JP5355639B2 - Hydrogen station - Google Patents

Description

  The present invention relates to a hydrogen station, and more particularly to a hydrogen station having a hydrogen production apparatus.

In recent years, hydrogen that does not emit CO2 due to combustion has attracted attention as clean energy. In addition, fuel cell vehicles (FCV) using hydrogen as fuel are free from problems caused by exhaust gas compared to gasoline engine vehicles, and have the advantage that they can be operated over long distances compared to electric vehicles. It has been. Furthermore, the promotion of the installation of a hydrogen station is being promoted as a fuel supply means for fuel cell vehicles.
The hydrogen station has a hydrogen station (on-site type hydrogen station) equipped with a hydrogen production device, and a hydrogen station (off-site type) that does not have a hydrogen production device and stores pressure by receiving supply from a hydrogen production facility, on-site type hydrogen station, etc. Classified as a site-type hydrogen station).

Among these, the configuration of the on-site type hydrogen station is disclosed in Patent Document 1, for example. As shown in FIG. 11, a hydrogen station 100 according to this document includes a hydrogen production unit 101 (corresponding to the hydrogen production apparatus of the present application), and a pressure increase unit 102 (compressed pressure) for compressing hydrogen produced by the hydrogen production unit 101 to a predetermined pressure. Apparatus), a plurality of gas storage units 103 (same fixed pressure accumulators) for storing hydrogen compressed by the pressure boosting unit 102, and a mobile hydrogen storage facility (same as the supply source for the off-site type hydrogen station 107) Portable pressure accumulator) 104 and dispenser units 105 and 108 for supplying hydrogen from a gas storage unit 103 or mobile hydrogen storage equipment to a fuel cell vehicle or the like.
With such a configuration, problems such as ensuring work efficiency and safety associated with replacement of inert gas when hydrogen gas is transported by a hydrogen gas trailer and supplied to a mobile (off-site) hydrogen station. Has been eliminated.

JP 2009-236270 A

The hydrogen station 100 has a configuration in which a fixed pressure accumulator and a portable pressure accumulator are simultaneously charged with hydrogen while a portable pressure accumulator is connected. For this reason, although it functions as a shipping facility for the portable pressure accumulator, it does not have a function of supplying hydrogen from the portable pressure accumulator via the dispenser.
For this reason, when a failure occurs in the hydrogen production apparatus, there is an inconvenience that a portable pressure accumulator shipped from another hydrogen production base is connected and hydrogen cannot be supplied to a vehicle or the like. In particular, since hydrogen supply to commercial vehicles such as buses and trucks requires higher supply stability, it is necessary to equip a plurality of systems for hydrogen production with the system of the above-mentioned literature 1, which causes a cost increase.

The present invention is for solving the above-described problems, and provides a hydrogen station capable of reducing costs while ensuring supply stability.
The gist of the present invention is as follows. That is,
A first invention is a hydrogen station equipped with a hydrogen production apparatus,
A booster (6) for boosting the hydrogen produced by the hydrogen production device (2) to a predetermined pressure;
A fixed pressure accumulator (S1) for storing hydrogen boosted by the booster (6);
A portable pressure accumulator (Ca) that stores hydrogen boosted by the pressure booster (6) and is movable to the outside;
A dispenser (3) for supplying hydrogen in the fixed pressure accumulator (S1) or portable pressure accumulator (Ca) to the vehicle;
A boosting system (R1) connecting the hydrogen production device (2) and the boosting device (6);
A pressure increasing system (R6) connecting the portable pressure accumulator (Ca) and the pressure increasing device (6) through the pressure reducing valve (4);
A filling system (R2) connecting the booster (6) and the fixed accumulator (S1);
A filling system (R3) connecting the booster (6) and the portable pressure accumulator (Ca);
A hydrogen supply system (R4) connecting the fixed pressure accumulator (S1) and the dispenser (3);
A hydrogen supply system (R5) connecting the portable pressure accumulator (Ca) and the dispenser (3);
A hydrogen filling system (R7) connecting the portable pressure accumulator (Ca) and the fixed pressure accumulator (S1);
And comprising
By appropriately switching each system (R1-R7), hydrogen is charged from the portable pressure accumulator (Ca) directly or through the pressure booster (6) to the fixed pressure accumulator (S1), and the dispenser (3) is charged with hydrogen. It is configured to be able to supply.

In the present invention, the “hydrogen production apparatus” means producing hydrogen by various methods such as steam reforming of hydrocarbon-based raw materials such as city gas, desulfurized gasoline, naphtha, and methanol, purification separation from iron-making COG, and alkaline water electrolysis. Refers to the device.
The system (R1-R7) can be switched by, for example, providing a channel switching means such as a switching valve in the system and appropriately operating it. Specifically, for example, when hydrogen is directly supplied from the portable pressure accumulator (Ca) to the fixed pressure accumulator (S1) or the dispenser (3) as described later (see FIG. 2 (e)), R6 and R2 This is possible by opening the system and closing the other systems. The same applies to each of the following inventions.

According to a second invention, in the first invention, the high pressure booster further boosts the hydrogen produced by the hydrogen production device (2) to a first high pressure setting pressure ( _PH1 ) higher than that of the booster device (6). A device (21);
A fixed high pressure accumulator (S2) for storing hydrogen boosted by the high pressure booster (21);
A pressure increasing system (R21) connecting the portable pressure accumulator (Ca) and the high pressure boosting device (21) with a pressure reducing valve (22) interposed therebetween;
A filling system (R22) connecting the high pressure booster (21) and the fixed high pressure accumulator (S2);
A hydrogen supply system (R23) connecting the fixed high-pressure accumulator (S2) and the dispenser (3);
A pressure boosting / filling system (R24) connecting the fixed high pressure accumulator (S1) and the high pressure booster (21) with a pressure reducing valve (22) interposed therebetween;
And by appropriately switching each system (R21-R24),
The hydrogen stored in the portable pressure accumulator (Ca) can be charged into the fixed high pressure accumulator (S2) after being boosted by the high pressure booster (21), and
The storage type hydrogen stored in the fixed high-pressure accumulator (S2) is configured to be able to fill the vehicle with a differential pressure via the dispenser (3).

  In the present invention, “differential pressure filling” refers to filling the vehicle using the differential pressure between the fixed pressure accumulator, the portable pressure accumulator or the fixed high pressure accumulator when the filling pressure is higher than the vehicle filling pressure. Refers to the filling method.

According to a third aspect of the present invention, there is provided a high pressure booster that boosts the hydrogen produced by the hydrogen production device (2) to a second high pressure setting pressure ( _PH2 ) that is higher than the booster (6). 31) and
A pressure increasing system (R31) connecting the portable accumulator (Ca) and the high pressure boosting device (31) with a pressure reducing valve (33) interposed therebetween;
A hydrogen supply system (R32) connecting the high pressure booster (31) and the dispenser (3);
A pressure increasing system (R33) connecting the fixed high pressure accumulator (S1) and the high pressure boosting device (31) with a pressure reducing valve (33) interposed therebetween, and switching between the systems (R31-R33) as appropriate By
It is configured such that the hydrogen stored in the portable pressure accumulator (Ca) can be directly charged into the vehicle via the dispenser (3) after being boosted by the high pressure booster (31).

  The set pressure of the booster (6) and the high pressure booster (21) can be determined as appropriate based on the supply pressure to the vehicle and the maximum filling pressure (and price) of the container.

A fourth invention is a method of filling hydrogen from a portable pressure accumulator to a fixed pressure accumulator in the hydrogen station according to any one of the first to third aspects,
When the filling pressure (Pca) of the portable pressure accumulator (Ca) is higher than the pressure of the fixed pressure accumulator (S1), it is filled with a differential pressure via the filling system (R7),
In the stage where the filling by the differential pressure becomes impossible, the boosting device (6) is operated and filling is performed via the boosting system (R6).

The fifth invention is a method of supplying hydrogen to a vehicle via a dispenser in the hydrogen station according to the second invention, until reaching the standard set pressure (P _L ) from the portable pressure accumulator (Ca). Hydrogen is supplied to the dispenser (3) through the supply system (R5),
When the pressure does not reach the standard set pressure (P _L ), hydrogen is further supplied from the fixed pressure accumulator (S1) to the dispenser (3) sequentially through the supply system (R4).

A sixth invention is a method of filling hydrogen from a portable pressure accumulator to a fixed pressure accumulator (S1) or a fixed pressure accumulator (S2) in the hydrogen station according to the second invention,
When the filling pressure (Pca) of the portable pressure accumulator (Ca) is higher than the receiving pressure (Pcr (min)) of the high pressure booster (21),
The high pressure booster (21) is operated to fill the stationary accumulator (S2) with hydrogen via the boosting system (R21), and then the high pressure booster (21) is stopped and fixed according to the process of claim 4. Fill the accumulator (S1) with hydrogen,
When the charging pressure (Pca) of the portable pressure accumulator (Ca) is equal to or lower than the receiving pressure (Pcr (min)) of the high pressure booster (21), the fixed pressure accumulator (S1) is applied according to the process of claim 4. Filling with hydrogen,
It is characterized by that.

A seventh invention is a method of filling hydrogen into a vehicle through a dispenser in the hydrogen station according to the second invention,
Hydrogen is supplied from the portable pressure accumulator (Ca) to the dispenser (3) via the supply system (R5),
When it can be filled up to the standard set pressure (P _L ), it is then filled up to the first high pressure set pressure (P _H1 ) with a differential pressure from the fixed pressure accumulator (S2) via the supply system (R23),
If the standard set pressure (P _L ) cannot be charged, hydrogen is supplied from the fixed accumulator (S1) to the dispenser (3) through the supply system (R4) until the standard set pressure (P _L ) is reached,
Furthermore, it is filled with a differential pressure from the fixed pressure accumulator (S2) to the first high pressure set pressure (P _H1 ) via the supply system (R23).

The eighth invention is a method of filling hydrogen into a vehicle through a dispenser in the hydrogen station according to the third invention,
Hydrogen is supplied from the portable pressure accumulator (Ca) to the dispenser (3) via the supply system (R5),
When the pressure reaches the set standard pressure (P _L ), the high pressure booster (31) is then operated and the second high pressure set pressure (Ca) is supplied from the portable accumulator (Ca) via the supply system (R31). Up to _{pH 2} )
If the set standard pressure (P _L ) cannot be filled, the fixed pressure accumulator (S 1) is filled to the standard set pressure (P _L ) via the supply system (R 4).
Further by operating the high-pressure booster (31), filling a fixed accumulator through the supply line (R32) and the supply line (R33) from (S1) to a second high pressure set pressure _{(P H2),} that Features.

According to the present invention, since it functions as a shipping facility and a receiving facility only by switching valves of the piping system, there is an effect that the system can be simplified and the cost can be reduced.
In addition, when the pressure of the portable pressure accumulator is high at the time of acceptance, energy for operating the hydrogen compressor can be reduced by enabling hydrogen supply to the fixed pressure accumulator or the dispenser without going through the hydrogen compressor. it can.
In addition, even when the hydrogen production apparatus does not function due to a failure or the like, there is an effect that the stationary pressure accumulator and the vehicle can be filled.

It is a figure which shows the structure of the hydrogen station 1 in 1st embodiment. It is a figure which shows pressure | voltage rise system R1 in the hydrogen station 1, and filling system R2. It is a figure which shows filling system | strain R3. It is a figure which shows supply system | strain R4. It is a figure which shows supply system R5. It is a figure which shows pressure | voltage rise system R6. It is a figure which shows pressure | voltage rise system R7. FIG. 3 is a flowchart showing a filling mode of the accumulator S1 and Ca at a normal time in the hydrogen station 1. It is a flowchart which shows the acceptance aspect from the portable pressure accumulator Ca. It is a flowchart which shows the filling aspect from the portable pressure accumulator Ca to a vehicle. It is a figure which shows the structure of the hydrogen station 20 in 2nd embodiment. 2 is a diagram showing a boosting system R21 and a filling system R22 in the hydrogen station 20. FIG. It is a figure which shows the supply system | strain R23. It is a figure which shows the same pressure | voltage rise and filling system | strain R24. FIG. 4 is a flowchart showing a filling mode from the portable pressure accumulator Ca to the fixed pressure accumulators S1 and S2 in the hydrogen station 20. It is a flowchart which shows the filling aspect to the vehicle. It is a figure which shows the structure of the hydrogen station 30 in 3rd embodiment. 2 is a diagram showing a boosting system R31 and a supply system R32 in the hydrogen station 30. FIG. It is a figure which shows the same pressure | voltage rise system R33. FIG. 4 is a flowchart showing how a vehicle is filled in the hydrogen station 30. It is a figure which shows the structure of the conventional hydrogen station.

  Hereinafter, embodiments of the hydrogen station according to the present invention will be described in more detail with reference to FIGS. In order to avoid redundant description, the same reference numerals are used for the same components in the respective drawings. Needless to say, the scope of the present invention is described in the claims and is not limited to the following embodiments.

(First embodiment)
The present embodiment relates to shipping, receiving, and filling in a 35 MPa differential pressure filling station (filling 35 MPa of hydrogen filled in a 40 MPa pressure accumulator into a vehicle via a dispenser).
Referring to FIG. 1, a hydrogen station 1 according to an embodiment of the present invention includes a hydrogen production apparatus 2 for producing hydrogen by introducing 13A city gas mainly composed of methane from a city gas conduit, and a hydrogen production apparatus. 2 is configured to be attachable to and detachable from the piping system by a hydrogen compressor 6 (corresponding to the pressure booster of the claims), a fixed pressure accumulator S1 for storing the boosted hydrogen, and a connecting coupler 5. The main components are a portable pressure accumulator Ca that can be moved to the outside, a fixed pressure accumulator S1, and a dispenser 3 for supplying charged hydrogen in the portable pressure accumulator Ca to the vehicle.
The hydrogen production apparatus 2 is configured to reform hydrocarbons in city gas with a steam reformer (not shown) and further separate them with a PSA (not shown) to obtain hydrogen. Check valves 8a and 8b are interposed downstream of the hydrogen production apparatus 2 and the hydrogen compressor 6, respectively, so as to prevent backflow.

The fixed pressure accumulator S1 is configured by bundling a plurality of hydrogen storage tanks, and is generally divided into a plurality of banks of about 2 to 3 in order to increase the effective gas storage amount of charged hydrogen. ing. Filling or shipping of each bank is performed by appropriately switching a valve Vs attached to each bank.
The portable pressure accumulator Ca is also configured by bundling a plurality of hydrogen storage tanks, and the maximum filling pressure depends on the container, but 20 MPa to 35 MPa is often used.
The hydrogen compressor 6 has a capability of an outlet pressure of 40 MPa, and the receiving pressure is generally set to 0.6 to 0.7 MPa in accordance with the outlet pressure of the hydrogen production apparatus.

The main piping system of the hydrogen station 1 is composed of the following six systems. Referring to FIG. 2A, the boost system R1 is configured by connecting the hydrogen production apparatus 2 and the compressor 6 with a pipe L1. The filling system R2 is configured by connecting the compressor 6 and the fixed pressure accumulator S1 with a pipe L2.
Referring to FIG. 2 (b), the filling system R3 is configured by connecting an open / close valve (V2) in the path and connecting the compressor 6 and the portable pressure accumulator Ca with pipes L2 and L3. Yes.
Referring to FIG. 2C, the supply system R4 is configured by connecting the fixed pressure accumulator S1 and the dispenser 3 with pipes L2 and L4. On the upstream side of the dispenser 3, an open / close valve V <b> 8 is provided, and is configured to be able to open when hydrogen is supplied to the vehicle or the like via the dispenser 3.
Referring to FIG. 2D, the supply system R5 is configured by connecting an open / close valve (V2) in the path and connecting the portable pressure accumulator Ca and the dispenser 3 with pipes L3 and L4. .
With reference to FIG.2 (e), pressure | voltage rise system R6 has the pressure reducing valve 4 and the opening-and-closing valve V1 interposed in a path | route, and connects between portable pressure accumulator Ca and the compressor 6 by piping L3, L6. Has been. Further, as described above, the filling system R2 is configured by connecting the compressor 6 and the fixed pressure accumulator S1 by the pipe L2.
Referring to FIG. 2 (f), the filling system R7 is configured by connecting an open / close valve (V2) in the path and connecting the portable pressure accumulator Ca and the fixed pressure accumulator S1 with pipes L3 and L2. Has been.

  The hydrogen station 1 is configured as described above. Next, referring to FIGS. 3 to 5, filling (shipment) of the fixed pressure accumulator S <b> 1 or the portable pressure accumulator Ca in a normal time and a hydrogen production apparatus The aspect of reception from the portable pressure accumulator Ca at the time of 2 failure etc. is demonstrated.

<Filling into pressure accumulator S1 and Ca at normal time>
Referring to FIG. 3, in the initial state, hydrogen production device 2 is stopped, hydrogen compressor 6 is stopped, and open / close valves V1-V2 are closed (S101). From this state, the operation of the hydrogen production apparatus 2 is started for shipment (S102). Next, the operation of the hydrogen compressor 6 is started (S103), and the fixed pressure accumulator S1 is filled up to the set pressure (S104). At this time, normally, among the plurality of banks of the fixed pressure accumulator S1, a bank having a low residual pressure (hereinafter referred to as a high pressure bank S1 (H) side) is sequentially used in order from a bank having a high residual pressure. (L) side).
When filling of the pressure accumulator S1 is completed (YES in S105), the valve V2 is opened (S106), and the portable pressure accumulator Ca is filled (S107). When the pressure in the pressure accumulator S1 drops below the threshold value due to shipping from the dispenser during the filling of the portable pressure accumulator Ca (YES in S108), the valve V2 is closed (S110), The pressure accumulator S1 is preferentially filled (S104 and below). When filling of the pressure accumulator Ca is completed (YES in S109), this flow is finished.

<Acceptance from portable pressure accumulator Ca>
Next, with reference to FIG. 4, the aspect of reception from portable pressure accumulator Ca when the hydrogen production apparatus 2 is out of order will be described. In the initial state, the valves V1-V2 are closed and the hydrogen compressor 6 is stopped (S201). The pressure reducing valve 4 is set to be equal to the standard acceptance pressure of the hydrogen compressor 6.
The filling flow of the present embodiment differs depending on the pressure state of the fixed pressure accumulator S1, as shown below. That is, when supply by the differential pressure from the portable pressure accumulator Ca to the fixed pressure accumulator S1 is possible (YES in S202), the valve V2 is opened (S203). Thus, the hydrogen gas is supplied to the fixed pressure accumulator S1 through the path (filling system R7) in FIG. 2 (f) (S204).
By such an operation, the pressure of the portable pressure accumulator can be used effectively, and the power consumption can be suppressed as compared with the case where the fixed pressure accumulator S1 is filled by the compressor 6 via the pressure reducing valve 4. It becomes.

  When both pressures become equal and filling is impossible (YES in S205), filling by boosting is performed next. First, the valves V1 are opened and V2 are closed (S206), and then the operation of the hydrogen compressor 6 is started (S207). As a result, the hydrogen gas in the portable pressure accumulator Ca was adjusted to be the same as the outlet pressure of the hydrogen production apparatus 2 via the pressure reducing valve 4 by the flow path (pressure increase system R6, filling system R2) of FIG. After that, it is introduced into the hydrogen compressor 6. The filling of the gas whose pressure has been increased to 40 MPa in the compressor 6 is performed preferentially from the bank having a high residual pressure of the fixed pressure accumulator S1 (S208).

  In S202, when Pca ≦ P1 (L) (NO in S202), charging cannot be performed directly from the portable pressure accumulator Ca to the fixed pressure accumulator S1, and therefore charging is performed by boosting. That is, the valve V1 is closed (S209), and the flow proceeds to S207 and subsequent steps. Also in this case, the pressure of each accumulator after filling is the same as in the case of Pca> P1 (L).

<Filling the vehicle from the portable pressure accumulator Ca>
Next, with reference to FIG. 5, the aspect of filling the vehicle when the hydrogen production apparatus 2 fails will be described. In this case, the vehicle is charged in the order of the portable pressure accumulator Ca and the fixed pressure accumulator S1.
First, the valves V2 and V8 are opened, and charging from the portable pressure accumulator Ca to the vehicle is started by the hydrogen gas supply system R5 of FIG. 2D (S301). In addition, although description may be abbreviate | omitted below, the valve | bulb V8 is opened when the vehicle is filled, and is closed when the dispenser 3 is not used.
At the stage where portable pressure accumulator Ca pressure Pca = vehicle pressure Pv (YES in S303), if vehicle pressure Pv has not reached the standard set pressure (P _L ) (NO in S3031), valve V2 is closed. (S304), and the supply system R4 in FIG. 2C shifts to charging from the pressure accumulator S1. Filling is preferentially performed from the low-pressure bank S1 (L) side, and filling is completed when the vehicle pressure Pv reaches the standard set pressure (P _L ) (YES in S306). Thereafter, the above steps S301 and S301 are performed (S307) (see FIG. 4).
If YES in S3031, that is, if the vehicle pressure Pv has reached the standard set pressure (P _L ), the filling is completed (to S307).

  In the present embodiment, the hydrogen gas supply system R5 is configured such that the open / close valve (V2) is interposed in the path and the portable pressure accumulator Ca and the dispenser 3 are connected by the pipes L3 and L4. For example, a configuration in which an open / close valve is interposed and the two apparatuses are directly connected by piping is also possible. Furthermore, for other systems, it is possible to select any valve intervention and piping configuration that can achieve the intended filling, supply, and the like. The same applies to the following embodiments.

(Second embodiment)
Next, another embodiment of the present invention will be described with reference to FIGS. This embodiment relates to receiving and filling in a 70 MPa differential pressure filling station.
With reference to Fig.6 (a), the point from which the structure of the hydrogen station 20 which concerns on this embodiment differs from the above-mentioned hydrogen station 1 is that the 80 MPa fixed high pressure accumulator S2 and the high pressure hydrogen compressor 21 for 80 MPa pressurization are It is also equipped. A check valve 23 is interposed downstream of the hydrogen compressor 21. Moreover, with reference to FIG.6 (b), the pressure | voltage rise system R21 (the figure thick line) which connects portable pressure accumulator Ca and the hydrogen compressor 21 is provided. The boosting system R21 is constituted by pipes L3, L2, and L21 with opening / closing valves V2 and V4 and a pressure reducing valve 22 interposed in the path. Further, a filling system R22 (thick line in the figure) connecting the high-pressure hydrogen compressor 21 constituted by the pipe L22 and the fixed high-pressure accumulator S2 is provided.
Furthermore, with reference to FIG.6 (c), the supply type | system | group R23 (the same figure thick line) which connects between fixed high pressure accumulator S2 and the dispenser 3 by piping L22, L23, and L4 is provided.
Further, referring to FIG. 6 (d), a pressure boosting / filling system R24 (connected between the fixed pressure accumulator S1 and the fixed high pressure accumulator S2 by pipes L2, L21, L22 with a high pressure hydrogen compressor 21 interposed therebetween. (Thick line in the figure). The system R24 is used when filling the fixed high pressure accumulator S2 from the fixed pressure accumulator S1.
Since the other configuration is the same as that of the hydrogen station 1, a duplicate description is omitted.

Next, an aspect of filling each accumulator or vehicle in the hydrogen station 20 will be described. Since the filling for shipping at the normal time is the same as that of the above-described embodiment, the redundant description is omitted, and here, the aspect of receiving from the portable pressure accumulator Ca at the time of failure of the hydrogen production apparatus 2 will be described.
<Filling from portable pressure accumulator Ca to fixed pressure accumulators S1 and S2>
Referring to FIG. 7, in the initial state, valves V1, V2, V4 and V6 are closed, and hydrogen compressors 6 and 21 are stopped (S401). At the time of filling, the step changes according to the pressure state of the portable pressure accumulator Ca.
First, when Pca> Pcr (min), that is, when the pressure of the portable accumulator Ca is higher than the lowest pressure received (for example, 30 MPa) of the hydrogen compressor 21 (YES in S402), the valve V4 is opened (S403), The operation of the hydrogen compressor 21 is started (S404), and the fixed high pressure accumulator S2 is filled (S405). After the filling is completed, the valve V4 is closed and the hydrogen compressor 21 is stopped (S406).
In the subsequent flow, steps S108 and S109 in the 35 MPa differential pressure station are performed (S407).

  Next, if NO in S402, that is, if Pca ≦ Pcr (min), 80 MPa cannot be increased by the compressor 21, the high pressure accumulator S2 cannot be charged, and only the accumulator S1 is charged (S408 and below). ). The filling flow in this case is the same as S202-S209 described above (see FIG. 3).

<Vehicle filling>
In the present embodiment, the vehicle is charged in the order of the portable accumulator Ca, the accumulator S1, and the high-pressure accumulator S2 through the dispenser.
Referring to FIG. 8, first, valves V2, V6, and V8 are opened (S501), and the vehicle is charged from portable pressure accumulator Ca (S502) (see FIGS. 2 (d) and R5). Portable pressure accumulator Ca pressure Pca = vehicle pressure Pv (YES in S503) If vehicle pressure Pv has not reached the standard set pressure (P _L ) (NO in S5031), valve V2 is closed. (S504), and the vehicle is filled from the pressure accumulator S1 (S505) (similar to FIG. 2 (c) and R4). In this case, it is used from the low-pressure bank S1 (L) side and sequentially moves to the high-pressure bank S1 (H) side (S506). When the vehicle pressure Pv reaches the standard set pressure (P _L ) (YES in S506), the vehicle is then charged from the high pressure accumulator S2 (S507) (similar to FIG. 6C and R23). Further, the filling is completed when the vehicle pressure Pv reaches a predetermined pressure (for example, 70 MPa), and then the above-described steps S401 and S402 are performed (S508) (see FIG. 7).
If YES in S5031, that is, if the vehicle pressure Pv has reached the standard set pressure (P _L ), the process proceeds to charging from the high pressure accumulator S2 (to S507).

(Third embodiment)
Furthermore, another embodiment of the present invention will be described with reference to FIGS. This embodiment relates to receiving and filling at a 70 MPa direct filling station (direct vehicle filling from a 70 MPa compressor).
Referring to FIG. 9A, the configuration of the hydrogen station 30 according to this embodiment is different from the above-described hydrogen station 20 in that it does not have the 80 MPa high-pressure accumulator S2, and hydrogen compression for 80 MPa pressure increase. It replaces with the machine 21 and is equipped with the hydrogen compressor 31 for 70 MPa pressure | voltage rise.
Further, referring also to FIG. 9B, a booster system R31 (thick line in the figure) connecting the portable accumulator Ca and the hydrogen compressor 31 is provided. The boosting system R31 is constituted by pipes L3 and L31 with a pressure reducing valve 33 and an opening / closing valve V5 interposed in the path. Moreover, it is comprised by piping L32 and L4, and is provided with supply system R32 (the thick line in the figure) which connects between the high pressure hydrogen compressor 21 and the dispenser 3.
In addition, referring also to FIG. 9C, a boosting system R33 (thick line in the figure) connecting the fixed accumulator S1 and the hydrogen compressor 31 is provided. The boosting system R33 is configured by pipes L2, L3, and L31 with a pressure reducing valve 33 and opening / closing valves V2 and V5 interposed in the path.
Since the other configuration is the same as that of the hydrogen station 20, a duplicate description is omitted.

Next, an aspect of filling the pressure accumulator and the vehicle in the hydrogen station 30 will be described. Since the filling for shipping and the filling for receiving in the normal state are the same as the flow of FIGS. 3 and 4 of the first embodiment, redundant description will be omitted.
^{<Vehicle filling>}
Referring to FIG. 10, the filling from the portable pressure accumulator Ca to the vehicle is the same as in the second embodiment, but the subsequent filling flow differs depending on the residual pressure state of the pressure accumulator Ca after filling.
First, the valves V2, V6, and V8 are opened (S601), and the vehicle is charged from the portable accumulator Ca (S602). When Pv = 35 MPa (standard set pressure (P _L )), that is, when the vehicle can be filled up to 35 MPa by the accumulator Ca (YES in S603), the residual pressure Pca of the accumulator Ca is the lowest received pressure of the hydrogen compressor 31. In order not to fall below Pcr (min) (usually, Pca ≧ P _L ≧ Pcr (min) or Pcr (min) ≧ P _L may be set, but the illustration in this case is omitted), then the valve V2, V6 is closed and valve V5 is opened (S604), the compressor 31 is started to operate (S605), and is filled up to 70 MPa (S606). After the completion of filling, a hydrogen transfer step to the pressure accumulator (S202 and after in FIG. 4) is performed in the same manner as in the first embodiment (S612).

  If NO in S603, that is, if the pressure cannot be filled up to 35 MPa by the accumulator Ca, the valve V2 is closed (S607), and the vehicle is filled from the accumulator S1 (S608). When the vehicle pressure Pv reaches 35 MPa (YES in S611), the direct charging by the pressure accumulator S1 is terminated, and thereafter, 70 MPa charging by the compressor 31 is performed (S604 and below).

  The present invention is not limited to hydrogen stations that use city gas as a raw material, but can be widely applied to hydrogen stations that use portable pressure accumulators.

1, 20, 30 ... Hydrogen station 2, 21, 31 ... Hydrogen production device 3 ... Dispenser 4 ... Pressure reducing valve 5 ... Connecting coupler 6 ... .... hydrogen compressors 8a, 8b, 23, 34 ... check valves 21, 31 ... high pressure hydrogen compressor Ca ... portable pressure accumulators R1, R6, R21, R31, ... R33 ... Boosting systems R2, R3, R22 ... Filling systems R4, R5, R23, R32 ... Supply system R24 ... Boosting / filling system S1, ... Fixed pressure accumulator S2 .... Fixed high-pressure accumulator V1 to V8 ... Open / close valve

Claims (8)

A hydrogen station equipped with hydrogen production equipment,
A booster (6) for boosting the hydrogen produced by the hydrogen production device (2) to a predetermined pressure;
A fixed pressure accumulator (S1) for storing hydrogen boosted by the booster (6);
A portable pressure accumulator (Ca) that stores hydrogen boosted by the pressure booster (6) and is movable to the outside;
A dispenser (3) for supplying hydrogen in the fixed pressure accumulator (S1) or portable pressure accumulator (Ca) to the vehicle;
A boosting system (R1) connecting the hydrogen production device (2) and the boosting device (6);
A pressure increasing system (R6) connecting the portable pressure accumulator (Ca) and the pressure increasing device (6) through the pressure reducing valve (4);
A filling system (R2) connecting the booster (6) and the fixed accumulator (S1);
A filling system (R3) connecting the booster (6) and the portable pressure accumulator (Ca);
A hydrogen supply system (R4) connecting the fixed pressure accumulator (S1) and the dispenser (3);
A hydrogen supply system (R5) connecting the portable pressure accumulator (Ca) and the dispenser (3);
A hydrogen filling system (R7) connecting the portable pressure accumulator (Ca) and the fixed pressure accumulator (S1);
And comprising
By appropriately switching each system (R1-R7), it is possible to charge or supply hydrogen to the fixed pressure accumulator (S1) or the dispenser (3) directly from the portable pressure accumulator (Ca) or via the pressure booster (6). did,
This is a hydrogen station. The claim 1, further comprising:
A high pressure booster (21) for boosting the hydrogen produced by the hydrogen production device (2) to a first high pressure setting pressure (P _H1 ) higher than the booster (6);
A fixed high pressure accumulator (S2) for storing hydrogen boosted by the high pressure booster (21);
A pressure increasing system (R21) connecting the portable pressure accumulator (Ca) and the high pressure boosting device (21) with a pressure reducing valve (22) interposed therebetween;
A filling system (R22) connecting the high pressure booster (21) and the fixed high pressure accumulator (S2);
A hydrogen supply system (R23) connecting the fixed high-pressure accumulator (S2) and the dispenser (3);
A pressure increasing system (R24) connecting the fixed high pressure accumulator (S1) and the high pressure boosting device (21) with a pressure reducing valve (22) interposed therebetween;
With
And by appropriately switching each system (R21-R24),
The hydrogen stored in the portable pressure accumulator (Ca) can be charged into the fixed high pressure accumulator (S2) after being boosted by the high pressure booster (21), and
The hydrogen stored in the fixed high pressure accumulator (S2) is configured so that the vehicle can be filled with a differential pressure via the dispenser (3).
This is a hydrogen station. The claim 1, further comprising:
A high pressure booster (31) for boosting the hydrogen produced by the hydrogen production device (2) to a second high pressure setting pressure ( _PH2 ) higher than the booster (6);
A pressure increasing system (R31) connecting the portable accumulator (Ca) and the high pressure boosting device (31) with a pressure reducing valve (33) interposed therebetween;
A hydrogen supply system (R32) connecting the high pressure booster (31) and the dispenser (3);
A pressure increasing system (R33) connecting the fixed high pressure accumulator (S1) and the high pressure boosting device (31) with a pressure reducing valve (33) interposed therebetween;
And by appropriately switching each system (R31-R33),
The hydrogen stored in the portable pressure accumulator (Ca) can be directly charged into the vehicle via the dispenser (3) after being boosted by the high pressure booster (31).
This is a hydrogen station. A hydrogen filling method from a portable pressure accumulator to a fixed pressure accumulator in a hydrogen station according to any one of claims 1 to 3,
When the filling pressure (Pca) of the portable pressure accumulator (Ca) is higher than the pressure of the fixed pressure accumulator (S1), it is filled with a differential pressure via the filling system (R7),
At the stage where the filling by the differential pressure becomes impossible, the booster (6) is operated and filled via the booster system (R6).
A hydrogen filling or supplying method in a hydrogen station. A method for supplying hydrogen to a vehicle via a dispenser in the hydrogen station according to any one of claims 1 to 3,
Hydrogen is supplied to the dispenser (3) through the supply system (R5) until it reaches the standard set pressure (P _L ) from the portable pressure accumulator (Ca),
When the standard set pressure (P _L ) has not been reached, hydrogen is further supplied from the fixed pressure accumulator (S1) to the dispenser (3) sequentially via the supply system (R4).
A hydrogen filling or supplying method in a hydrogen station. A hydrogen filling method from a portable pressure accumulator to a fixed pressure accumulator (S1) or a fixed pressure accumulator (S2) in the hydrogen station according to claim 2,
When the filling pressure (Pca) of the portable pressure accumulator (Ca) is higher than the receiving pressure (Pcr (min)) of the high pressure booster (21),
The high pressure booster (21) is operated to fill the stationary accumulator (S2) with hydrogen via the boosting system (R21), and then the high pressure booster (21) is stopped and fixed according to the process of claim 4. Fill the accumulator (S1) with hydrogen,
When the charging pressure (Pca) of the portable pressure accumulator (Ca) is equal to or lower than the receiving pressure (Pcr (min)) of the high pressure booster (21), the fixed pressure accumulator (S1) is applied according to the process of claim 4. Filling with hydrogen,
A hydrogen filling or supplying method in a hydrogen station. A method for filling hydrogen into a vehicle via a dispenser in the hydrogen station according to claim 2,
Hydrogen is supplied from the portable pressure accumulator (Ca) to the dispenser (3) via the supply system (R5),
When it can be filled up to the standard set pressure (P _L ), it is then filled up to the first high pressure set pressure (P _H1 ) with a differential pressure from the fixed pressure accumulator (S2) via the supply system (R23),
If the standard set pressure (P _L ) cannot be charged, hydrogen is supplied from the fixed accumulator (S1) to the dispenser (3) through the supply system (R4) until the standard set pressure (P _L ) is reached,
Further, the pressure is charged from the fixed pressure accumulator (S2) to the first high pressure set pressure (P _H1 ) via the supply system (R23) with a differential pressure.
A hydrogen filling or supplying method in a hydrogen station. A method for filling hydrogen into a vehicle via a dispenser in a hydrogen station according to claim 3,
Hydrogen is supplied from the portable pressure accumulator (Ca) to the dispenser (3) via the supply system (R5),
If the pressure reaches the standard set pressure (P _L ), then the high pressure booster (31) is operated and the second high pressure set pressure (Ca) is supplied from the portable accumulator (Ca) via the supply system (R31). Up to _{pH 2} )
When the standard set pressure (P _L ) cannot be filled, the fixed pressure accumulator (S 1) is filled to the standard set pressure (P _L ) via the supply system (R 4).
Further, the high pressure booster (31) is operated and charged from the fixed pressure accumulator (S1) to the second high pressure set pressure (P _H2 ) via the supply system (R32) and the supply system (R33).
A hydrogen filling or supplying method in a hydrogen station.

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