JP2015090188A - Insertion assembling mechanism of fuel battery component - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a force when inserting a component into a component to be inserted.SOLUTION: One of an insertion component and a component to be inserted has a first placing part for placing a first seal component thereon, and a second placing part for placing a second seal component thereon, and the another has a first seal part for performing seal between the first seal component and itself, and a second seal part for performing seal between the second seal component and itself, the first seal part has a first contact point at which the first seal part initially contacts with the first seal component when inserting the insertion component into the component to be inserted, and the second seal part has a second contact point at which the second seal part initially contacts with the second seal component when inserting the insertion component into the component to be inserted. When an interval between the first and second contact points is denoted by La, an interval between the first and second placing parts is denoted by Lb, a diameter of the first seal component before the insertion of the insertion component is denoted by Lc, and a diameter of the second seal component is denoted by Ld, at least either of relations of La-Lb-Lc>0 and Lb-La-Ld>0 is satisfied.

Description

  The present invention relates to an assembly mechanism for inserting a fuel cell component into another component for assembly.

  Patent Document 1 describes a drain valve. Two flow paths are formed in the insertion part of the drain valve to the other parts, and the gap between the drain valve insertion part and the other parts is sealed by two seal members (O-rings). Yes.

JP2013-93255A

  When the insertion portion of the drainage valve is inserted into another part, a large force is required at the time of insertion because the two seal members are inserted at the same time. This problem is not limited to the case where the drain valve insertion portion is inserted into another part, but includes an insertion part, an inserted part, and a plurality of seal parts provided between the inserted part and the inserted part. This is a common problem in the fuel cell component insertion and assembly mechanism.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms.

(1) According to one aspect of the present invention, an insertion assembly of a fuel cell component comprising an insertion component, a component to be inserted, and a plurality of seal components provided between the insertion component and the component to be inserted A mechanism is provided. In the insertion and assembling mechanism, one of the insertion part and the insertion target part is a first placement part for placing a first seal part and a second placement part for placing a second seal part. And the other of the inserted part and the inserted part seals between the first seal part that seals with the first seal part and the second seal part. A second seal portion, and the first seal portion has a first contact point that first contacts the first seal component when the insert component is inserted into the inserted component. The second seal portion has a second contact point that first comes into contact with the second seal component when the insert component is inserted into the component to be inserted, and the first contact point and the The distance from the second contact point is La, and the distance between the first placement part and the second placement part is b, where Lc is the diameter of the first seal part before insertion of the insertion part, and Ld is the diameter of the second seal part before insertion of the insertion part, La-Lb-Lc> 0 or Satisfy at least one of Lb-La-Ld> 0. In general, when an insertion part is inserted into a part to be inserted with a seal part interposed therebetween, a large force is required when the seal part comes into contact with the seal portion and deforms. According to the insertion assembly mechanism of this embodiment, the first seal part and the second seal part are deformed simultaneously by satisfying at least one of La-Lb-Lc> 0 or Lb-La-Ld> 0. do not do. As a result, it is possible to insert the insertion part into the part to be inserted with a small force as compared with the case of simultaneous deformation.

  Note that the present invention can be realized in various modes. For example, in addition to the fuel cell component insertion and assembly mechanism, it can be realized in the form of a fuel cell insertion component and a component to be inserted, a fluid channel joint structure, and the like.

It is explanatory drawing which expands and shows the coupling | bond part of the insertion part of the drain valve of this embodiment, and the insertion part of an insertion part. It is explanatory drawing which shows the insertion process in this embodiment. It is explanatory drawing which shows the relationship between the insertion amount and insertion load in this embodiment. It is explanatory drawing which expands and shows the coupling | bond part of the insertion part of the drain valve of a comparative example, and the insertion part of an insertion part. It is explanatory drawing which shows the insertion process in a comparative example. It is explanatory drawing which shows the relationship between the insertion amount and insertion load in a comparative example. It is explanatory drawing which shows the insertion process in the modification 1. It is explanatory drawing which shows the insertion process in the modification 2.

  Drawing 1 is an explanatory view expanding and showing a joint part of an insertion part of a drainage valve of this embodiment, and an insertion part of an insertion part. The drain valve 10 and the inserted part 30 are fuel cell parts used for fuel cell vehicles, respectively. The drainage valve 10 includes a valve part 100 and an insertion part 200. In the present embodiment, the one provided with the insertion part 200 is called an insertion part. The valve unit 100 includes a valve body 110, a valve seat 120, a plunger 130, a core 140, a coil 150, and a solenoid 160. The plunger 130 is a substantially cylindrical member and is connected to the valve body. A coil 150 wound around the core 140 is disposed inside the plunger 130. A solenoid 160 is disposed outside the plunger 130. Whether the coil 150 and the plunger 130 are moved and the space between the valve body 110 and the valve seat 120 is opened or closed is controlled depending on whether or not a current is applied to the solenoid 160.

  The insertion part 200 has a convex shape, and includes an inner cylinder part 210 having a substantially cylindrical shape and an outer cylinder part 220 having a substantially cylindrical shape. A first flow path 230 is formed inside the inner cylinder part 210, and a second flow path 240 is formed between the inner cylinder part 210 and the outer cylinder part 220. The first flow path 230 and the second flow path 240 are controlled to be non-communication and communication by contact and non-contact between the valve body 110 and the valve seat 120.

  The inner cylinder portion 210 has a first placement portion 215 having a stepped shape on the outside, and the first placement portion 215 is provided with a first O-ring 250 that is a seal component. The outer cylinder part 220 has the 2nd mounting part 225 which has step shape on the outer side, and the 2nd O-ring 260 which is a seal component is arrange | positioned at the 2nd mounting part 225. FIG.

  The part to be inserted 30 is a part into which the insertion part 200 is inserted, and is used, for example, at an end of a pipe. The inserted part 300 of the inserted part 30 has a concave shape. The inserted portion 300 performs sealing between the first seal portion 310 that seals with the first O-ring 250 and the second O-ring 260 when the insertion portion 200 is inserted. 2nd seal part 320 is provided. The first seal portion 310 has a first contact point 311 that makes first contact with the first O-ring 250, and the second seal portion 320 has a second contact that makes first contact with the second O-ring 260. Contact point 321. The insertion part 200 and the insertion target part 300 constitute an insertion assembly mechanism.

  FIG. 2 is an explanatory view showing an insertion step in the present embodiment. In FIG. 2, the cross section in the range surrounded by the alternate long and short dash line in FIG. 1 is enlarged. Note that the first contact point 311 and the second contact point 321 are illustrated as corner vertices for easy understanding. In FIG. 2, the first flow path 230 and the second flow path 240 are not shown.

  When the insertion portion 200 is inserted into the insertion portion 300, as shown in FIG. 2A, the first O-ring 250 and the first contact point 311 come into contact with each other, and the first O-ring 250 is deformed. Begin to. When the insertion part 200 is further inserted into the insertion part 300, the position of the first placement part 215 in the insertion direction is the same as the position of the first contact point 311 as shown in FIG. Reach. When the insertion portion 200 is inserted into the insertion target portion 300 up to this position, the first O-ring 250 is no longer deformed. In this state, the first O-ring 250 performs a seal between the insertion portion 200 and the insertion target portion 300. In the present embodiment and the comparative examples and modifications described later, changing the cross-sectional shape of the O-ring is referred to as deformation, and if the cross-sectional shape of the O-ring once deformed is maintained in a deformed state, It shall not be called.

  When the insertion portion 200 is further inserted into the insertion portion 300, as shown in FIG. 2C, the contact point 261 of the second O-ring 260 (referred to as the “second O-ring contact point 261”). And the second contact point 321 come into contact with each other, and the second O-ring 260 starts to deform.

  When the insertion portion 200 is further inserted into the insertion portion 300, the position of the second placement portion 225 in the insertion direction reaches the same position as the second contact point 321 as shown in FIG. Reach. When the insertion portion 200 is inserted into the insertion target portion 300 up to this position, the second O-ring 260 is no longer deformed. In this state, the second O-ring 260 performs a seal between the insertion portion 200 and the insertion target portion 300.

  FIG. 3 is an explanatory diagram showing the relationship between the insertion amount and the insertion load. 3A to 3D correspond to the states of FIGS. 2A to 2D. When the insertion portion 200 is changed to the insertion portion 300 and the state shown in FIG. 2A is reached, the first contact point 311 is referred to as a contact point of the first O-ring 250 (referred to as “first O-ring contact point 251”). )), The first O-ring 250 begins to deform, and the insertion load increases. Until the state shown in FIG. 2B, the insertion load is hardly changed. When the insertion portion 200 is inserted into the insertion target portion 300 until the state shown in FIG. 2B, the first O-ring 250 is no longer deformed, so the insertion load is reduced.

  Further, when the insertion portion 200 is inserted into the insertion portion 300 and enters the state shown in FIG. 2C, the second contact point 321 contacts the second O-ring 260, and the second O-ring 260 begins to deform. . Therefore, the insertion load becomes large. Further, when the insertion part 200 is inserted into the insertion part 300 and the position of the second mounting part 225 in the insertion direction reaches the same position as the position of the second contact point 321, the state shown in FIG. Since the second O-ring 260 is no longer deformed, the insertion load is reduced.

  FIG. 4 is an explanatory view showing, in an enlarged manner, a coupling portion between the insertion portion of the drain valve and the insertion portion of the inserted component of the comparative example. In FIG. 4, members having the same functions as those in the present embodiment are denoted by the same reference numerals. In the comparative example and this embodiment, the distance between the first placement part 215 and the second placement part 225 in the insertion part 200 and the distance between the first contact point 311 and the second contact point 321 in the inserted part 300. Are different, but the others are the same.

  FIG. 5 is an explanatory diagram showing an insertion process in a comparative example. In the comparative example, the same members as those in the present embodiment are denoted by the same reference numerals. In FIG. 5, the cross section in the range surrounded by the one-dot chain line in FIG. 4 is enlarged. In FIG. 5, the first flow path 230 and the second flow path 240 are not shown. The difference between this embodiment and the comparative example is that the distance La between the first contact point 311 and the second contact point 321 and the distance between the first placement part 215 and the second placement part 225 are different. It is in the interval Lb.

  When the insertion portion 200 is inserted into the insertion portion 300, the first O-ring 250 and the first contact point 311 come into contact as shown in FIG. Here, the first O-ring 250 starts to deform. Further, when the insertion portion 200 is inserted into the insertion portion 300, in the modified example, the position of the first placement portion 215 in the insertion direction is the position of the first contact point 311 as shown in FIG. Before reaching the same position, the second O-ring 260 comes into contact with the second contact point 321 and the second O-ring 260 starts to deform. In this embodiment, as shown in FIGS. 2B and 2C, the position of the first placement portion 215 in the insertion direction first reaches the same position as the position of the first contact point, and then The second O-ring 260 and the second contact point 321 come into contact with each other, and the second O-ring 260 starts to deform.

  When the insertion part 200 is further inserted into the insertion part 300, the position of the first placement part 215 in the insertion direction reaches the same position as the position of the first contact point 311. When the insertion portion 200 is inserted into the insertion portion 300 up to this position, the first O-ring 250 is no longer deformed, and only the second O-ring 260 is deformed. When the insertion portion 200 is further inserted into the insertion portion 300, the position of the second placement portion 225 in the insertion direction reaches the same position as the second contact point 321 as shown in FIG. Reach. When the insertion portion 200 is inserted into the insertion target portion 300 up to this position, the second O-ring 260 is no longer deformed.

  FIG. 6 is an explanatory diagram showing the relationship between the insertion amount and the insertion load in the comparative example. Only the first O-ring 250 is deformed between FIGS. 6E to 6F. The insertion load during this period is approximately the same as the insertion load in FIGS. 3A to 3B of the present embodiment. Between FIG. 6 (F) and FIG. 6 (G), both the first O-ring 250 and the second O-ring 260 are deformed. The insertion load is approximately twice the insertion load up to (F). Moreover, the magnitude | size of the load in the meantime is larger than the insertion load in FIG.3 (C)-(D) of this embodiment. Between FIGS. 6G to 6H, the first O-ring 250 is not further deformed, and only the second O-ring 260 is deformed. The insertion load during this period is smaller than the insertion load between FIGS. 6 (E) to 6 (F). In addition, the magnitude | size of the insertion load in the meantime is substantially the same magnitude | size as the insertion load in FIG.3 (C)-(D) of this embodiment.

  Comparing the present embodiment and the comparative example, when both the first O-ring 250 and the second O-ring 260 are deformed at the same time as shown in FIGS. growing. Therefore, the positions of the first placement unit 215 and the second placement unit 225, and the first contact point 311 so that both the first O-ring 250 and the second O-ring 260 are not deformed simultaneously. If the position of the second contact point 321 is determined, the maximum value of the insertion load can be lowered. In addition, when the maximum value of the insertion load was measured, it was 40N to 90N in the comparative example, whereas in this embodiment, it was 20N to 40N, which was halved or less.

  2 and 5, the interval in the insertion direction of the insertion portion 200 between the first contact point 311 and the second contact point 321 is La, and the first placement portion 215 and the second placement portion 225. The interval in the insertion direction of the insertion portion 200 between the two is Lb, the diameter of the first O-ring 250 is Lc, and the diameter of the second O-ring 260 is Ld. Further, the distance between the second contact point 321 and the second placement portion 225 when the second contact point 321 and the second O-ring 260 are in contact with each other is Lx (FIG. 2C). ). In general, Lx <Ld. In FIG. 2B, the distance between the second contact point 321 and the second O-ring contact point 261 is Lb-La-Lx. If this value is a positive value, the second O-ring 260 does not contact the second contact point 321 when the first O-ring 250 stops deforming. In this case, after the deformation of the first O-ring 250 is finished, the second O-ring 260 comes into contact with the second contact point 321 and the second O-ring 260 starts to deform. That is, both the first O-ring 250 and the second O-ring 260 are not deformed simultaneously. Note that the value of Lx also depends on the interval in the radial direction with the insertion direction of the insertion portion 200 and the insertion target portion 300 as an axis. Considering the above-described Lx <Ld, the positions of the first placement unit 215 and the second placement unit 225, the first contact point 311 and the second position so as to satisfy Lb-La-Ld> 0. If the position of the contact point 321 is determined, the second O-ring 260 comes into contact with the second contact point 321 after the deformation of the first O-ring 250 is finished, and the second O-ring 260 is deformed. Can be configured to start. As a result, the maximum value of the insertion load can be lowered.

One of the insertion portion 200 and the insertion target portion 300 has the same shape as that of the comparative example, and the other shape is changed so as to satisfy either Lb-La-Ld> 0 or La-Lb-Lc> 0. May be.

Modification 1:
FIG. 7 is an explanatory diagram showing an insertion process in the first modification. In FIG. 7, as in FIG. 2, the first flow path 230 and the second flow path 240 are not shown. In the present embodiment, the distance Lb between the first placement portion 215 and the second placement portion 225 in the insertion portion 200 is greater than the first contact point 311 and the second contact point 321 in the insertion portion 300. Although the distance La is larger than the distance La, in the comparative example, the distance La between the first contact point 311 and the second contact point 321 in the inserted portion 300 is larger than the first placement portion 215 in the insertion portion 200. It is larger than the interval Lb between the two mounting portions 225.

  When the insertion portion 200 is inserted into the insertion portion 300, as shown in FIG. 7A, the second O-ring 260 and the second contact point 321 come into contact with each other, and the second O-ring 260 is deformed. Begin to. When the insertion portion 200 is further inserted into the insertion portion 300, the position of the second placement portion 225 in the insertion direction is the same as the position of the second contact point 321 as shown in FIG. Reach. When the insertion portion 200 is inserted into the insertion target portion 300 up to this position, the second O-ring 260 is no longer deformed. When the insertion portion 200 is further inserted into the insertion portion 300, as shown in FIG. 7C, the first O-ring 250 and the first contact point 311 come into contact, and the first O-ring 250 is Start to transform. When the insertion portion 200 is further inserted into the insertion portion 300, the position of the first placement portion 215 in the insertion direction is the same as the position of the first contact point 311 as shown in FIG. Reach. When the insertion portion 200 is inserted into the insertion target portion 300 up to this position, the first O-ring 250 is no longer deformed.

  In the first modification, Ly is the distance between the first contact point 311 and the first placement portion 215 when the first contact point 311 and the first O-ring 250 are in contact (FIG. 7). (C)). As in the present embodiment, Ly <Lc. In the state of FIG. 7B, the interval in the insertion direction of the insertion portion 200 between the first O-ring 250 and the first contact point 311 is La-Lb-Ly. If this value is a positive value, the first O-ring 250 is not in contact with the first contact point 311 when the second O-ring 260 stops deforming. As a result, after the deformation of the second O-ring 260 is finished, the first O-ring 250 comes into contact with the first contact point 311 and the first O-ring 250 starts to deform. That is, both the first O-ring 250 and the second O-ring 260 are not deformed simultaneously. Note that the value of Ly also depends on the interval in the radial direction about the insertion direction of the insertion portion 200 and the insertion portion 300. Considering Ly <Lc described above, the positions of the first placement unit 215 and the second placement unit 225, the first contact point 311 and the second position so as to satisfy La-Lb-Lc> 0. If the position of the contact point 321 is determined, after the second O-ring 260 is reliably deformed, the first O-ring 250 comes into contact with the first contact point 311 and the first O-ring 250 is deformed. Can be configured to start. As a result, the maximum value of the insertion load can be lowered.

Modification 2:
FIG. 8 is an explanatory diagram showing an insertion process in the second modification. In the present embodiment, the first O-ring 250 and the second O-ring 260 are disposed in the insertion portion 200. However, in the second modification, the first O-ring 250 and the second O-ring are disposed in the insertion portion 300. The difference is that the ring 260 is arranged. Specifically, in the second modification, the first placement portion 315 and the second placement portion 325 are formed in the inserted portion 300, and the first O-ring 250 and the second O-ring 260 are respectively formed. It is placed. In the second modification, the first seal portion 270 and the second seal portion 280 are formed in the insertion portion 200. The first seal portion 270 has a first contact point 271 that makes initial contact with the first O-ring 250, and the second seal portion 280 has a second contact that makes initial contact with the second O-ring 260. It has a point 281.

  When the insertion portion 200 is inserted into the insertion portion 300, as shown in FIG. 8A, the first O-ring 250 and the first contact point 271 come into contact with each other, and the first O-ring 250 is deformed. Begin to. When the insertion portion 200 is further inserted into the insertion portion 300, the position of the first placement portion 315 in the insertion direction is the same as the position of the first contact point 271 as shown in FIG. Reach. When the insertion portion 200 is inserted into the insertion target portion 300 up to this position, the first O-ring 250 is no longer deformed. When the insertion portion 200 is further inserted into the insertion portion 300, the second O-ring 260 and the second contact point 281 come into contact with each other as shown in FIG. Start to transform. When the insertion portion 200 is further inserted into the insertion portion 300, the position of the second placement portion 325 in the insertion direction is the same as the position of the second contact point 281 as shown in FIG. Reach. When the insertion portion 200 is inserted into the insertion target portion 300 up to this position, the second O-ring 260 is no longer deformed.

  In FIG. 8, the interval in the insertion direction of the insertion portion 200 between the first contact point 271 and the second contact point 281 is La, and between the first placement portion 315 and the second placement portion 325. The interval of the insertion portion 200 in the insertion direction is Lb, the diameter of the first O-ring 250 is Lc, and the diameter of the second O-ring 260 is Ld. Similarly, if either Lb-La-Ld> 0 or La-Lb-Lc> 0 is satisfied, both the first O-ring 250 and the second O-ring 260 can be prevented from being deformed simultaneously.

  In the present embodiment, the drain valve 10 and the inserted part 300 of the part to be inserted into which the insertion part 200 of the drain valve 10 is inserted have been described as an example. However, in this configuration, one of two members for flowing fluid is the other. It can be used in an insertion assembly mechanism that is inserted into the assembly.

  The embodiments of the present invention have been described above based on some examples. However, the above-described embodiments of the present invention are for facilitating the understanding of the present invention and limit the present invention. It is not a thing. The present invention can be changed and improved without departing from the spirit and scope of the claims, and it is needless to say that the present invention includes equivalents thereof.

DESCRIPTION OF SYMBOLS 10 ... Drain valve 30 ... Inserted part 100 ... Valve part 110 ... Valve body 120 ... Valve seat 130 ... Plunger 140 ... Core 150 ... Coil 160 ... Solenoid 200 ... Insertion part 210 ... Inner cylinder part 215 ... First mounting Part 220 ... Outer cylinder part 225 ... Second placement part 230 ... First flow path 240 ... Second flow path 250 ... First O-ring 251 ... First O-ring contact point 260 ... Second O Ring 261 ... second O-ring contact point 270 ... first seal part 271 ... first contact point 280 ... second seal part 281 ... second contact point 300 ... inserted part 310 ... first seal part 311 ... 1st contact point 315 ... 1st mounting part 320 ... 2nd seal | sticker part 321 ... 2nd contact point 325 ... 2nd mounting part

Claims (1)

An insertion assembly mechanism for a fuel cell component comprising an insertion component, a component to be inserted, and a plurality of seal components provided between the insertion component and the component to be inserted,
One of the insertion part and the part to be inserted has a first placement part for placing a first seal part and a second placement part for placing a second seal part,
The other of the insertion part and the part to be inserted is a first seal part that seals with the first seal part, and a second seal part that seals with the second seal part And
The first seal portion has a first contact point that first comes into contact with the first seal component when the insertion component is inserted into the inserted component.
The second seal portion has a second contact point that first comes into contact with the second seal component when the insertion component is inserted into the inserted component.
The interval between the first contact point and the second contact point is La, the interval between the first placement part and the second placement part is Lb, and the first part before the insertion part is inserted. When the diameter of the sealing part is Lc and the diameter of the second sealing part before the insertion part is Ld,
La-Lb-Lc> 0 or Lb-La-Ld> 0
An insertion assembly mechanism that satisfies at least one of the above.

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