gas amount downstream of the valve in the gas supply path after the gas supply to the supply target is completed. And a gas amount calculating means after completion of supply that calculates based on the pressure value measured by the pressure measuring unit,
Subtract the gas amount difference between the pre-supply gas amount calculated by the pre-supply gas amount calculation means and the post-supply gas amount calculated by the post-supply gas amount calculation means from the supply amount measured by the flow rate measuring unit A filling amount calculating means for calculating a gas supply amount supplied to the supply target body;
It is provided with.

  According to the present invention, the gas amount downstream of the valve in the gas supply path before and after the gas supply to the supply target is measured by the volume of the gas supply path downstream from the valve and the temperature measuring means. Is calculated based on the measured temperature data and the pressure value measured by the pressure measurement unit, and the pre-supply gas amount and the post-supply gas calculated by the pre-supply gas amount calculation means from the supply amount measured by the flow rate measurement unit In order to calculate the gas supply amount supplied to the supply object by subtracting the gas amount difference from the post-supply gas amount calculated by the amount calculation means, the gas temperature before the start of gas filling and the gas temperature at the end of gas filling The amount of increase due to thermal expansion due to the temperature difference of the gas can be accurately corrected, and the difference in volume expansion of the gas caused by the gas temperature before the gas supply and the rising temperature due to the pressure increase after the gas supply ends can be considered. Measured It becomes possible to accurately correct the scan feed amount.

  Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic configuration diagram showing an embodiment of a gas supply apparatus according to the present invention. As shown in FIG. 1, the gas supply device 10 is installed, for example, in a gas supply station that supplies compressed gas to a fuel tank (supplied body) 12 of an automobile. The supplied gas is a gas that is compressed and used at a high pressure such as compressed natural gas.

  The gas supply device 10 is roughly composed of a gas accumulator (gas supply source) 14 for storing gas compressed to a high pressure, a dispenser unit 15 for supplying gas from the gas accumulator 14 to the fuel tank 12, and these The controller 16 controls each device of the dispenser unit 15.

  The dispenser unit 15 is provided with a gas supply path 18 communicated with the gas pressure accumulator 14. The gas supply path 18 includes a primary pressure gauge 20, a gas supply opening / closing valve 22, a control valve 24, a flow meter ( A flow rate measuring means) 26, a pressure sensor (pressure measuring means) 30, a secondary pressure gauge 32, and a safety valve 34 are provided.

  Further, a gas filling hose 44 is connected downstream of the gas supply path 18 via an emergency disconnection coupler 42. At the tip of the gas filling hose 44, a filling coupling 46 coupled to the filling port 12a of the fuel tank 12 is provided. The filling coupling 46 is provided with a depressurization hose 36, and the other end of the depressurization hose 36 is communicated with the gas diffusion port 38. In addition, a depressurization path 37 that branches from the gas supply path 18 is provided with a depressurization valve 40 that discharges gas to the gas diffusion port 38. A check valve 13 is provided between the fuel tank 12 and the filling port 12a to prevent backflow.

  The filling coupling 46 is provided with a temperature sensor (temperature measuring means) 47 for measuring the temperature of the supplied gas as will be described later. The temperature sensor 47 measures the temperature of the gas supplied to the fuel tank 12 via the filling coupling 46 and outputs a temperature detection signal to the control device 16. Then, the control device 16 converts the flow rate of the reference temperature (for example, 15 ° C.) with respect to the temperature measured when calculating the gas supply amount supplied to the gas filling hose 44, as will be described later, and calculates the temperature correction. To do.

  The dispenser unit 15 also opens the filling start switch 50 that is operated with the filling coupling 46 coupled to the filling port 12 a of the fuel tank 12, the filling stop switch 52 that stops filling, and the pressure release valve 40. An in-hose depressurization switch 54 that is operated when depressurizing the gas in the gas supply path 18 is provided. A gas supply path 56 that communicates between the gas pressure accumulator 14 and the gas supply path 18 is provided with a main valve 57 that is an electromagnetic valve and a check valve 58 that prevents backflow.

  The control device 16 controls each device arranged in the dispenser unit 15 based on a control law stored in the memory 48 in advance. When the filling start switch 50 is turned on, the flow meter 26 measures the device. The valve opening degree of the control valve 24 is controlled so that the measured flow rate value becomes the target flow rate.

  Further, the memory 48 stores the amount of gas downstream from the gas supply opening / closing valve 22 in the gas supply path 18 before supplying gas to the fuel tank 12, and the volume of the gas supply path 18 downstream from the gas supply opening / closing valve 22. And a control program (pre-supply gas amount calculation means) that calculates based on the temperature data measured by the temperature sensor 27 and the pressure value measured by the pressure sensor 30, and gas supply after the gas supply to the fuel tank 12 ends The amount of gas downstream of the gas supply opening / closing valve 22 in the path 18 was measured by the volume of the gas supply path 18 downstream of the gas supply opening / closing valve 22, the temperature data measured by the temperature sensor 47, and the pressure sensor 30. A control program for calculating based on the pressure value (after-supply gas amount calculating means) and a pre-supply gas amount calculating means from the supply amount measured by the flow meter 26 A control program (filling) that calculates the gas supply amount supplied to the fuel tank 12 by subtracting the gas amount difference between the pre-supply gas amount calculated by the calculation and the post-supply gas amount calculation means calculated by the post-supply gas amount calculation means (Quantity calculating means). The control device 16 reads each control program stored in the memory 48 and performs correction calculation in consideration of pressure and temperature, and accurately calculates the amount of gas supplied to the fuel tank 12.

  FIG. 2 is a block diagram showing each device connected to the control device 16. As shown in FIG. 2, the control device 16 includes a gas supply opening / closing valve 22, a control valve 24, a flow meter 26, a pressure sensor 30, a depressurization valve 40, a temperature sensor 47, a memory 48, a filling start switch 50, and a filling stop switch. 52, the main valve 57, the in-hose pressure release switch 54, and the nozzle switch 67 are connected.

  The flow meter 26 is a Coriolis mass flow meter, measures the flow rate of the gas supplied through the gas supply path 18, and outputs a signal corresponding to the flow rate to the control device 16.

  Further, the gas supply opening / closing valve 22 and the depressurization valve 40 are composed of electromagnetic valves or the like, and are opened or closed by turning on / off a valve opening signal from the control device 16.

  The control valve 24 is adjusted to an arbitrary valve opening degree according to a command from the control device 16 and operates to control the gas pressure or flow rate based on a preset control law.

  FIG. 3 is a front view of the dispenser unit 15. FIG. 4 is an enlarged side view showing the filling coupling 46. As shown in FIGS. 3 and 4, the dispenser unit 15 is provided with a pressure-proof explosion-proof case 61 that houses the above-described device, the control device 16, and the memory 48 inside the housing 60. Further, a display 62 for displaying the supplied gas supply amount is provided on the front surface of the housing 60.

  Further, at the upper part of the side surface of the housing 60, there are a joint 64 that communicates with the base end of the gas filling hose 44 and a latching portion 66 that latches the filling coupling 46 that communicates with the tip of the gas filling hose 44. Is provided. The latching portion 66 is provided with a nozzle switch 67 that detects that the filling coupling 46 is latched and outputs a detection signal to the control circuit 16. Further, the filling coupling 46 is provided with a filling nozzle 68, a three-way valve 70, and a temperature sensor 47. The signal line 72 connected to the temperature sensor 47 drawn out in parallel from the filling coupling 46 is drawn into the housing 62 via the joint 64.

  Further, in the filling coupling 46, the gas filling hose 44 and the decompression hose 36 are connected to the hose connection parts 72 and 73 of the three-way valve 70, and the connecting part 74 of the gas filling hose 44 connected to the hose connection part 72. A temperature sensor 47 is attached to the outer periphery of the. Therefore, the temperature sensor 47 can detect a temperature change that rises as the pressure of the gas flowing in the gas filling hose 44 rises with the filling coupling 46 closest to the fuel tank 12. Therefore, the temperature sensor 47 can detect the temperature of the gas supplied to the fuel tank 12 near the fuel tank 12.

  Further, the switching operation handle 70a provided at the upper part of the three-way valve 70 is rotated to a position where the filling nozzle 68 and the gas filling hose 44 communicate with each other at the time of gas supply, and filling is performed at the time of depressurization after the gas supply ends. The nozzle 68 and the decompression hose 36 are rotated to a position where they communicate with each other.

  Here, the gas filling control process executed by the control device 16 will be described with reference to the flowchart of FIG. When the vehicle that receives the gas filling arrives, the worker connects the filling coupling 46 to the filling port 12a of the fuel tank 12, and then turns the switching operation handle 70a of the three-way valve 70 to rotate the filling nozzle 68 and the gas. The filling hose 44 is communicated. As a result, the gas filled in the gas supply path 18 and the gas filling hose 44 downstream from the gas supply opening / closing valve 22 flows into the fuel tank 12.

  When the coupling 46 is removed from the latching portion 66 (see FIG. 3) of the housing 60 and the nozzle switch 67 is turned off in S11 shown in FIG. 5, the control device 16 supplies the gas downstream from the gas supply opening / closing valve 22. The amount of gas in the path 18 and the gas filling hose 44 is calculated. In the calculation at the initial stage before the gas supply to the fuel tank 12 is started, the volume of the hose is obtained from the volume of the gas supply path 18 downstream from the gas supply opening / closing valve 22 and the inner diameter and the total length of the gas filling hose 44. The volume value before the start of gas supply is obtained by multiplying the volume value by the pressure value detected by the pressure sensor 30.

When the filling start switch 50 is turned on in the next S12, the process proceeds to S13, and the current gas temperature T detected by the temperature sensor 47 is read. Then, the gas amount before starting the gas supply is converted into a gas amount V _TA with respect to the reference temperature, and the temperature-corrected gas amount V _TA is stored in the memory 48.

  In next S14, the main valve 57 of the gas pressure accumulator 14, the gas supply opening / closing valve 22 of the gas supply path 18, and the control valve 24 are opened. Thereby, the gas accumulated in the gas accumulator 14 is supplied to the fuel tank 12 via the gas supply path 18 and the gas filling hose 44.

Then, the process proceeds to S15, reads the pressure value P detected by the pressure sensor 30, the current charging pressure P confirms whether reaches the target pressure P _0. In this S15, when the current charging pressure P has not reached the target pressure P _0, the process proceeds to S16, reads the temperature detection signal detected by the temperature sensor 47, the current detected temperature T is set in advance 1 to check whether higher or not than the set temperature T _a. In this S16, the current detected temperature T when lower than the first set temperature T _A, the gas temperature, which is filled in the fuel tank 12 is still low, the process proceeds to S17, the pressure value P detected by the pressure sensor 30 read, the current filling pressure P is to check whether or not reached the target pressure P _0.

In S17, when the current charging pressure P has not reached the target pressure _{P 0,} still to continue the gas supply, the flow returns to S16, and repeats the processing of S16, S17. Further, in S17, when the current charging pressure P reaches the target pressure _{P 0,} the process proceeds to S18, main valve 57 of the gas accumulator 14, the gas supply on-off valve 22 of the gas supply path 18, the control valve 24 closed I speak.

Thereafter, in S 19, the amount of gas in the gas supply path 18 and the gas filling hose 44 downstream from the gas supply opening / closing valve 22 at the stage after completion of gas supply to the fuel tank 12 is calculated. In this calculation, the internal volume of the hose is obtained from the volume of the gas supply path 18 downstream from the gas supply opening / closing valve 22 and the inner diameter and the total length of the gas filling hose 44, and the target pressure P ₀ detected by the pressure sensor 30 is obtained as the volume value. To obtain the amount of gas after the gas supply is completed. Further, the current gas temperature T detected by the temperature sensor 47 is read. Then, the gas amount after the end of the gas supply is converted into a gas amount V _TB with respect to the reference temperature, and the temperature-corrected gas amount V _TB is stored in the memory 48.

  Then, it progresses to S20 and it is confirmed whether the gas filling with respect to the said fuel tank 12 was completed. In S 20, the switching operation handle 70 a of the three-way valve 70 is rotated, and the filling nozzle 68 and the decompression hose 36 are communicated to depressurize the inside of the filling coupling 46, and the filling coupling 46 is removed from the housing 60. The nozzle switch 67 is turned on by being hooked on the hook 66 (see FIG. 3), or when the filling stop switch 52 is turned on, it is determined that the filling is completed and the process proceeds to S21.

In S21, the temperature-corrected gas amounts V _TA and V _TB stored in the memory 48 are read, the temperature-corrected gas amount V _TA before the start of supply, and the temperature-corrected gas amount V _TB after the end of supply, and If there is a difference (V _TA <V _TB ), the difference between both gas amounts in the hose (V _TB −V _TA ) is obtained, and the gas amount in the hose is calculated from the gas supply amount measured by the flow meter 26. If the difference (V _TB −V _TA ) is subtracted and the reverse (V _TA > V _TB ), the gas amount difference (V _TA −V _TB ) in both the hoses is obtained, and the gas supply measured by the flow meter 26 Add the difference in gas amount in the hose (V _TA -V _TB ) from the amount. Thereby, the gas supply amount corrected so that the gas supply amount measured by the flow meter 26 is not affected by the pressure difference and the temperature difference can be accurately calculated.

In the next S22, the gas amounts V _TA and V _TB stored in the memory 48 are cleared. This completes the current gas filling control process.

Further, in the above S16, the current detected temperature T when the above first predetermined temperature T _A, the gas temperature, which is filled in the fuel tank 12 is high, migration to the current detected temperature T is set in advance to S26 Whether the temperature is higher than the second set temperature T _B (> T _A ). In this S26, if the current detected temperature T is less than the second predetermined temperature T _B, the gas temperature, which is filled in the fuel tank 12 is lower than the allowable temperature, the process proceeds to S27, the valve opening of the control valve 24 1 The flow rate of the gas supply to the stage throttle and the fuel tank 12 is reduced. Thereby, it becomes possible to suppress the temperature rise of the gas filled in the fuel tank 12. Thereafter, the process returns to S16, and the processes after S16 are performed.

Further, in the above S26, the current detected temperature T when the above second predetermined temperature T _B, the gas temperature, which is filled in the fuel tank 12 has exceeded the permissible temperature, the processing proceeds to S28, a gas accumulator 14 The main valve 57, the gas supply opening / closing valve 22 of the gas supply path 18, and the control valve 24 are closed to urgently stop the gas supply, and an alarm is issued to notify that an abnormality has occurred. Thereafter, all processing is stopped.

  Thus, the gas supply amount supplied in the gas supply path before the gas supply calculated and stored in S13 and the gas supply supplied in the gas supply path after the gas supply calculated and stored in S19. Since the amount is calculated based on the volume of the gas supply path 18 downstream from the gas supply opening / closing valve 22, the temperature data measured by the temperature sensor 47, and the pressure value measured by the pressure sensor 30, The volume expansion of the gas caused by the gas temperature before the gas supply and the rising temperature with the pressure increase after the gas supply can be accurately compensated for the increase due to the thermal expansion due to the temperature difference between the gas temperature and the gas temperature at the end of the gas filling. The difference can be taken into account, and the measured gas supply amount can be accurately corrected accordingly.

  Of course, the gas supplied in the above embodiment can be applied to supply CNG, hydrogen gas consumed by a fuel cell vehicle, or gas such as butane and propane.

  Moreover, in the above embodiment, the case where the compressed gas is filled in the fuel tank of the automobile is given as an example. However, the present invention is not limited thereto, and can be applied to an apparatus for supplying the compressed gas to other containers, Of course, the present invention can also be applied to an apparatus configured to be installed in the middle of a pipeline for feeding compressed gas to another place.

In the above embodiment, whether or not the current filling pressure P has reached the target pressure P ₀ is confirmed in S17. However, the present embodiment is not limited to this, and the current filling measured by the flow meter 26 in S17. It may be confirmed whether or not the supply amount (integrated flow rate) has reached the target supply amount.

It is a schematic block diagram which shows one Example of the gas supply apparatus which becomes this invention. FIG. 3 is a block diagram showing each device connected to the control device 16. 3 is a front view of the dispenser unit 15. FIG. It is a side view which expands and shows the filling coupling 46. FIG. 4 is a flowchart for explaining a gas filling control process executed by a control device 16;

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Gas supply apparatus 12 Fuel tank 14 Gas accumulator 15 Dispenser unit 16 Control apparatus 18 Gas supply path 22 Gas supply on-off valve 24 Control valve 26 Flow meter 24 Gas supply on-off valve 26 Control valve 30 Pressure sensor 40 Decompression valve 46 Filling coupling 47 Temperature sensor 48 Memory 50 Filling start switch

Claims (1)

A filling coupling provided at the downstream end of the gas supply path for supplying the compressed gas;
A valve provided in the gas supply path;
A flow rate measuring unit for measuring a supply amount flowing through the gas supply path by opening the valve;
A pressure measurement unit that is provided on the downstream side of the position where the valve is provided in the gas supply path, and measures the pressure of the gas in the gas supply path;
Control means for closing the valve when the supply amount measured by the flow rate measurement unit or the pressure measured by the pressure measurement unit reaches a predetermined target value for completion of filling;
In a gas supply device having
Temperature measuring means for measuring the temperature of the gas flowing through the gas supply path;
The amount of gas downstream from the valve in the gas supply path before supplying gas to the supply target, the volume of the gas supply path downstream from the valve, and temperature data measured by the temperature measuring means, A pre-supply gas amount calculating means for calculating based on the pressure value measured by the pressure measuring unit;
Temperature data measured by the temperature measuring means and the volume of the gas supply path downstream of the valve and the gas amount downstream of the valve in the gas supply path after the gas supply to the supply target is completed. And a gas amount calculating means after completion of supply that calculates based on the pressure value measured by the pressure measuring unit,
Subtract the gas amount difference between the pre-supply gas amount calculated by the pre-supply gas amount calculation means and the post-supply gas amount calculated by the post-supply gas amount calculation means from the supply amount measured by the flow rate measuring unit A filling amount calculating means for calculating a gas supply amount supplied to the supply target body;
A gas supply device comprising:

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