DE112008003542T5 - Gas supply structure - Google Patents

Abstract

Gas supply structure, comprising:
a nozzle that supplies a gas,
a recipient into which the nozzle is introduced and thereby receives the supplied gas,
an O-ring, which is provided in the recipient and which seals the neck and the recipient and which slides during the introduction of the nozzle against the neck, and
a foreign matter removing member provided at a position closer to an insertion opening for the nozzle than the O-ring in the recipient.

Description

FIELD OF TECHNOLOGY

The The present invention relates to a gas supply structure, and more particularly it relates to a gas supply structure with improved gas sealing properties.

TECHNICAL BACKGROUND

Fuel cells are installed in electric cars and hybrid cars. Further, solid polymer fuel cells can be used as these fuel cells. The mechanism for generating electric power in these solid polymer fuel cells generally involves supplying a fuel gas such as a hydrogen-containing gas to a fuel electrode (the anode-side electrode) and supplying an oxidizing gas such as a gas mainly containing oxygen (O ₂ ). contains, or air, to an air electrode (the cathode-side electrode), wherein the hydrogen-containing gas supplied to the fuel electrode is split into electrons and hydrogen ions (H ⁺ ) under the action of the electrode catalyst, and these electrons are passed through an external circuit to migrate from the fuel electrode to the air electrode, whereby electric current is generated. On the other hand, the hydrogen ions (H ⁺ ) pass through an electrolyte membrane interposed between the fuel electrode and the air electrode to reach the air electrode, and bond with oxygen and the electrons which have passed through the external circuit, whereby water of reaction (H ₂ O) arises.

In order to the above-described fuel cell with a hydrogen-containing Gas (such as hydrogen gas) can be supplied, is the electric car or hybrid car equipped with a hydrogen fuel storage system. This hydrogen fuel storage system has a high-pressure hydrogen tank and a hydrogen filling coupling serving as a mounting portion Serves when the high-pressure hydrogen tank with under high pressure hydrogen from a dispenser a hydrogen station is filled.

As in 9 has a conventional hydrogen filling coupling 300 a nozzle for supplying hydrogen gas (not shown in the figure) and a recipient 70 or a receptacle with an insertion opening 72 Into which the neck is inserted, and is with an O-ring 74 provided the environment of the insertion opening 72 the recipient 70 seals. In the 9 illustrated hydrogen filling coupling 300 is a feed structure that can be used in filling high pressure hydrogen gas under a high pressure of 35 MPa, and provides a standard form for a ISO 17268 described hydrogen filling coupling.

The range of a vehicle in which the high-pressure hydrogen tank using the in 9 illustrated type of hydrogen filling coupling 300 is filled with a hydrogen gas under a high pressure of 35 MPa, is about 350 km, which is not quite satisfactory compared to the 500 km range required by the market. On the other hand, limitations of the vehicle assemblies make it impossible to increase the high-pressure hydrogen tank, and as a result, it has recently been proposed to increase the filling pressure for the high-pressure hydrogen gas from 35 MPa to 70 MPa. This increase in pressure of the filling gas makes it necessary to reduce the diameter of the nozzle of the hydrogen filling coupling, and as a result the nozzle has become longer and now good gas sealing properties are needed near the front end of the nozzle.

For example, an example of a novel structure for a hydrogen fill coupling capable of filling hydrogen at 70 MPa and proposed by a German company (hereinafter referred to as "German proposal" or "shaped according to the German proposal"). in) 10 shown. As in 10 shown, has a hydrogen filling coupling 400 , which is shaped according to the German proposal, a neck 10 with a gas supply line 12 and a recipient 80 on with an insertion opening 82 into which the neck 10 introduced to him, the recipient 80 with a first O-ring 84 which is near the insertion opening 82 is provided to provide gas seal, and with a second O-ring 88 is provided in the gas supply path further downstream than the first O-ring 84 to provide a gas seal, and wherein a portion of the second O-ring 88 using an adhesive 87 at a recess portion in the recipient 80 is attached.

Further, an example of a novel structure of a hydrogen filling clutch capable of filling hydrogen at a pressure of 70 MPa and proposed by a Japanese company (hereinafter referred to as "Japanese proposal" or "according to the Japanese proposal shaped "), in 11 shown. As in 11 shown, has a hydrogen filling coupling 500 , which is shaped according to the Japanese proposal, a neck 90 with a gas supply line 92 and a recipient 20 on with an insertion opening 22 into which the neck 90 introduced to him, the recipient 40 with a first O-ring 44 who is near the insertion opening 42 is provided to provide a gas seal, and with a second O-ring 98 is provided at the front end of the neck 90 is provided to provide a gas seal, and wherein a portion of the second O-ring 98 attached to a recess portion near the front end of the nozzle using an adhesive 90 is provided.

With increasing nozzle length increases the risk that foreign substances, which adhere to the nozzle surface, from the front end of the neck, located in the gas pipe of the recipient is off, go into the gas. Neither the German Proposal still the Japanese proposal is with a device to prevent contamination with foreign matter.

The Patent Document 1 proposes a fuel filling system ago, which has a neck for the filling of Gas and a recipient into which gas from the neck provides GE is, wherein the system with a malfunction diagnostic device. Mistake that is a malfunction of the recipient or the neck during the gas filling diagnosed. However, this is in the patent document 1 proposed fuel filling system not with a device provided that prevents contamination by foreign substances or inhibits.

• Patentdokument 1: JP 2006-177253 A
• Patentdokument 2: JP 2005-241882 A
• Patentdokument 3: JP 2003-225540 A
• Patentdokument 4: JP 08-75098 A

Patent Document 2 proposes a structure for an optically communicating socket in which an engaging member having a protruding sliding surface is provided on the inner circumferential surface of a plug insertion opening of the optically communicating socket, so that dust is removed on the surface of the plug upon insertion, thereby removing prevents dust from getting inside the optically communicating socket. Further, Patent Documents 3 and 4 suggest structures for filters used in the removal of toxic components or impurities from a flowing gas stream.

• Patent Document 1: JP 2006-177253 A
• Patent Document 2: JP 2005-241882 A
• Patent Document 3: JP 2003-225540 A
• Patent Document 4: JP 08-75098 A

DISCLOSURE OF THE INVENTION

POBLEMS SOLVED BY THE INVENTION SHOULD

As above, none of the novel structures for Hydrogen filling couplings that have been proposed to the transition to a higher pressure of the filling gas to cope with a device for preventing or Inhibition of contamination of the recipient gas line by foreign matter, due to the increased length of the Cling to the neck surface, provided.

If in the case of a hydrogen filling coupling, according to the German proposal is formed, the nozzle in the gas filling introduced into the insertion of the recipient while adhere foreign matter to the nozzle surface, Therefore, the foreign substances remain at the O-rings within the recipient, which are provided so that no space between the neck and The O-ring remains, adhere and remain in particular on the O-ring stick, which is near the front end of the neck is provided. If these foreign substances damage cause the surface of the O-ring, there is a risk that the sealing properties become worse. Also in the case a hydrogen filling coupling, which according to the Japanese suggestion, foreign matter tends to be on the O-ring sticking close to the front end of the neck, if such foreign matter on the inner peripheral surface of the recipient insertion opening adhere, and if damaged, the surface causes the O-ring, there is a risk that the sealing properties become worse.

Further when filling the liquid fuel the filling is usually done while the liquid fuel has a low temperature of about -40 ° C to increase the temperature of the high-pressure hydrogen tank (like a tank) to prevent. If during this filling Water adheres to the neck of the hydrogen filling coupling, it freezes and sticks to the nozzle as ice, which causes it difficult to remove the nozzle from the recipient. If the neck in this situation by force from the recipient In addition, there is a risk that the O-rings within the hydrogen filler partially become solve, resulting in a loss of sealing properties leads. These problems in connection with the filling of cold liquid fuel are with conventional hydrogen filler coupling structures and the prior art described above are difficult to solve.

The The present invention has been made in view of the problems described above made, and she creates a gas supply structure capable of is to prevent foreign substances on the nozzle surface adhere to the O-rings within the gas supply structure when the Nozzle during filling of the gas in the recipient is introduced.

MEANS TO SOLUTION THE PROBLEMS

• (1) Eine Gaszufuhrstruktur, die aufweist: einen Stutzen, der ein Gas zuführt, einen Rezipienten, in den der Stutzen eingeführt wird, und der dadurch das Gas empfängt, einen in dem Rezipienten vorgesehenen O-Ring, der den Stutzen und den Rezipienten abdichtet und der während der Einführung des Stutzens am Stutzen entlang gleitet, und ein Element zum Entfernen von Fremdstoffen, das im Rezipienten an einer Stelle vorgesehen ist, die näher an der Einführöffnung für den Stutzen liegt als der O-Ring.

In order to achieve the above-described objects, the gas supply structure of the present Invention to the features described below.

• (1) A gas supply structure comprising: a nozzle supplying a gas, a recipient into which the nozzle is inserted, and thereby receiving the gas, an O-ring provided in the recipient, which seals the nozzle and the recipient and slides along the nozzle during insertion of the nozzle, and a foreign matter removing member provided in the recipient at a position closer to the nozzle insertion opening than the O-ring.

• (2) Eine Gaszufuhrstruktur, die aufweist: einen Stutzen, der ein Gas zuführt, einen Rezipienten, in den der Stutzen eingeführt wird, und der dadurch das Gas empfängt, einen am Stutzen vorgesehenen O-Ring, der den Stutzen und den Rezipienten abdichtet und der während der Einführung des Stutzens am Stutzen entlang gleitet, und ein Element zum Entfernen von Fremdstoffen, das im Rezipienten an einer Stelle vorgesehen ist, die näher am vorderen Ende des Stutzens liegt als der O-Ring.

Since the recipient-provided foreign-matter-removing member is located closer to the nozzle insertion hole than the O-ring provided in the recipient, the foreign-matter removing member removes foreign matters existing on the nozzle surfaces beginning at the front end of the nozzle while the neck is inserted into the recipient. This prevents foreign matter from sticking to the front end of the nozzle and to the nozzle surface on the O-ring.

• (2) A gas supply structure comprising: a nozzle supplying a gas, a recipient into which the nozzle is inserted, thereby receiving the gas, an O-ring provided at the nozzle, sealing the nozzle and the recipient, and which slides along the spigot during the introduction of the spigot, and an element for removing foreign matter, which is provided in the recipient at a location which is closer to the front end of the nozzle than the O-ring.

• (3) Gaszufuhrstruktur, die aufweist: einen Rezipienten, in den ein Stutzen eingeführt wird, und der dadurch zugeführtes Gas empfängt, einen im Rezipienten vorgesehenen O-Ring, der den Stutzen und den Rezipienten abdichtet und der während der Einführung des Stutzens am Stutzen entlang gleitet, und ein Element zum Entfernen von Fremdstoffen, das im Rezipienten an einer Stelle vorgesehen ist, die näher an der Einführöffnung für den Stutzen liegt als der O-Ring.

Since the spigot removing member is disposed nearer to the front end of the spigot than the spigot O-ring, the foreign matter removing member is capable of removing foreign matters existing on the inner peripheral surface other than the spigot the receiving opening of the recipient from extending inwardly, while the nozzle is inserted into the recipient. Thus, adhesion of foreign matter to the O-ring provided on the neck is inhibited.

• (3) A gas supply structure comprising: a recipient into which a nozzle is inserted and receiving gas supplied thereto, an O-ring provided in the recipient, which seals the nozzle and the recipient, and which runs along the nozzle during introduction of the nozzle slides, and an element for removing foreign matter, which is provided in the recipient at a position which is closer to the insertion opening for the nozzle than the O-ring.

• (4) Gaszufuhrstruktur, die aufweist: einen Rezipienten, in den ein Stutzen eingeführt wird, und der dadurch ein zugeführtes Gas empfingt, einen am Stutzen vorgesehenen O-Ring, der den Stutzen und den Rezipienten abdichtet und der während der Einführung des Stutzens am Stutzen entlang gleitet, und ein Element zum Entfernen von Fremdstoffen, das am Stutzen an einer Stelle vorgesehen ist, die näher am vorderen Ende des Stutzens liegt als der O-Ring.
• (5) Gaszufuhrstruktur nach einem der obigen Punkte (1) bis (4), ferner einen O-Ring auf der Seite der Einführöffnung aufweisend, der im Rezipienten in der Nähe der Einführöffnung vorgesehen ist.
• (6) Gaszufuhrstruktur nach einem der obigen Punkte (1) bis (5), die ferner aufweist: einen Tank zum Speichern des Gases, einen Filter mit einem kleinen Verlustkoeffizien ten, der auf der stromaufwärtigen Seite einer Gasleitung, die den Rezipienten mit dem Tank verbindet, vorgesehen ist, und einen Filter mit einem großen Verlustkoeffizienten, der auf der stromabwärtigen Seite der Gasleitung vorgesehen ist.

Since the recipient-provided foreign-matter-removing member is located closer to the nozzle insertion hole than the O-ring provided in the recipient, the foreign-matter removing member removes foreign matters existing on the nozzle surfaces beginning at the front end of the nozzle while the neck is inserted into the recipient. Thus, adhesion of foreign matters existing at the front end of the nozzle and on the nozzle surfaces is inhibited or prevented at the O-ring.

• (4) A gas supply structure comprising: a recipient into which a nozzle is inserted, thereby receiving a supplied gas, an o-ring provided at the nozzle, which seals the nozzle and the recipient, and the nozzle during insertion of the nozzle along and a foreign matter removing member provided at the nozzle at a position closer to the front end of the nozzle than the O-ring.
• (5) The gas supply structure according to any one of the above (1) to (4), further comprising an O-ring on the side of the insertion opening provided in the recipient in the vicinity of the insertion opening.
• (6) The gas supply structure according to any one of the above items (1) to (5), further comprising: a tank for storing the gas, a filter having a small loss coefficient located on the upstream side of a gas line connecting the recipient to the tank connects, is provided, and a filter with a large loss coefficient, which is provided on the downstream side of the gas line.

• (7) Gaszufuhrstruktur nach einem der oben genannten Punkte (1) bis (6), wobei das Element zum Entfernen von Fremdstoffen einen Gleitwiderstand aufweist, der, auf Basis einer in JIS B 8812 vorgeschriebenen Ausziehkraftmessung bestimmt, nicht kleiner als 300 N und nicht größer als 500 N ist.

The two filters described above trap foreign matter within the gas supplied to the tank, and by combining a filter with a relatively small loss coefficient with a filter having a relatively large loss coefficient, the differential pressure upstream and downstream of the two filters can be compared to one single filter can be lowered. As a result, blockages in the entire filter system within the gas line can be inhibited.

• (7) The gas supply structure according to any one of the above-mentioned (1) to (6), wherein the element for removing foreign matters has a sliding resistance which, based on an in JIS B 8812 prescribed pull-out force measurement is not less than 300 N and not greater than 500 N.

By Using an element to remove foreign matter that causes the has above-defined sliding resistance, foreign substances, especially in the form of water within the gas supply structure are present, better to be removed.

EFFECT OF THE INVENTION

The The present invention is capable of contaminating gas supply structures with foreign substances to inhibit.

BRIEF DESCRIPTION OF THE DRAWING

1 FIG. 10 is a partial sectional view illustrating an example of a gas supply structure according to a first embodiment of the present invention at a pre-insertion stage. FIG.

2 FIG. 14 is a partial sectional view showing the gas supply structure according to the first embodiment of the present invention at a stage after insertion. FIG.

3 Fig. 10 is a partial sectional view showing a gas supply structure according to a second embodiment of the present invention at a pre-insertion stage.

4 FIG. 10 is a partial sectional view showing the gas supply structure according to the second embodiment of the present invention at a stage after insertion. FIG.

5 FIG. 12 is a schematic diagram of an example of a gas pipe of the gas supply structure according to a third embodiment of the present invention. FIG.

6 FIG. 12 is a schematic diagram of an example of the structure of a low loss coefficient filter used in the gas supply structure according to the third embodiment of the present invention. FIG.

7 Fig. 12 is a graph showing the relation between the differential pressure before and after a filter having a low loss coefficient and an upstream gas pressure.

8th Fig. 12 is a graph showing the relation between the differential pressure before and after a filter having a large loss coefficient and the upstream gas pressure.

9 Fig. 10 is a partial sectional view illustrating an example of the structure of a hydrogen filling clutch designed for a filling gas pressure of 35 MPa.

10 Fig. 10 is a partial sectional view showing an example of the structure of a hydrogen filling clutch for a filling gas pressure of 70 MPa formed in accordance with the German proposal.

11 Fig. 16 is a partial sectional view showing an example of the structure of a hydrogen filling clutch for a filling gas pressure of 70 MPa molded in accordance with the Japanese proposal.

10 30

Support

12 32

Gas supply line

20 40

recipient

22 42

insertion

24 44

first O-ring

26 36

element for removing foreign matter

27 37

adhesives

28 38

second O-ring

50

gas pipe

52 54

filter

100 200

Gas supply structure

BEST WAY TO PERFORM THE INVENTION

below Become embodiments of the present invention with Referring to the drawing described. Furthermore, the gas supply structure of the present invention with reference to the example of a hydrogen filling coupling, used for filling high pressure gas at 70 MPa, described.

An example of a gas supply structure according to a first embodiment of the present invention is shown in FIG 1 and 2 shown. As in 1 and 2 shown, the gas supply structure 100 this embodiment on: a nozzle 10 that feeds gas, a recipient 20 into the neck 10 is introduced, and receives the gas supplied thereby, an O-ring, the nozzle 10 and the recipient 20 seals, and an element 26 for removing foreign matter at the front end of the nozzle 10 Adhesive foreign matter prevents it from sticking to the O-ring.

In This description describes the term "foreign substances", in both this embodiment and in the other, hereinafter described embodiments, substances, those at the front end and at the surface of the neck can stick, and closes dust, moisture and the like.

In a more detailed description, the gas supply structure 100 according to the present embodiment, in a case where it is shaped according to the German proposal, a nozzle 10 with a gas supply line 12 and a recipient 20 with an insertion opening 22 on, in which the neck 10 is introduced to him in it, whereby the recipient 20 with a first O-ring, which is near the insertion opening 22 is intended for a gas seal, and with a second O-ring 28 is provided in the gas supply path in the flow direction further down than the first O-ring 24 is provided to provide a gas seal, wherein a part of the second O-ring 28 using an adhesive 27 at a recess portion in the recipient 20 is attached and an element 26 for removing foreign matter closer to the insertion opening 26 arranged as the second O-ring 28 , Further, the element is 26 for removing foreign matter so provided in the recipient that it partially over the inner peripheral surface, extending from the insertion 22 extends from the recipient, protrudes.

There are no special restrictions on the positioning of the element 26 for removing foreign matter within the recipient 20 , assuming the item 26 for removing foreign matter, as described above, closer to the insertion opening 22 arranged as the second O-ring 28 , In view of the fact that foreign substances during the introduction of the nozzle 10 from the front end and the surface of the neck 10 However, it is most preferable for the element to be removed 26 for removing foreign matter near the insertion opening 22 the recipient 20 adjacent to the first O-ring 24 and this is positioned downstream, but it may be beneficial at any point between the first O-ring 24 and the second O-ring 28 be provided. Given that the ultimate goal is to adhere foreign matter to the second O-ring 28 can prevent the element 26 for removing foreign matter also the second O-ring 28 be positioned upstream and immediately adjacent to this.

Hereinafter, the operation of the foreign matter removal by the gas supply structure of the first embodiment will be described with reference to FIG 1 and 2 described. 1 shows the stage before the introduction of the neck 10 in the recipient 20 , As in 1 represented, is the element 26 for removing foreign matter so as to be provided around the inner circumferential surface of the recipient so as to project partially over this surface. If the neck 10 in the insertion opening 22 the recipient 20 is introduced, the surface of the neck comes 10 thus, starting at the front end of the neck 10 , with the element 26 For removing foreign matters in sliding contact, and as a result, foreign matter is starting at the front end of the neck 10 from the surface of the neck 10 This makes it possible to have a cleaned front end and a cleaned surface of the neck 10 against the second O-ring 28 in the recipient 20 be pressed, as in 2 shown. Thus it can be prevented that foreign matter on the second O-ring 28 adhere, which means that damage to the surface of the second O-ring 28 , which is caused by foreign matter, can be prevented, and that the gas sealing properties between the neck 10 and the recipient 20 how a seal against high-pressure gas at 70 MPa can be maintained advantageously.

The stub 10 and the recipient 20 of this embodiment are formed of metal, and from the viewpoint of workability and strength, they are preferably formed of stainless steel or the like.

In contrast, the material of the element 26 For removing foreign matter in the present embodiment, any material that has sufficient elasticity and / or flexibility to damage the surface of the nozzle 10 during a sliding contact. Examples of materials that can be used include rubbers and flexible resins, and the use of polytetrafluoroethylene (PTFE) is preferred.

Furthermore, the said element 26 for removing foreign matter either as a single contiguous ring or as a non-contiguous ring on the inner peripheral surface of the recipient 20 be provided, and the section of the element 26 For removing foreign matter projecting over the inner circumferential surface, it may be shaped either like a squeegee or a blade or like a brush. Further, the length of the protruding portion may be as required and according to the degree of elasticity or flexibility of the selected member 26 be selected for removing foreign substances.

In addition, the item points 26 for removing foreign matter, preferably a glowing resistance, determined on the basis of a JIS B 8812 described Zugkraftmessung or Ausziehkraftmessung, not less than 300 N and not more than 500 N. To ensure a sliding resistance that satisfies this range requirement means that when the element slides 26 for removing foreign matter on the surface of the nozzle 10 while the neck 10 is introduced, the neck 10 is not damaged, but any foreign matter at the front end and on the surface of the nozzle 10 can be removed. The removal performance is particularly good when the foreign matter is water. For example, if a liquid fuel is used to fill a high pressure hydrogen container (such as a tank) and the filled liquid fuel is at a low temperature of about -40 ° C, any water will be on the surface of the nozzle 10 through the element 26 to remove removed from foreign matter when the nozzle 10 in the recipient 20 is introduced, and therefore there is no risk of water on the second O-ring 28 freezes where there is no space between the neck 10 and the recipient 20 is present, which means that it can be prevented during coupling and uncoupling of the nozzle 10 and the recipient 20 damage such as detachment of part of the second O-ring 28 , comes.

Now, an example of a gas supply structure according to a second embodiment of the present invention will be described with reference to FIG 3 and 4 described. As in 3 and 4 shown, the gas supply structure 200 this embodiment on: a nozzle 30 that feeds gas, a recipient 40 into the neck 30 is introduced and thereby receives the supplied gas, an O-ring, the nozzle 30 and the recipient 40 seals, and an element 36 for removing foreign matter, which prevents foreign matter from the front end of the nozzle 30 stick to the O-ring.

In a more detailed description, the gas supply structure 200 According to the present embodiment, in a case where it is formed according to the above-mentioned Japanese proposal, a nozzle 30 with a gas supply line 32 and a recipient 40 with an insertion opening 42 on, in which the neck 30 is introduced to him in it, whereby the recipient 40 with a first O-ring 44 is provided near the insertion opening 42 is provided to provide a gas seal, a second O-ring 38 at the front end of the neck 30 is provided to provide a gas seal, and a portion of the second O-ring 38 using an adhesive 37 attached to a recess portion near the front end of the nozzle 90 is provided. The element 36 For removing foreign matter is closer to the front end of the nozzle 30 positioned as the second O-ring 38 ,

There are no special restrictions on the positioning of the element 36 for removing foreign substances at the nozzle 30 , assuming the item 36 for removing foreign matter, as described above, closer to the front end of the nozzle 30 arranged as the second O-ring 38 , In view of the fact that foreign substances during the introduction of the nozzle 30 from the inner peripheral surface of the recipient 40 However, it is most preferable for the element to be removed 36 for removing foreign matter near the front end of the nozzle 30 is positioned, though it is in order to prevent any foreign matter on the second O-ring 38 stick with advantage, can be positioned at any point, attached to the second O-ring 38 adjoins and on the side of the front end of the neck 30 lies.

Hereinafter, the operation of the foreign matter removal by the gas supply structure of the second embodiment will be described with reference to FIG 3 and 4 described. 3 shows the stage before the introduction of the neck 30 in the recipient 40 , As in 3 represented, is the element 36 for removing foreign matter on the surface of the nozzle 30 provided that it protrudes partially from the nozzle surface. If the neck 30 in the insertion opening 42 the recipient 40 is introduced, the element comes 36 for removing foreign matter thus in sliding contact with the inner circumferential surface extending from the insertion opening 42 the recipient 40 extends inwardly, thereby allowing a cleaned inner peripheral surface of the recipient 40 against the second O-ring 38 at the neck 30 be pressed, as in 4 shown. Thus it can be prevented that foreign matter on the third O-ring 28 adhere, which means that damage to the surface of the second O-ring 28 , which is caused by foreign matter, can be prevented, and that the gas sealing properties between the neck 30 and the recipient 40 how a seal against high-pressure gas at 70 MPa can be maintained advantageously.

In a similar manner as described above for the first embodiment, the neck are 30 and the recipient 40 this embodiment of metal, such as stainless steel formed. Furthermore, the material of the element may be 36 for removing foreign matter in a manner similar to that described above for the first embodiment by any material that has sufficient elasticity and / or flexibility to damage the surface of the recipient 40 during a sliding contact. Examples of materials that can be used include rubbers and flexible resins, and the use of polytetrafluoroethylene (PTFE) is preferred.

Furthermore, the said element 36 for removing foreign matter either as a single contiguous ring or as a non-contiguous ring on the surface of the nozzle 30 be provided, and the section of the element 36 for removing foreign matter from the surface of the nozzle 30 can protrude either as a squeegee or a blade or as a brush, and the length of the protruding portion can be as required and according to the degree of elasticity or flexibility of the selected element 36 be selected for removing foreign substances.

In addition, the item points 36 For removing foreign matters in a manner similar to that described above for the first embodiment, preferably a sliding resistance determined on the basis of a JIS B 8812 described Zugkraftmessung or Ausziehkraftmessung, not less than 300 N and not more than 500 N. To ensure a sliding resistance that satisfies this range requirement means that when the element slides 36 for removing foreign matter on the surface of the recipient 40 while the neck 30 introduced, the recipient 40 is not damaged, but any foreign matter on the inner peripheral surface of the recipient 40 can be removed. The removal performance is particularly good when the foreign matter is water. For example, if a liquid fuel is used to fill a high pressure hydrogen container (such as a tank) and the filled liquid fuel is at a low temperature of about -40 ° C, any water will be on the surface of the recipient 40 through the element 36 for removing foreign substances at the nozzle 30 removed, and therefore there is no risk of water on the second O-ring 38 freezes where there is no space between the neck 30 and the recipient 40 is present, which means that it can be prevented during coupling and uncoupling of the nozzle 30 and the recipient 40 damage such as detachment of part of the second O-ring 38 , comes.

Now, an example of a gas supply structure according to a third embodiment of the present invention will be described with reference to FIG 5 described. As in 5 12, the gas supply structure of this embodiment is based on the gas supply structure of the first and second embodiments described above, and further includes a tank for storing the gas, a filter 52 with a small loss coefficient, on the upstream side of a gas pipe 50 , which connects the recipient to the tank, and a filter with a large loss coefficient, located on the downstream side of the gas pipe 50 is provided.

7 is a graph showing the relationship between the differential pressure in front of and behind the filter 52 with the relatively small loss coefficient (ie with the value ΔP _f = P ₀ -P ₁ in 1 ) and the gas pressure upstream of the filter 52 represents. As in 7 As shown, the higher the upstream gas pressure, the smaller the value of the differential pressure ΔP _f = P ₀ -P ₁ becomes). On the other hand is 8th a graph showing the relationship between the differential pressure before and after the filter 54 with the relatively large loss coefficient (ie, the value ΔP _s = P ₁ -P ₂ in 1 ) and the gas pressure upstream of the filter 54 represents. As in 8th As shown, the higher the upstream gas pressure, the larger the value for the differential pressure ΔP _s = P ₀ -P ₁ ) becomes. By placing the filter 52 Thus, with the relatively small loss coefficient on the upstream side of the gas line, where the high pressure gas comes first, the differential pressure ΔP _{f in} front of and behind the filter 52 be lowered, and blocking the filter 52 can be prevented while the filter 52 all of the relatively large foreign matter within the gas supplied to the tank traps. As a result, even if the high pressure gas from which a part of the foreign matters has been removed, the filter 54 with the relatively high loss coefficient occurring on the downstream side of the gas line 50 is arranged, the differential pressure ΔP _s compared to a conventional structure in which only the filter 54 is provided, and blocking the filter with foreign matter is less likely.

In other words, by combining the filter 52 with the relatively small loss coefficient with the filter 54 with the relatively large loss coefficient, foreign matters within the gas supplied to the tank are trapped more reliably, and the values for the differential pressure ΔP _f and ΔP _s before and after the filters 52 and 54 can compared to the case that only a single filter is provided, and in particular to the case where only the filter 54 is intended to be lowered, which means that blockages throughout the filter system within the gas line 50 can be inhibited or prevented.

Grid-like filters can be considered the filters 52 is used with the small loss coefficient, and the distance between the wires forming the grid-like filter is about 0.2 mm, although the present invention is not limited to this value. Furthermore, either a single filter 52 or two or more filters may be used in combination. For example, as in 6 shown, filters 52 be rotated stepwise in one direction with the same inter-wire spacing and either stacked on top of each other or spaced apart a certain distance apart. Through such use of two or more filters, the effective pore size of the filter 52 can be changed, or if the filters are arranged with a certain distance from each other, the differential pressure can be lowered.

Sintered metal filters can act as filters 54 are used with the large loss coefficient, and a sintered metal filter having a pore size of about 5 μm is preferred, but the present invention is not limited to filters having this pore size.

Furthermore, the respective pore sizes of the passages of the filter 52 and the filter 54 as required according to the gas pressure of the gas flowing through and the nature of the foreign matter contained in the gas.

Even though the present invention has been described in detail above is the scope of the present invention is not limited to limited to the specific embodiments described above.

Furthermore, the detailed description, the claims, the drawing and the summary of the invention, which are described in the Japanese Patent Application No. 2007-336307 , filed on Dec. 27, 2007, incorporated herein by reference in its entirety.

INDUSTRIAL APPLICABILITY

A Gas supply structure of the present invention may be for each Equipment used to supply a gas, but it is particularly suitable for systems for filling of high pressure gas and is ideal for the Hydrogen filling couplings, which are used in movable structures, like vehicles, are installed.

SUMMARY

GAS SUPPLY STRUCTURE

A gas supply structure 100 indicates: a nozzle 10 with a gas supply line 12 and a recipient 20 with an insertion opening 22 into which the neck 10 introduced to him, the recipient 20 with a first O-ring 24 which is near the insertion opening 22 is provided to provide a gas seal, and with a second O-ring 28 is provided, which is arranged in the gas supply path in the flow direction further down than the first O-ring 24 to provide a gas seal, with a portion of the second O-ring 28 using an adhesive 27 at a recess portion in the recipient 20 is attached, and an element 26 for removing foreign matter in the recipient is provided so that it partially protrudes beyond an inner peripheral surface extending from the insertion 22 the recipient 20 extends out.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• JP 2006-177253 A [0010]
• JP 2005-241882 A [0010]
• JP 2003-225540 A [0010]
• - JP 08-75098 A [0010]
• - JP 2007336307 [0057]

Cited non-patent literature

• - ISO 17268 [0004]
• - JIS B 8812 [0019]
• - JIS B 8812 [0042]
• - JIS B 8812 [0049]

Claims (16)

Gas supply structure, comprising: a neck, which supplies a gas, a recipient into which the Stutzen is introduced and thereby the supplied Receives gas, an O-ring in the recipient is provided and which seals the nozzle and the recipient and during the introduction of the neck against the Neck slips, and an element for removing foreign matter, that at a position closer to an insertion opening for the nozzle is provided as the O-ring, in the recipient is. Gas supply structure, comprising: a neck, which supplies a gas, a recipient into which the Stutzen is introduced and thereby the supplied Receives gas, an o-ring provided on the neck and that seals the neck and the recipient and the while the introduction of the neck against the neck slides, and an element for removing foreign matter, which at a Position closer to a front end of the neck lies as the O-ring, is provided at the neck. Gas supply structure, comprising: a recipient, in which a nozzle is introduced and thereby supplied Receives gas, an O-ring in the recipient is provided and which seals the nozzle and the recipient and during the introduction of the neck against the Neck slips, and an element for removing foreign matter, that at a position closer to an insertion opening for the nozzle is provided as the O-ring, in the recipient is. Gas supply structure, comprising: a recipient, in which a nozzle is introduced and thereby supplied Receives gas, an o-ring provided on the neck and that seals the neck and the recipient and the while the introduction of the neck against the neck slides, and an element for removing foreign matter, which at a Position closer to a front end of the neck lies as the O-ring, is provided at the neck. The gas supply structure of claim 1, further comprising: one O-ring on the side of an insertion opening in near the import opening in the recipient is provided. The gas delivery system of claim 2, further comprising: one O-ring on the side of an insertion opening in near the insertion opening in the recipient is provided. The gas delivery system of claim 3, further comprising: one O-ring on the side of an insertion opening in near the insertion opening in the recipient is provided. The gas delivery system of claim 4, further comprising: one O-ring on the side of an insertion opening in near the insertion opening in the recipient is provided. The gas delivery system of claim 1, further comprising: one Tank for storing the gas, a filter with a small one Loss coefficient, in a gas line, the recipient connects to the tank, on an upstream side is arranged, and a filter with a big one Loss coefficient, on a downstream side the gas line is arranged. The gas delivery system of claim 2, further comprising: one Tank for storing the gas, a filter with a small one Loss coefficient, in a gas line, the recipient connects to the tank, on an upstream side is arranged, and a filter with a big one Loss coefficient, on a downstream side the gas line is arranged. The gas delivery system of claim 3, further comprising: one Tank for storing the gas, a filter with a small one Loss coefficient, in a gas line, the recipient connects to the tank, on an upstream side is arranged, and a filter with a big one Loss coefficient, on a downstream side the gas line is arranged. The gas delivery system of claim 4, further comprising: one Tank for storing the gas, a filter with a small one Loss coefficient, in a gas line, the recipient connects to the tank, on an upstream side is arranged, and a filter with a big one Loss coefficient, on a downstream side the gas line is arranged. A gas supply structure according to claim 1, wherein: the Element for removing foreign substances has a sliding resistance, based on a pull-out force measurement prescribed in JIS B 8812 is determined and not smaller than 300 N and not larger than 500 N is. A gas delivery structure according to claim 2, wherein: the Element for removing foreign substances has a sliding resistance, based on a pull-out force measurement prescribed in JIS B 8812 is determined and not smaller than 300 N and not larger than 500 N is. A gas supply structure according to claim 3, wherein: the Element for removing foreign substances has a sliding resistance, based on a pull-out force measurement prescribed in JIS B 8812 is determined and not smaller than 300 N and not larger than 500 N is. A gas supply structure according to claim 4, wherein: the Element for removing foreign substances has a sliding resistance, based on a pull-out force measurement prescribed in JIS B 8812 is determined and not smaller than 300 N and not larger than 500 N is.