JP2010140666A - Stacking load adjusting device for fuel cell stack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily and satisfactorily adjusting a stack fastening load while reducing deflection with an aligning function. <P>SOLUTION: This stacking load adjusting device 10 is arranged between an end plate 44a and an insulating plate 42a constituting a fuel cell stack 12. It includes a pair of inclined members 50a, 50b having inclined faces 58a, 58b inclined in mutually opposite directions, a moving mechanism 52 having a right screw member 60a and a left screw member 60b, and adapted to be rotated in one direction for moving the pair of inclined members 50a, 50b in the direction of approaching each other and adapted to be rotated in the other direction for moving the pair of inclined members 50a, 50b in the direction of leaving each other, and a thrust member 54 arranged between the pair of inclined members 50a, 50b and a unit cell 14 and adapted to be moved in the stacking direction of the unit cell 14 under the moving operation of the pair of inclined members 50a, 50b. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention comprises a laminate in which a plurality of unit cells each having an electrolyte / electrode structure and a separator provided with a pair of electrodes on both sides of the electrolyte are laminated, and end plates are provided at both ends in the lamination direction of the laminate. The present invention relates to a stack load adjusting device for a fuel cell stack.

  For example, a polymer electrolyte fuel cell employs an electrolyte membrane (electrolyte) made of a polymer ion exchange membrane. A fuel cell (unit cell) is configured by sandwiching an electrolyte membrane / electrode structure (MEA) in which an anode side electrode and a cathode side electrode are disposed on both sides of the electrolyte membrane with a separator.

  Normally, this fuel cell is used as a fuel cell stack in which a predetermined number (for example, several tens to several hundreds) is stacked in order to obtain a desired power generation. In this fuel cell stack, the stacked fuel cells need to be reliably pressurized and held in order to prevent an increase in the internal resistance of the fuel cell and a decrease in the sealing performance of the reaction gas.

  Therefore, for example, in the flat solid electrolyte fuel cell disclosed in Patent Document 1, as shown in FIG. 9, a holding frame 3 including a bottom plate 1 and side plates 2 a and 2 b standing upright from both ends of the bottom plate 1. It has.

  On the bottom plate 1, a stack 4 in which single cells are stacked in a horizontal direction is placed, and a wedge-like shape is provided between a clamping plate 5 having an inclined surface 5a superimposed on an end surface of the stack 4 and the side plate 2a. The inclined plate 6 is inserted. Then, by placing a weight on the inclined plate 6, a downward load generates a horizontal force via the inclined surface 5a, and the stack 4 is tightened by this force.

Japanese Patent Laid-Open No. 6-1888023

  However, in Patent Document 1 described above, the stack 4 is fastened under the pressing action of the single fastening plate 5 having the inclined surface 5a, and therefore there is a possibility that the stack 4 cannot be evenly pressed in the stacking direction. In particular, on the side of the bottom plate 1 that is separated from the inclined surface 5a, it is difficult to apply a desired tightening force to the stack 4, and there is a problem that the stack 4 is likely to be bent. In addition, it is difficult to maintain the parallelism of the fastening plate 5, it cannot have a centering function, and there is a problem that it is difficult to effectively suppress shaking from an external impact or vibration. .

  The present invention solves this type of problem, and is a high-quality fuel cell that can easily and satisfactorily adjust the tightening load of the laminate and has a centering function to reduce bending and the like. An object of the present invention is to provide a stack load adjusting device for a stack.

  The present invention comprises a laminate in which a plurality of unit cells having a separator and an electrolyte / electrode structure provided with a pair of electrodes on both sides of an electrolyte membrane are laminated, and end plates are provided at both ends in the lamination direction of the laminate. The present invention relates to a stack load adjusting device for a fuel cell stack.

  The stacked load adjusting device is disposed inside at least one end plate, is movable in the surface direction of the end plate, and has a pair of inclined members having inclined surfaces inclined in opposite directions, a right screw portion and a left screw A moving mechanism that has a threaded portion and moves the pair of inclined members in directions close to each other by rotation in one direction, and moves the pair of inclined members in directions away from each other by rotation in the other direction; And a pressing member that is arranged between the inclined member and the laminated body and moves in the laminating direction of the laminated body under the moving action of the pair of inclined members.

  In addition, the moving mechanism includes a right screw portion fixed to one inclined member, a left screw portion fixed to the other inclined member, the right screw portion and the left screw portion being integrally screwed and rotated. It is preferable to provide an operated nut portion.

  Furthermore, the end plate is preferably formed with an opening for rotating the nut portion from the outside.

  Furthermore, the moving mechanism includes a connecting rod body in which a right screw portion that is screwed to one inclined member and a left screw portion that is screwed to the other inclined member are integrally connected, and an end portion of the connecting rod body It is preferable to include an operation unit that is provided on the control unit and rotates the connecting rod body.

  Moreover, it is preferable that a press member has an inclined surface contact | abutted to each inclined surface of a pair of inclined member.

  According to the present invention, when the moving mechanism is rotated in one direction, the pair of inclined members move in directions close to each other. Therefore, the pressing member that contacts the inclined surfaces of the pair of inclined members maintains parallelism. It moves to one side of the lamination direction of the laminated body in the state. Further, when the moving mechanism is rotated in the other direction, the pair of inclined members move away from each other. Therefore, the pressing member that abuts the inclined surfaces of the pair of inclined members maintains the parallelism while maintaining the parallelism. It moves to the other lamination direction.

  Therefore, only by rotating the moving mechanism, the pressing member can advance and retract in the stacking direction while maintaining the parallelism. This makes it possible to easily and satisfactorily adjust the tightening load of the laminated body via the pressing member, and to have a centering function to reduce bending and the like.

  FIG. 1 is a schematic perspective view of a fuel cell stack 12 incorporating the stack load adjusting device 10 according to the first embodiment of the present invention, and FIG. 2 is a side view of the fuel cell stack 12.

  The fuel cell stack 12 is used for in-vehicle use, for example. The fuel cell stack 12 constitutes a stacked body in which a plurality of unit cells 14 are stacked in the direction of arrow A. As shown in FIG. 3, the unit cell 14 includes an electrolyte membrane / electrode structure 16, and a first separator 18 and a second separator 20 that sandwich the electrolyte membrane / electrode structure 16. The first separator 18 and the second separator 20 are constituted by a carbon separator or a metal separator.

  The first separator 18 and the second separator 20 have a vertically long shape, and are configured such that the long side is directed in the direction of gravity (arrow C direction) and the short side is directed in the horizontal direction (arrow B direction).

  The upper end edge of the unit cell 14 in the long side direction communicates with each other in the direction of arrow A, and an oxidant gas supply communication hole 22a for supplying an oxidant gas, for example, an oxygen-containing gas, and a fuel gas, for example, A fuel gas supply passage 24a for supplying a hydrogen-containing gas is provided.

  The lower end edge of the unit cell 14 in the long side direction communicates with each other in the direction of the arrow A, and the fuel gas discharge communication hole 24b for discharging the fuel gas, and the oxidant gas discharge for discharging the oxidant gas. A communication hole 22b is provided.

  At one edge of the unit cell 14 in the short side direction (arrow B direction), there is provided a cooling medium supply communication hole 26a that communicates with each other in the arrow A direction and supplies a cooling medium. A cooling medium discharge communication hole 26b for discharging the cooling medium is provided at the other end edge in the short side direction.

  The electrolyte membrane / electrode structure 16 includes, for example, a solid polymer electrolyte membrane 28 in which a perfluorosulfonic acid thin film is impregnated with water, and a cathode side electrode 30 and an anode side electrode 32 sandwiching the solid polymer electrolyte membrane 28. With.

  The cathode side electrode 30 and the anode side electrode 32 are uniformly coated on the surface of the gas diffusion layer with a gas diffusion layer (not shown) made of carbon paper or the like, and porous carbon particles carrying a platinum alloy on the surface. An electrode catalyst layer (not shown). The electrode catalyst layers are formed on both surfaces of the solid polymer electrolyte membrane 28.

  An oxidant gas flow path 34 that connects the oxidant gas supply communication hole 22a and the oxidant gas discharge communication hole 22b is formed on the surface 18a of the first separator 18 facing the electrolyte membrane / electrode structure 16. The oxidizing gas channel 34 extends in the direction of arrow C (vertical direction).

  A fuel gas flow path 36 that connects the fuel gas supply communication hole 24 a and the fuel gas discharge communication hole 24 b is formed on the surface 20 a of the second separator 20 facing the electrolyte membrane / electrode structure 16. The fuel gas channel 36 extends in the direction of arrow C.

  Between the surface 20b of the second separator 20 and the surface 18b of the first separator 18, a cooling medium flow path 38 communicating with the cooling medium supply communication hole 26a and the cooling medium discharge communication hole 26b is formed. The cooling medium flow path 38 extends in the arrow B direction.

  Between the electrolyte membrane / electrode structure 16 and the first separator 18 and the second separator 20 and between the first separator 18 and the second separator 20 adjacent to each other (between the adjacent unit cells 14), Although not shown, a seal member is provided.

  As shown in FIGS. 1 and 2, terminal plates 40a and 40b, insulating plates 42a and 42b, and end plates 44a and 44b are disposed outward at both ends of the unit cell 14 in the stacking direction. The end plates 44a and 44b are made of a light metal such as aluminum or magnesium, for example.

  In the fuel cell stack 12, for example, rectangular end plates 44 a and 44 b are integrally clamped and held by a plurality of tie rods 46 extending in the arrow A direction. The fuel cell stack 12 may be integrally held by a box-shaped casing (not shown) including end plates 44a and 44b as end plates.

  The laminated load adjusting device 10 is disposed between the end plate 44a and the insulating plate 42a. As shown in FIGS. 1, 2 and 4, the laminated load adjusting device 10 is disposed in sliding contact with the inner surface of the end plate 44a and has a pair of inclined members 50a and 50b having symmetrical shapes, and the inclined members. A moving mechanism 52 that moves the members 50a and 50b integrally in a direction toward and away from each other, and the inclined members 50a and 50b and the insulating plate 42a are disposed between the inclined members 50a and 50b. And a pressing member 54 that moves in the stacking direction (arrow A direction) of the plurality of unit cells 14.

  The inclined members 50a and 50b have a substantially wedge shape. The inclined member 50a disposed above has a sliding surface 56a adjacent to the end plate 44a, and an inclined surface 58a facing the pressing member 54 is provided on the opposite side of the sliding surface 56a. The inclined surface 58a is inclined toward the end plate 44a in the vertically downward direction.

  The inclined member 50b disposed below has a sliding surface 56b slidably contacting the end plate 44a, and an inclined surface 58b is provided on the opposite side of the sliding surface 56b so as to face the pressing member 54. The inclined surface 58b is inclined in the opposite direction to the inclined surface 58a, that is, in the vertically upward direction toward the end plate 44a.

  The moving mechanism 52 is embedded in the inclined member 50a and has one or more lower end portions extending downward from the inclined member 50a, for example, two right screw members 60a and the inclined member 50b, and the upper end portion. 1 or more extending upward from the inclined member 50b, for example, two left screw members 60b, and two nut members 62 screwing the right screw member 60a and the left screw member 60b together. (So-called turnbuckle). For example, the nut member 62 has a hexagonal outer periphery, whereby the rotation operation is simplified through a spanner (not shown).

  The inclined members 50a and 50b may be divided into right and left (for example, divided into two) corresponding to the two right-handed screw members 60a and the two left-handed screw members 60b, respectively.

  The end plate 44a is formed with two openings 64 that can rotate the nut members 62 from the outside. The pressing member 54 has a flat surface 66 on the unit cell 14 side and inclined surfaces 68a and 68b corresponding to the inclined surfaces 58a and 58b on the inclined members 50a and 50b side.

  Although not shown, a cooling medium supply communication hole 26a and a cooling medium discharge communication hole 26b are provided at both left and right edge portions of the end plate 44b. An oxidant gas supply communication hole 22a, a fuel gas supply communication hole 24a, an oxidant gas discharge communication hole 22b, and a fuel gas discharge communication hole 24b are provided at both upper and lower edges of the end plate 44b.

  The operation of the fuel cell stack 12 configured as described above will be described below.

  First, as shown in FIG. 1, in the fuel cell stack 12, an oxidant gas such as an oxygen-containing gas, a fuel gas such as a hydrogen-containing gas, and a cooling medium such as pure water or ethylene glycol are provided from the end plate 44b side. Supplied.

  As shown in FIG. 3, the oxidant gas is introduced into the oxidant gas flow path 34 of the first separator 18 from the oxidant gas supply communication hole 22 a constituting each unit cell 14, and the electrolyte membrane / electrode structure 16 It moves vertically downward along the cathode side electrode 30. On the other hand, the fuel gas is introduced into the fuel gas flow path 36 of the second separator 20 from the fuel gas supply communication hole 24 a constituting each unit cell 14, and vertically along the anode side electrode 32 of the electrolyte membrane / electrode structure 16. Move down.

  As described above, in each electrolyte membrane / electrode structure 16, the oxidant gas supplied to the cathode side electrode 30 and the fuel gas supplied to the anode side electrode 32 are subjected to an electrochemical reaction in the electrode catalyst layer. It is consumed and power is generated.

  Next, the oxidant gas consumed by being supplied to the cathode side electrode 30 is discharged from the oxidant gas discharge communication hole 22b to the end plate 44b side. Similarly, the fuel gas supplied to and consumed by the anode side electrode 32 is discharged from the fuel gas discharge communication hole 24b to the end plate 44b side.

  The cooling medium is introduced into the cooling medium flow path 38 between the first and second separators 18 and 20. This cooling medium flows along the arrow B direction (horizontal direction), cools the electrolyte membrane / electrode structure 16, and is then discharged from the cooling medium discharge communication hole 26b to the end plate 44b side.

  In this case, in the first embodiment, the stack load adjusting device 10 is provided in the fuel cell stack 12. In this laminated load adjusting device 10, when each nut member 62 constituting the moving mechanism 52 is rotated in one direction through each opening 64 of the end plate 44a, a right-hand thread member that is screwed into the nut member 62. For example, 60a moves vertically downward, and the inclined member 50a in which the right screw member 60a is embedded moves vertically downward (see FIG. 5).

  On the other hand, the left screw member 60b that is screwed into the nut member 62 moves in the opposite direction to the right screw member 60a, that is, vertically upward. For this reason, the inclined member 50b in which the left screw member 60b is embedded moves vertically upward (see FIG. 5).

  Accordingly, the pair of inclined members 50a and 50b move in the directions close to each other, and the pressing member 54 having the inclined surfaces 68a and 68b that contact the inclined surfaces 58a and 58b of the inclined members 50a and 50b maintains parallelism. In this state, the plurality of unit cells 14 move to one side (end plate 44b side) in the stacking direction. As a result, the pressing member 54 can easily and satisfactorily adjust the tightening load of the plurality of unit cells 14 under the moving action of the pair of inclined members 50a and 50b.

  Moreover, the pair of upper and lower inclined members 50a and 50b are arranged symmetrically with each other. For this reason, while suppressing that the pressing member 54 rock | fluctuates with respect to the lamination direction, the alignment function by the wedge shape of the inclination members 50a and 50b can be exhibited. Accordingly, the plurality of unit cells 14 can maintain parallel movement with respect to the stacking direction, and, for example, the occurrence of bending is prevented as much as possible, and the tightening load adjustment is performed smoothly and satisfactorily. There is an advantage that. Thereby, a high-quality fuel cell stack 12 can be easily obtained.

  When the tightening load by the laminated load adjusting device 10 is relaxed, the nut member 62 is rotated in the reverse direction, and the right screw member 60a and the left screw member 60b that are screwed into the nut member 62 are separated from each other. Move. For this reason, the pair of inclined members 50a and 50b move in directions away from each other, and the pressing member 54 moves toward the end plate 44a, thereby reducing the tightening load.

  FIG. 6 is a schematic perspective view of a lamination load adjusting device 80 according to the second embodiment of the present invention, and FIG. 7 is a side view of the lamination load adjusting device 80. In addition, the same referential mark is attached | subjected to the component same as the lamination load adjustment apparatus 10 and fuel cell stack 12 which concern on 1st Embodiment, and the detailed description is abbreviate | omitted.

  The stacked load adjusting device 80 includes a pair of inclined members 82a and 82b, a moving mechanism 84, and a pressing member 54. The upper inclined member 82a is provided with one or more, for example, two screw holes 86a penetrating in the vertical direction, and the lower inclined member 82b is coaxial with the screw hole 86a and reversely screwed. A certain two screw holes 86b are formed penetrating in the vertical direction.

  The moving mechanism 84 includes a connecting rod 90 in which a right screw portion 88a screwed into the screw hole 86a of the inclined member 82a and a left screw portion 88b screwed into the screw hole 86b of the inclined member 82b are integrally connected. . At the end of each connecting rod 90, a knob portion (operating portion) 92 for rotating the connecting rod 90 is provided.

  In the second embodiment configured as described above, when the knob portion 92 configuring the moving mechanism 84 is rotated in one direction, the right screw portion 88a and the left screw portion 88b provided in the connecting rod 90 are Rotate in one direction. Accordingly, the inclined member 82a provided with the screw hole 86a into which the right screw portion 88a is screwed and the inclined member 82b provided with the screw hole 86b to be screwed into the left screw portion 88b move, for example, in directions close to each other. .

  For this reason, under the pressing action of the inclined surfaces 58a and 58b of the inclined members 82a and 82b, the pressing member 54 moves in the direction of tightening each unit cell 14 and applies a tightening load to the unit cell 14. At that time, the pressing member 54 can move in the stacking direction while maintaining the parallel movement, and the same effect as the first embodiment can be obtained.

  In the second embodiment, a knob portion 92 that is an operation portion is provided at the end of the connecting rod 90. For example, the end plate 44a has an opening for exposing the knob portion 92. There is an advantage that it becomes unnecessary.

  FIG. 8 is an explanatory side view of the fuel cell stack 12 incorporating the laminated load adjusting apparatus 100 according to the third embodiment of the present invention. Note that the same reference numerals are assigned to the same components as those of the stacked load adjusting device 80 and the fuel cell stack 12 according to the second embodiment, and detailed description thereof is omitted.

  The stacked load adjusting device 100 includes a pair of inclined members 82a and 82b, a moving mechanism 84, and an end plate 102. The end plate 102 has inclined surfaces 68a and 68b toward the unit cell 14, while the inclined members 82a and 82b are disposed so that the inclined surfaces 58a and 58b face the inclined surfaces 68a and 68b.

  In the third embodiment configured as described above, when the knob portion 92 constituting the moving mechanism 84 is rotated in one direction, the right screw portion 88a and the left screw portion 88b provided in the connecting rod 90 are Rotate in one direction. Accordingly, the inclined member 82a and the inclined member 82b move, for example, in directions close to each other. For this reason, the inclined member 82a and the inclined member 82b are in a direction to tighten the unit cells 14 under the pressing action of the inclined surfaces 58a and 58b of the inclined members 82a and 82b and the inclined surfaces 68a and 68b of the end plate 102. Moving.

  Thereby, in 3rd Embodiment, the effect similar to said 1st and 2nd embodiment is acquired.

  In the first to third embodiments, the pair of inclined members 50a and 50b and 82a and 82b are provided on the upper and lower sides, but the present invention is not limited to this. For example, a pair of inclined members (not shown) may be disposed on the left and right.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic perspective view of a fuel cell stack incorporating a stack load adjusting device according to a first embodiment of the present invention. It is side surface explanatory drawing of the said fuel cell stack. It is a disassembled perspective view of the unit cell which comprises the said fuel cell stack. It is principal part perspective explanatory drawing of the said lamination | stacking load adjustment apparatus. It is operation | movement explanatory drawing of the said lamination | stacking load adjustment apparatus. It is principal part perspective explanatory drawing of the lamination | stacking load adjustment apparatus which concerns on the 2nd Embodiment of this invention. It is side surface explanatory drawing of the said lamination | stacking load adjustment apparatus. It is side surface explanatory drawing of the fuel cell stack incorporating the lamination load adjusting device which concerns on the 3rd Embodiment of this invention. 2 is an explanatory diagram of a flat plate solid electrolyte fuel cell disclosed in Patent Document 1. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 80, 100 ... Laminate load adjustment apparatus 12 ... Fuel cell stack 14 ... Unit cell 16 ... Electrolyte membrane and electrode structure 18, 20 ... Separator 28 ... Solid polymer electrolyte membrane 30 ... Cathode side electrode 32 ... Anode side electrode 40a Terminal plates 42a, 42b ... Insulating plates 44a, 44b, 102 ... End plates 50a, 50b, 82a, 82b ... Inclined members 52, 84 ... Moving mechanism 54 ... Press members 58a, 58b ... Inclined surfaces 60a, 88a ... Right Screw member 60b, 88b ... Left screw member 62 ... Nut member 64 ... Opening 86a, 86b ... Screw hole 90 ... Connecting rod 92 ... Knob portion

Claims (5)

Provided with a laminate in which a plurality of unit cells each having an electrolyte / electrode structure provided with a pair of electrodes on both sides of an electrolyte and a separator are laminated, and end plates are disposed at both ends in the lamination direction of the laminate. A stack load adjusting device for a fuel cell stack,
A pair of inclined members that are disposed inside at least one of the end plates and have inclined surfaces that are movable in the surface direction of the end plate and are inclined in opposite directions;
A movement having a right screw portion and a left screw portion and moving the pair of inclined members in a direction close to each other by rotation in one direction and moving the pair of inclined members in a direction away from each other by rotation in the other direction. Mechanism,
A pressing member that is disposed between the pair of inclined members and the laminated body and moves in the stacking direction of the laminated body under the moving action of the pair of inclined members;
A stack load adjusting device for a fuel cell stack, comprising: The laminated load adjusting apparatus according to claim 1, wherein the moving mechanism includes the right-hand thread portion fixed to one of the inclined members;
The left-hand thread portion fixed to the other inclined member;
The right screw portion and the left screw portion are screwed together and a nut portion that is rotated,
A stack load adjusting device for a fuel cell stack, comprising:   3. The stack load adjusting device according to claim 2, wherein the end plate is formed with an opening for rotating the nut portion from the outside. 2. The stacked load adjusting device according to claim 1, wherein in the moving mechanism, the right screw portion screwed to one of the inclined members and the left screw portion screwed to the other inclined member are integrally connected. Connecting rods,
An operating portion provided at an end of the connecting rod, and rotating the connecting rod
A stack load adjusting device for a fuel cell stack, comprising:   5. The stack of fuel cell stacks according to claim 1, wherein the pressing member has an inclined surface that abuts against each inclined surface of the pair of inclined members. 6. Load adjustment device.

Images