JP2002358988A - Hollow fiber module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve humidifying performance of a hollow fiber module by distributing the flow rate of the fluid flowing on the outside of the hollow fibers generally evenly to the housing, and further by improving the flow velocity. SOLUTION: In the hollow fiber module, a hollow fiber bunch 32 bundling plural hollow fibers 32a, 32a,... is housed in the housing 31 and a fluid (supply air A, exhaust air Ae) that has different moisture contents respectively is flown on the inside and outside of each hollow fiber 32a and moisture exchange is performed between these fluids (supply air A, exhaust air Ae). A spiral passage wall 50 centering on the longitudinal direction of the above hollow fiber bunch 32 is provided for the fluid (supply air A) that flows on the outside of the hollow fibers 32a, 32a,....

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hollow fiber membrane module, and more particularly, to a hollow fiber membrane module used as, for example, a humidifier for a fuel cell in an electric vehicle.

[0002]

2. Description of the Related Art In recent years, polymer electrolyte fuel cells have attracted attention as power sources for electric vehicles. A polymer electrolyte fuel cell (PEFC) has a solid polymer electrolyte membrane sandwiched between an anode electrode and a cathode electrode, and can generate electricity at room temperature. is there.

The solid polymer fuel cell uses a humidifier configured to exchange moisture in the exhaust air, which is a humid gas discharged from the fuel cell, with supply air supplied to the fuel cell. Have been. Examples of the humidification method of the humidification device include ultrasonic humidification, steam humidification, vaporization humidification, and nozzle injection. A humidification device is preferably a compact humidification device which consumes less power and has a small installation space. Therefore, a humidifier using a hollow fiber membrane is used as a humidifier used for a fuel cell.

As a humidifier using such a hollow fiber membrane, for example, a humidifier disclosed in JP-A-8-273687 is known. FIG. 6 shows a hollow fiber membrane module provided in such a humidifier. As shown in the figure, in the hollow fiber membrane module 80, a large number, for example, 5000, arranged along the longitudinal direction of the housing 81.
A hollow fiber membrane bundle 82 composed of about this number of water-permeable hollow fiber membranes is housed in a housing 81. An inlet 83 and an outlet 84 for a fluid flowing outside the hollow fiber membrane are formed near both ends of the side portion of the housing 81. At both ends of the housing 81, an inflow port 85 and an outflow port 86 for a fluid flowing through the inside of the hollow fiber membrane are formed.

[0005] Such a conventional hollow fiber membrane module 80
In order to efficiently exchange moisture between the fluid flowing inside and outside the hollow fiber membrane in the housing 81, the flow of the fluid flowing outside the hollow fiber membrane is increased, and It is desired to increase the residence time of the fluid flowing outside the container. However, in such a conventional hollow fiber membrane module 80, since the fluid simply flows from one end of the housing 81 to the other end, the flow rate cannot be increased. Also,
Since the flow path of the fluid flowing outside the hollow fiber membrane is also uniquely determined by the length of the housing 81, the residence time cannot be increased.

[0006] For this reason, the present applicant has filed Japanese Patent Application No. 2000-2.
No. 58868 proposes a hollow fiber membrane module in which a flow path of a fluid flowing outside the hollow fiber membrane is formed in a meandering shape by a plurality of baffles. FIG. 7 is an explanatory view showing the internal structure of such a hollow fiber membrane module. The hollow fiber membrane bundle 32 of the hollow fiber membrane module includes a plurality of hollow fiber membranes 32a in advance.
Are arranged in a plane, these hollow fiber membranes 32a are
A baffle for binding fluid that flows outside the hollow fiber membrane 32a when the hollow fiber membrane 32a bound by the knitting thread is wound up in a cylindrical shape. 41a to 41d are formed.

[0007]

As described above, if the fluid flowing outside the hollow fiber membrane is caused to flow to the downstream side while meandering by the baffle, the flow velocity and the flow rate of the fluid flowing outside the hollow fiber membrane are reduced. The path length increases, and the humidifying performance of the hollow fiber membrane module improves. However, the fluid flowing outside the hollow fiber membrane meanders through the shortest distance of the meandering flow path formed by the baffle, so that the fluid flowing outside the hollow fiber membrane with respect to the entire hollow fiber membrane bundle There is a problem that it is difficult to distribute the flow rate, and it is difficult to spread the flow over the entire hollow fiber membrane.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to distribute the flow rate of a fluid flowing outside a hollow fiber membrane uniformly in a housing, and to further increase the flow rate of the fluid. To improve the humidification performance.

[0009]

According to one aspect of the present invention, a hollow fiber membrane bundle formed by bundling a plurality of hollow fiber membranes is accommodated in a housing. In the hollow fiber membrane module in which fluids having different moisture contents flow through the inside and outside of the hollow fiber membrane to exchange moisture between these fluids, the length of the hollow fiber membrane bundle is longer than that of the fluid flowing outside the hollow fiber membrane. An object of the present invention is to provide a hollow fiber membrane module provided with a spiral flow path wall having a direction as an axis. As described above, when the spiral flow path wall is formed in the housing around the longitudinal direction of the hollow fiber membrane bundle, the flow rate of the fluid flowing outside the hollow fiber membrane is uniformly distributed throughout. Further, since the flow velocity and the flow path length of the fluid flowing outside the hollow fiber membrane are increased, the humidifying ability of the entire hollow fiber membrane module is greatly improved.

According to a second aspect of the present invention, in the first aspect, the flow path wall has a plurality of holes through which a part of a fluid flowing outside the hollow fiber membrane can pass. A thread membrane module is provided. That is, when the flow velocity of the fluid flowing outside the hollow fiber membrane increases due to the spiral flow path wall, the humidification capacity per unit time of the fluid flowing outside the hollow fiber membrane increases, but the flow velocity increases. In some cases, a drift near the flow path wall may occur in the flow path of the fluid flowing through the housing. When such a drift occurs, the flow rate on the side opposite to the drift side of the flow path decreases, and the humidification performance decreases accordingly. In view of the above, in the invention according to claim 2, a plurality of holes for passing a part of the fluid from the upstream side to the downstream side are provided in the flow channel wall, and one of the fluids flowing outside the hollow fiber membrane is provided. The part is passed from the upstream side to the downstream side by passing through a plurality of holes, and water is simultaneously recovered on the deviated side of the flow path and on both the deviated side and the opposite side.

Further, according to a third aspect of the present invention, in the first or second aspect of the invention, the flow path wall is formed of a hollow material formed of a binding material for binding the plurality of hollow fiber membranes. A thread membrane module is provided.
That is, to form the flow path wall in the housing,
For example, it is conceivable to form a plurality of holes for inserting a plurality of hollow fiber membranes into the partition plate and a plurality of holes for allowing fluid to pass from upstream to downstream, and to pass the hollow fiber membranes through the corresponding holes. Forming such a large number of holes and passing the hollow fiber membrane through each of the corresponding holes is a laborious and laborious operation. Therefore, according to the third aspect of the present invention, a plurality of hollow fiber membranes are bound with a binding material, thereby saving labor and time.

According to a fourth aspect of the present invention, there is provided the hollow fiber membrane module according to the third aspect, wherein the binding material is a knitting yarn that connects the hollow fiber membranes. When the binding material is a knitting yarn in this manner, a hollow fiber membrane bundle having the flow path wall integrally can be formed accurately and easily.

According to a fifth aspect of the present invention, in the third or fourth aspect of the present invention, the plurality of hollow fiber membranes arranged in a plane are separated from each other by forming a portion forming a flow path wall. An object of the present invention is to provide a hollow fiber membrane module in which the hollow fiber membranes are bound by a binding material and the hollow fiber membrane bundle is formed by winding up the hollow fiber membranes bound by the binding material. With this configuration, a hollow fiber membrane bundle having holes for allowing fluid to pass from the flow path wall and the upstream side to the downstream side can be formed easily and with a constant quality.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, a vehicle fuel cell system in which a hollow fiber membrane module according to the present invention is incorporated as a humidifier of a vehicle fuel cell system will be described with reference to FIGS.

FIG. 1 is an overall configuration diagram of a fuel cell system provided with a humidifier, and FIG. 2 is an explanatory diagram schematically showing the configuration of a fuel cell. Fuel cell system FCS shown in FIG.
Is a fuel cell 1, an air supply device AS, a hydrogen supply device HS
It is a power generation system composed of the above. As shown in FIG. 2, the fuel cell 1 is divided into a cathode electrode side (oxygen electrode side) and an anode electrode side (hydrogen electrode side) with an electrolyte membrane 1c interposed therebetween, and each side contains a platinum-based catalyst. An electrode is provided to form a cathode electrode 1b and an anode electrode 1d. As the electrolyte membrane 1c, a solid polymer membrane, for example, a perfluorosulfonic acid polymer (product name: Nafion), which is a proton exchange membrane, is used. When the membrane is saturated with water, it exhibits a low resistivity of 20 Ωcm or less at room temperature. Functions as a conductive electrolyte membrane. The cathode electrode 1
The catalyst contained in b is a catalyst that generates hydroxyl ions,
The catalyst contained in the anode electrode 1d is a catalyst that generates protons from hydrogen.

Outside the cathode electrode 1b, there is provided a cathode electrode side gas passage 1a through which supply air A as an oxidant gas flows through the cathode electrode 1b. Outside the anode electrode 1d, the anode electrode 1d Is provided with an anode-side gas passage 1e through which supply hydrogen H as a fuel gas flows. The inlet and outlet of the cathode-side gas passage 1a are connected to the air supply device AS, and the inlet and outlet of the anode-side gas passage 1e are connected to the hydrogen supply device HS. Although the configuration of the fuel cell 1 in FIG. 2 is schematically illustrated as one single cell, the actual fuel cell 1 is configured as a stacked body in which several hundred single cells are stacked. . Further, since the fuel cell 1 generates heat due to an electrochemical reaction during power generation, a cooling device (not shown) for cooling the fuel cell 1 is provided.

In the fuel cell 1, the supply air A flows through the cathode-side gas passage 1a, and the anode-side gas passage 1a
When the supply hydrogen H is supplied to e, hydrogen is ionized by the catalytic action at the anode electrode 1d to generate protons. The generated protons move through the electrolyte membrane 1c and reach the cathode electrode 1b. And the cathode electrode 1b
The protons that have arrived immediately react with oxygen in the supply air A in the presence of a catalyst to produce water. The supply air A containing the generated water and unused oxygen is discharged from the outlet on the cathode side of the fuel cell 1 as the discharge air Ae (the discharge air Ae contains a large amount of moisture). Also, the anode electrode 1d
When hydrogen ionizes, electrons e ^- are generated,
The generated electrons e ⁻ reach the cathode electrode 1b via an external load M such as a motor.

As shown in FIG. 1, the air supply device AS includes an air cleaner 3, a compressor 4, a pressure control valve 5, etc., in addition to the humidifier 2 according to the present embodiment. In the air supply device AS, the humidifier 2 is disposed upstream of the fuel cell 1 in the flow path of the supply air A in the fuel cell 1, and the compressor 4 is disposed upstream of the humidifier 2. Further, an air cleaner 3 is arranged upstream of the compressor 4. A humidifier 2 is disposed downstream of the fuel cell 1 in a flow path for discharging the exhaust air Ae from the fuel cell 1, and a pressure control valve 5 is disposed downstream of the humidifier 2.

The humidifier 2 humidifies the air supplied from the air cleaner 3 and supplies the humidified air to the fuel cell 1. The details will be described later.

The air cleaner 3 is composed of a filter (not shown) or the like, and filters air (supply air A) supplied to the cathode side of the fuel cell 1 to remove dust contained therein. The compressor 4 includes a positive displacement compressor such as a supercharger (not shown) and a motor for driving the compressor. The compressor 4 sends out supply air A used as an oxidizing gas in the fuel cell 1 and supplies it to the humidifier 2. The supply air A is sent out to the cathode side of the fuel cell 1 through the humidifier 2 by the output power of the compressor 4, and after passing through the fuel cell 1, becomes the exhaust air Ae and passes through the pressure control valve 5 to the humidifier 2. Will be sent to

The pressure control valve 5 comprises a butterfly valve (not shown) and an actuator such as a stepping motor for driving the butterfly valve. The pressure control valve 5 controls the pressure (discharge) of the supply air A discharged from the compressor 4 and the discharge air Ae discharged from the fuel cell 1. Is controlled by decreasing or increasing the opening of the pressure control valve 5.

On the other hand, as shown in FIG.
S comprises a hydrogen gas cylinder 11, a regulator 12, a hydrogen circulation pump 13, a three-way valve 14, and the like.

The hydrogen gas cylinder 11 stores the supply hydrogen H introduced to the anode side of the fuel cell 1. The supply hydrogen H to be stored is pure hydrogen, and its pressure is 15 to 35MPa.
aG (150 to 350 kg / cm ² G). In addition,
The hydrogen gas cylinder 11 contains a hydrogen storage alloy,
A hydrogen storage type that stores hydrogen at a pressure of about aG (10 kg / cm ² G) can also be used. If a hydrogen storage alloy type is used, hydrogen can be stored at a density equal to or higher than that of liquid hydrogen, so that an improvement in storage efficiency can be expected as compared with the case of storing as high-pressure gas.

The regulator 12 is a pressure control valve composed of a diaphragm, a pressure adjusting spring (not shown), and the like, and reducing the supply hydrogen H stored at a high pressure to a predetermined pressure so that it can be used at a constant pressure. This regulator 12 can reduce the pressure of the supply hydrogen H stored in the hydrogen gas cylinder 11 to near atmospheric pressure, when the reference pressure input to the diaphragm is atmospheric pressure.

The hydrogen circulating pump 13 is composed of an ejector (not shown) and the like, and utilizes the flow of the supply hydrogen H toward the anode of the fuel cell 1 to supply hydrogen after being used as fuel gas in the fuel cell 1. H, that is, fuel cell 1
The exhausted hydrogen He discharged from the anode electrode side and flowing through the three-way valve 14 is sucked and circulated. The circulation of the discharged hydrogen He is for improving the hydrogen use efficiency.

The fuel cell system F thus configured
In the CS, the supply air A passing through the cathode gas passage 1a of the fuel cell 1 via the humidifier 2 is supplied to the electrolyte membrane 1 of the fuel cell 1 while passing through the cathode gas passage 1a.
Wet c to saturation humidity. In addition, protons move from the anode electrode 1d in the electrolyte membrane 1c and the protons move to the cathode electrode 1b.
Is reached, the protons react with oxygen in the supply air A in the presence of the catalyst to produce water. The generated water is discharged from the fuel cell 1 together with the discharged air Ae and supplied to the humidifier 2 provided on the downstream side. In the humidifier 2, the inside of each hollow fiber membrane (described later) of the humidifier 2 is discharged air A
The supply air A passes outside, and the supply air A is humidified by moisture moving from the discharge air Ae. Therefore, in order to obtain a stable output of the fuel cell 1, it is effective to enhance the humidification performance of the hollow fiber membrane module.

Hereinafter, the structure of a hollow fiber membrane module and a humidifier using the hollow fiber membrane module according to an embodiment of the present invention will be described in detail. FIG. 3 shows the internal structure of the humidifier 2. As shown in FIG. 3A, the humidifier 2
It has a plurality of hollow fiber membrane modules 21 each having a substantially cylindrical shape, and has a box-shaped one-side distributor 22 and a second-side distributor 23, and has a rectangular parallelepiped shape as a whole. The plurality of hollow fiber membrane modules 21 (two in this embodiment) include one end-side distributor 22 and the other end-side distributor 2.
3 and are fixed at a predetermined interval in the horizontal direction. Further, the supply of the supply air A and the discharge of the wet exhaust air Ae are performed to the hollow fiber membrane modules 21 and 21 through the one end side distribution passage 22, and the other end side distributor 2
The exhaust of the supply air A humidified and the supply of the exhaust air Ae are carried out via 3.

The one end distributor 22 fixes the two hollow fiber membrane modules 21 and 21 together with the other end distributor 23 in a predetermined positional relationship. The one end distributor 22 has a discharge air outlet 22a and a supply air inlet 22b. As shown in FIG. 3B, the discharge air outlet 22a is connected to the discharge air outlet 37 of each hollow fiber membrane module 21, 21 by an internal flow path 22a 'disposed inside the one end distributor 22.
Is in communication with Further, the supply air inlet 22b communicates with supply air inlets 33, 33,... Formed on one end side of the hollow fiber membrane modules 21 and 21 by an internal flow passage 22b 'disposed inside the one end distributor 22. are doing.

On the other hand, the other end side distributor 23 has a discharge air inlet 23a and a supply air outlet 23b. The discharge air inlet 23a is connected to the hollow fiber membrane modules 21 and 2 by an internal flow path 23a 'disposed inside the other end side distributor 23.
One exhaust air inlet 38 is connected. In addition, the supply air outlet 23b is connected to the hollow fiber membrane modules 21 and 22 by an internal flow passage 23b 'disposed inside the other end distributor 23.
1, the supply air outlets 34, 34,
....

Next, the structure of the hollow fiber membrane module according to one embodiment of the present invention will be described. The hollow fiber membrane module 21 includes a housing 31 as shown in FIG.
have. The housing 31 accommodates a hollow fiber membrane bundle 32 formed by bundling water-permeable hollow fiber membranes 32a arranged along the longitudinal direction. The hollow fiber membrane bundle 32 is formed by bundling a large number, for example, 5000, of hollow fiber membranes 32a, 32a,..., As shown in FIG. The end is attached to the housing 31 by potted portions 35 and 36 which are potted.

In FIG. 4B, the hollow fiber membranes 32a, 32
a,... have many fine capillaries with a diameter of several nanometers (nanometers) reaching from the inside to the outside.
The vapor pressure drops and moisture condenses. The condensed water is sucked out by capillary action from a higher water content to a lower water content, and passes through the hollow fiber membranes 32a, 32a,. In addition,
The diameters of the hollow fiber membranes 32a, 32a,.
Or less.

The housing 31 of the hollow fiber membrane module 21
Is formed in a hollow cylindrical shape having both ends open, and a plurality (eight in the present embodiment) of supply air inlets 3 for introducing supply air A into the housing 31 at one end in the longitudinal direction.
Are formed to be spaced apart in the circumferential direction. A plurality of (eight in the present embodiment) supply air outlets 34 serving as outlets of the supply air A are formed on the other end side in the longitudinal direction of the housing 31 so as to be circumferentially separated. Have been.

The housing 31 is provided with a characteristic structure of the present invention. That is, in order to increase the flow velocity of the supply air A and increase the flow path length of the supply air A, a spiral flow path wall 50 having the longitudinal axis of the housing 31 as an axis is formed. And the inner surface of the housing 31, the spiral flow path (the hollow fiber membrane bundle 32
The flow path) 51 is defined by a surface that travels around the axis at a constant or indefinite progression with respect to the axis. The channel 5
The inlet 1 faces the supply air inlets 33, 33,..., And is adapted to introduce the supply air A into the spiral flow path 51, and the outlets are connected to the supply air outlets 34, 34,. The supply air A is discharged smoothly. Further, a plurality of holes 52, 5
Are provided so that a part of the supply air A (fluid flowing outside the hollow fiber membrane 32a) passes through the flow path wall 50 from the upstream side to the downstream side.

With this configuration, the flow path wall 50 is provided with the supply air A flowing outside the hollow fiber membranes 32a, 32a,.
Is uniformly distributed, the flow velocity of the supply air A is increased, and the flow path length of the supply air A in the housing 31 is increased. For this reason, the amount of water per unit time sucked out of the hollow fiber membranes 32a, 32a,... And the residence time of the supply air A flowing outside the hollow fiber membranes 32a, 32a,. And the humidifying ability of the hollow fiber membrane module 21 is improved as a whole.

When the flow velocity of the supply air A is increased by the spiraling of the flow path 51 by the flow path wall 50 and the drift of the supply air A occurs near the flow path wall 50 of the flow path 51, the supply air A Of the plurality of holes 5 provided in the channel wall 50.
2, water is drawn from the capillary of the hollow fiber membranes 32a, 32a,. For this reason, a decrease in the humidification capacity due to the drift is also prevented.

FIG. 5 shows another embodiment of the hollow fiber membrane bundle, in which 32 'is a hollow fiber membrane bundle, 50' is a channel wall, 5 '
Reference numeral 5 denotes a binding material. As shown in FIG. 5A, both ends of the hollow fiber membranes 32a, 32a,.
4 and are wound up around one hollow fiber membrane 32a on one side to form a cylindrical hollow fiber membrane bundle 32 '(FIG. 5 (b)). The hollow fiber membrane bundle 3
2 ′ is a state in which the hollow fiber membranes 32a, 32a are adjacent to each other by the binding members 55, 55,. The outside surfaces of the portions where the flow path walls 50 'are formed between the 32a, 32a are covered from outside with the binding materials 55, 55,.
For this reason, the hollow fiber membranes 32a, 32a,
, And the binding materials 55, 55,... Covering the outer surfaces of the lower hollow fiber membranes 32a, 32a,. The binding material 55, 55,... On the outer surface of the upper hollow fiber membranes 32a, 32a,.
When they come into contact with the outer surfaces of a,..., the flow path walls 50 ′, 50 ′,.

As the binding material 55, an adhesive, a knitting yarn (including a string), an adhesive and a knitting yarn are used. It is preferable to use a knitting yarn or a combination of a knitting yarn and an adhesive as the binding material 55, 55, 55, 55, 55, 55. Preferably, it is applied to the surface of each knitting yarn. When the plurality of hollow fiber membranes 32a are bound together by the binding members 55, 55,..., For example, holes for inserting the plurality of hollow fiber membranes 32a into the partition plate, or upstream to downstream A plurality of holes 52, 52,... For allowing the fluid to pass therethrough are formed, and time and labor are required in comparison with a case where the hollow fiber membrane 32a is passed through each of the holes for inserting the hollow fiber membrane 32a. Can be saved. Also,
When the knitting yarn is used for the binding materials 55, 55, compared to the case where the hollow fiber membranes 32a are bound with only the adhesive, the reworking during the binding becomes easier, and the flow path wall 50 (5
0 ', 50', ...) and a plurality of holes 52, 52, ... for allowing fluid to pass from upstream to downstream can be formed accurately and easily. In addition, a yarn (or a string) having elasticity can be used for the knitting yarns as the joining yarns 54, 54 and the binding materials 55, 55,. Of course, the material is not particularly limited as long as the physical properties and functions required for the flow path wall 50 (50 ', 50',...) Such as durability and reliability can be satisfied.

The binding members 55, 55,..., When wound up, prevent the adjacent hollow fiber membranes 32a from overlapping with each other and prevent the binding members 55 from being locally thickened.
Are shifted by the diameter of the wire (wire diameter). Various methods are conventionally known for knitting the knitting yarn. In the present embodiment, the hollow fiber membranes are wound at least once around the outer surface of the hollow fiber membranes 32a, 32a,. 32
The knitting method of connecting (binding) the a and 32a can be used.

FIG. 5 (b) shows a perspective view of the winding up of the hollow fiber membrane bundle 32 'in which the flow path walls 50', 50 ',... Are formed by the binding materials 55, 55,. 5B shows a state in which the cylindrical hollow fiber membrane bundle 32 ′ shown in FIG. 5B is accommodated in the housing 31, and the openings at both ends of the housing 31 are closed by the potting portions 35 and 36.

As shown in FIG. 5 (b), spiral channel walls 50 ', 50',... Are formed on the outer surfaces of the hollow fiber membranes 32a, 32a wound up in a cylindrical shape. The gaps S, S in the axial direction corresponding to the plurality of holes 52, 52,... Described in FIG. 4 are provided between the binding materials (knitting yarn or knitting yarn and adhesive) 55, 55 of the hollow fiber membranes 32a, 32a to be formed. , ... are formed.

Therefore, as shown in FIG. 5 (c), when the hollow fiber membrane 32 'is incorporated in the housing 31, the flow path walls 50', 50 ',... Are hollow hollow fiber membranes 32a, 32a,.
The flow rate of the supply air A flowing through the outside of the housing 31 is uniformly distributed over the entirety, and the flow rate of the supply air A and the supply air A
Channel length. Therefore, similarly to the hollow fiber membrane module 32, the amount of water per unit time sucked out of the hollow fiber membranes 32a, 32a,.
The residence time of the supply air A flowing outside the a, 32a,. Further, a part of the supply air A passes through the gap S between the adjacent binding members 55, 55 to the downstream flow path 51 ', and the passed supply air A is supplied to the hollow fiber membranes 32a, 32a.
a, because it can draw out water from each of the capillaries,
The spiral of the flow path walls 50 ′, 50 ′,.
Of the supply air A near the flow path wall 50 'of the flow path 51' as a result, it is possible to prevent the humidification capacity from being reduced due to the flow deviation.

In each of the above embodiments, when the supply air A is spirally swirled along the flow path wall 50 (50 ', 50',...) To increase the flow rate, the hollow fiber membrane 3
Since the turbulent flow when colliding with the outer surface of the 2 (32 ') enhances the diffusion action of moisture, the overall humidifying ability is improved. Also,
When the hollow fiber membranes 32a, 32a,... Connected in a blind shape are wound around one hollow fiber membrane 32a on one side as a winding center, the hollow fiber membranes 32 adjacent to each other in the circumferential direction are formed.
The gap in the circumferential direction between the a and 32a is narrower on the center side and gradually widens outward, and becomes maximum on the outer periphery of the hollow fiber membrane bundle 32. Therefore, the supply air A through this gap
Can be expected, and improvement of the humidification efficiency by the dispersion can be expected. Since a negative pressure due to the swirling flow of the supply air A acts on the circumferential gap between the hollow fiber membranes 32a adjacent to each other in the circumferential direction, a dry fluid (supply air A) is supplied inside the hollow fiber membrane 32a. Flow through and wet fluid outside
When the (discharged air Ae) flows, the improvement of the humidification efficiency of the entire hollow fiber membrane bundle 32 due to the negative pressure can be expected.

Further, when forming the cord-like hollow fiber membrane bundle 32 ', the interval between the adjacent hollow fiber membranes 32a, 32a can be changed. , The gap on the lower layer side, sequentially toward the lower layer side,
As coarse or vice versa, hollow fiber membranes 32a, 32a,
May be adjusted. Further, the flow path wall 50 (50 ', 5
0 ′,...), The hollow fiber membrane bundles 32 (32 ′) are arranged in a core in an injection mold, and each hollow fiber membrane bundle 3
It is also possible to integrally form the flow path wall 50 (50 ', 50',...) With 2 (32 ').

In each of the above-described embodiments, the supply air inlets 33, 33,... And the supply air outlets 34, 34,.
, Supply air A to supply air outlets 34, 34,.
In the above description, an inner pipe (not shown) is provided which extends into the housing 31. The supply air inlets 33, 33,... 31
Are arranged at the other end of the supply air outlets 34, 34,.
A plurality of hollow fiber membranes 32 are provided between the inner pipe and the housing 31.
a, 32a,... are formed, and an inner tube and a housing 3 of the hollow fiber membrane module are formed.
1, the hollow fiber membrane bundle 32 (32 ') may be filled. In this case, the supply air inlet 3 formed in the inner pipe
The supply air A flowing from the supply air outlets 34, 34,... To the flow path walls 50 (50 ', 50',...)
While turning along each axis, the centrifugal force spreads outward and the path near the axial center becomes the shortest flow path of the gas flow, and the entirety of the hollow fiber membrane bundle 32 is spread. As with the form, the humidification capacity is greatly improved. In the embodiment described above, the hollow fiber membrane 3
The description has been made in which the discharge air Ae flows through the inside of the hollow fiber membrane 2a and the supply air A flows through the outside of the hollow fiber membrane 32a.
The humidification ability can be improved also when the supply air A flows inside the hollow fiber membrane 32a and the exhaust air Ae flows outside the hollow fiber membrane 32a.

[0045]

As apparent from the above description, according to the present invention, the following excellent effects are exhibited. According to the first aspect of the present invention, a hollow fiber membrane bundle formed by bundling a plurality of hollow fiber membranes is accommodated in the housing, and fluids having different moisture contents are passed through the inside and outside of each hollow fiber membrane. In the hollow fiber membrane module that flows and exchanges water between these fluids, a spiral flow path wall is formed around the longitudinal direction of the hollow fiber membrane for the fluid flowing outside each hollow fiber membrane. Thus, the flow velocity and the flow path length of the fluid flowing outside the hollow fiber membrane can be increased. Therefore, the flow rate of the supply air flowing outside the hollow fiber membrane is uniformly distributed throughout,
Since the residence time of the fluid flowing outside the housing in the housing is increased, the humidification capacity is greatly improved.

According to a second aspect of the present invention, in the first aspect of the present invention, a plurality of holes through which a portion of the fluid passes from the upstream side to the downstream side are provided in the flow path wall, and the upstream side is passed through these holes. Since the fluid passes through the flow path on the downstream side from, the humidification capacity can be prevented from lowering when a drift occurs in the flow path toward the flow path wall.

According to a third aspect of the present invention, in the first or second aspect of the present invention, the flow path wall is formed of a binding material that binds the plurality of hollow fiber membranes. The labor and time required for forming the wall can be saved.
Further, the flow path wall can be easily formed without skill.

According to the fourth aspect of the present invention, since the binding material is a knitting yarn for connecting the hollow fiber membranes to each other, it is possible to accurately and easily form a hollow fiber membrane bundle having the flow path wall integrally. it can.

According to a fifth aspect of the present invention, for the plurality of hollow fiber membranes arranged in a plane, the portions forming the flow path walls are bound by the binding material and bound by the binding material. The hollow fiber membrane is wound up to form the hollow fiber membrane bundle. Therefore, for example, a hollow fiber membrane bundle having a large number of holes for allowing a fluid to pass from a flow path wall or an upstream side to a downstream side can be formed easily and with a constant quality.

[Brief description of the drawings]

FIG. 1 shows an embodiment of the present invention, and is an overall configuration diagram of a fuel cell system including a humidifier using a hollow fiber membrane module.

FIG. 2 shows one embodiment of the present invention, and is an explanatory diagram schematically showing a configuration of a fuel cell.

3 shows an embodiment of the present invention, FIG. 3 (a) is a perspective view showing an internal structure of a humidifier, and FIG. 3 (b) is a sectional view showing an internal structure of the humidifier.

4 shows an embodiment of the hollow fiber membrane module according to the present invention, FIG. 4 (a) is a perspective view showing the structure of the hollow fiber membrane module, and FIG. 4 (b) shows the structure of the hollow fiber membrane module. FIG. 5 is a sectional view taken along line bb of FIG.

5 shows an embodiment of a hollow fiber membrane according to one embodiment of the present invention, FIG. 5 (a) is a view showing a state before winding of a hollow fiber membrane bundle, and FIG. 5 (b) is a state after winding. FIG. 5C is a perspective view showing a state, and FIG.

FIG. 6 is a sectional view showing a conventional example and showing a hollow fiber membrane module.

FIG. 7 shows a conventional example and is an explanatory view showing an internal structure of a hollow fiber membrane module in which a meandering flow path is formed by a baffle.

[Explanation of symbols]

 Reference Signs List 21 hollow fiber membrane module 21 'hollow fiber membrane module 31 housing 32 hollow fiber membrane bundle 32' hollow fiber membrane bundle 32a hollow fiber membrane 50 flow wall 50 'flow wall 52 hole 55 binding member A supply air (fluid) Ae discharge Air (fluid) S Gap (hole)

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Mikihiro Suzuki 1-4-1 Chuo, Wako-shi, Saitama F-term in Honda R & D Co., Ltd. (Reference) 4D006 GA41 HA02 JA24A MA01 PB65 PC80 5H026 AA06 CX04 5H027 AA06

Claims (5)

[Claims] 1. A hollow fiber membrane bundle formed by bundling a plurality of hollow fiber membranes is accommodated in a housing, and fluids having different moisture contents are passed through the inside and outside of each hollow fiber membrane, respectively. In a hollow fiber membrane module for performing moisture exchange, a hollow flow path wall provided around a longitudinal direction of the hollow fiber membrane bundle with respect to a fluid flowing outside the hollow fiber membrane is provided. Membrane module. 2. The hollow fiber membrane module according to claim 1, wherein the flow path wall has a plurality of holes through which a part of a fluid flowing outside the hollow fiber membrane can pass. 3. The hollow fiber membrane module according to claim 1, wherein the flow path wall is formed of a binding material that binds the plurality of hollow fiber membranes. 4. The hollow fiber membrane module according to claim 3, wherein the binding material is a knitting yarn that connects the hollow fiber membranes. 5. A method for a plurality of hollow fiber membranes arranged in a plane,
The part forming the flow path wall is bound by the binding material, and the hollow fiber membrane bundled by the binding material is wound up to form the hollow fiber membrane bundle. 3. The hollow fiber membrane module according to item 1.