JPH06134210A - Deaeration film module - Google Patents

Abstract

PURPOSE:To improve the treated water amount of deaerated water and make a device compact by forming bypass flow paths inside a plurality of deareation film elements. CONSTITUTION:A part of raw water fed from a raw water port 1 is fed into a first deaeration element 3 and deaerated. The inside of the element is vacuumized by a vacuum line 10 and dissolved gas in the raw water is removed to the vacuumized side through a film. The remaining raw water is fed to a second deaeration element 4 through a second deaeration film element raw water flow bypass 6 formed inside the first deaeration element 3, and deaerated in the second deaeration film element 4. The deaerated water in a deaeration element 3 is fed to a deaeration film water outlet 2 through the first deaeration element deaerated water flow bypass 8 formed inside the second deaeration film element 4, and discharged out of the deaerated water outlet 2 together with deaerated water in the second deaeration film element 4. Although the module size is almost same as those heretofore available, the treated water amount of the deaerated air is increased to a large extent. It is preferable to make the element of spiral type or of hollow yarn type.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a degassing membrane module which uses a hydrophobic gas permeable membrane to remove the dissolved gas in the raw water by flowing the raw water into one of the membranes and depressurizing the other. More specifically, the present invention relates to a spiral type or hollow fiber type degassing membrane module.

[0002]

2. Description of the Related Art Recently, a so-called degassing process for removing gases such as oxygen, nitrogen and carbon dioxide dissolved in water using a hydrophobic gas separation membrane has recently been put into practical use. (Actual exploitation Sho 57-35795, Japanese Unexamined Patent Publication No. 62-273095) In this method, raw water is applied to the front or back surface of a membrane made of silicone or the like, which has a gas permeation function and does not allow water to permeate. By flowing and reducing the pressure on the opposite surface, only the dissolved gas in the raw water is removed through the membrane and degassed. By removing the dissolved gas in the water, it is possible to prevent, for example, corrosion of the inner surface of the liquid contacting the pipe due to dissolved oxygen in the water circulation line and deterioration of the water quality of the ultrapure water due to carbon dioxide. With this method, there are no problems such as chemical residual components found in the conventional chemical addition method, the apparatus is simpler than the vacuum degassing method, etc., and the operating cost is reduced. There is.

Reverse osmosis membranes which are generally used at present,
The size of the ultrafiltration membrane module is mainly about 1 m, and other half sizes such as 50 cm long are in circulation. Therefore, in determining the length of the degassing membrane module, there are many cases in which the module of the same size is adopted from the viewpoints of device design, production and distribution. Therefore, when it is necessary to increase the amount of degassing treatment in a module with a length of 1 m or 0.5 m, generally,
The following measures can be taken in order to reduce the dissolved gas concentration to a target level.

1. Make a high vacuum on the permeate side.

2. To increase the residence time on the membrane surface, slow the flow rate of raw water.

B-. Lengthen the module.

3. Increase the flow velocity to reduce the gas permeation resistance due to the concentration film on the membrane surface.

B-1. In case of flat film type and spiral type: reduce the flow channel width and thickness.

A channel material for promoting turbulence is used.

B-2. In case of hollow fiber type: The hollow fiber diameter is reduced.

[0011]

However, these factors are complicatedly related, and the contents of 2,3-a are contradictory, and it is necessary to take one or three measures. Not a thing. Although it is possible to increase the amount of degassing treatment, there are negative factors such as pressure loss, increase in required power due to vacuum degree, increase in required pressure resistance of the membrane and module, etc. However, it was a very big problem in improving deaeration ability.

[0012]

DISCLOSURE OF THE INVENTION An object of the present invention is to use a hydrophobic gas permeable membrane, and to degas the raw water by flowing the raw water through one side while depressurizing the other side. In the membrane module, while taking a form in which a plurality of degassing membrane elements are connected in series, by providing the raw water and degassing water bypass channels inside each element,
This is basically achieved by the degassing membrane module in which at least a part of the raw water passes through the degassing membrane element in an amount less than the number of the plurality of series.

FIG. 1 is a schematic view of a typical example of the degassing membrane module of the present invention, and FIG. 2 is a sectional view showing its structure. As shown in FIG. 2, part of the raw water supplied from the raw water supply port 1 is supplied to the first degassing membrane element 3 and degassed. That is, the inside of the element is depressurized by the vacuum line 10, and the dissolved gas in the raw water is removed to the depressurized side through the membrane. However, the position and number of the vacuum lines 10 shown here are not particularly limited, and it is sufficient if there is no element, but the pressure can be sufficiently reduced. On the other hand, the remaining raw water is the second water provided inside the first degassing membrane element 3.
Liquid is sent to the second degassing membrane element through the raw water bypass channel 6 for the degassing membrane element, and degassed by the second degassing membrane element 4. The degassed water in the first degassing membrane element 3 is sent to the degassing water outlet 2 through the degassing water bypass passage 8 for the first degassing membrane element provided inside the second degassing membrane element 4, 2 It is taken out from the degassed water outlet 2 together with the degassed water of the degassing membrane element 4. This module is particularly suitable when the element is the hollow fiber membrane type degassing membrane element shown in FIG.

With this module form, it is possible to shorten the raw water flow path while maintaining compatibility with the conventional module having a length of 50 cm to 1 m.
It is possible to prevent an increase in pressure loss, which is a big problem. That is, a dramatic amount of degassed water can be obtained by simply using the existing degassing membrane device and changing the module.

As a result of earnest studies for improving the degassing performance, we have found that the method of increasing the degree of vacuum described in the above item 1 is effective for reducing the dissolved gas concentration of degassed water. For the purpose of obtaining degassed water, the effect of increasing the amount of treated water is small, that is, an increase in the amount of treated water directly leads to an increase in pressure loss.Therefore, it is not possible to improve the degree of vacuum as a measure to improve the amount of degassed treated water. We have found that it is not very effective.

When the measures 2 and 3 are taken,
Any of these causes an increase in pressure loss in the degassing membrane module, which is a problem in improving degassing performance. Therefore, we investigated the relationship between these degassing performance and pressure loss, and as a result, when the degassed water-soluble gas concentration and the required power were defined, the amount of degassed treated water and the treated water flow path diameter (in the case of the spiral type, It was found that the equivalent diameter) and module length are uniquely determined. Therefore, an optimization study was conducted under various detailed conditions.As the effective length of the membrane was increased to several cm, the treated water volume increased, but the treated water volume did not change even if the membrane length was further increased. There was found. In other words, it became clear that the optimum module length is much shorter than 50 cm or 1 m, which is currently the mainstream. In particular, when considering module volume, for example, modules with 25 cm length and 50 cm length double the module volume, but the amount of treated water increases by only a few percent, and a module with 50 cm length has 2 modules with 25 cm length. Since the main unit can be installed, the amount of treated water can be almost doubled by using the 25 cm long module. However, connecting and arranging short modules in parallel has problems that existing degassing membrane devices cannot be used, piping becomes complicated, and replacement of degassing membrane modules at the end of their life is troublesome. Therefore, the module size is almost the same as the conventional one,
In addition, the inventors have invented a degassing membrane module in which elements are connected in parallel in the module.

In this case, it is most ideal that all raw water passes through the degassing membrane element only once.
It is not limited to this. That is, as needed, when a part of the raw water passes through the degassing membrane element only once and the other part passes through the degassing membrane element twice or more, or when three or more dewatering elements occur. The effect of the present invention also when the gas membrane elements are serially connected and the raw water passes through two or more times less than the number of degassing membrane elements in series, or when the above cases are arbitrarily combined. Can be acceptable as long as it is sufficiently obtained. In these cases, 70% or more of the raw water may pass through each degassing membrane element only once, or may pass through 2/3 or less of the number of degassing membrane elements in series. This is the preferred embodiment.

The effective length of the degassing membrane element in the present invention is not particularly limited. However, as described above, the shorter the module length is, the higher the efficiency is. On the other hand, even if the module length is shortened, the end length required for bonding does not change so much, and as a result, the effective film area with respect to the used film area is reduced. It may lead to up. Also,
When the length is shortened, the inner diameter of the hollow fiber suitable for the length is also reduced, which causes problems such as handling of the hollow fiber and spinnability of the hollow fiber. In view of the above, as a result of diligent examination, in the case of the hollow fiber type, the effective length of the membrane is 5 cm or more and 50 cm or less, and the hollow fiber inner diameter is 50 μm or more correspondingly.
It has been found that it is desirable that the thickness is 300 μm or less. In particular, the highest efficiency can be obtained when the effective length is 10 cm or more and 20 cm or less and the hollow fiber inner diameter is 100 μm or more and 150 μm or less. However, for the purpose of preventing the development of concentration film and increasing the membrane area, the flow path condition is complicated, such as the shape of the hollow fiber is not cylindrical, the surface condition is special, and the turbulence promoting material is present. In the case of flat membrane type and spiral type, the optimum conditions are very different, and the required degassing level,
Since it also changes depending on the water temperature, the degree of vacuum, etc., if compatibility with existing modules is not considered, it is not necessary to set the length to 0.5 m or 1 m, and there is no limit to the length.

The position of the vacuum line installation port 10 of the module according to the present invention is not particularly limited as long as each flow path can be secured, but in the case of the type as shown in FIG. 1, as shown in FIG. , Bypass channels 6, 7,
8 and 9, which deviate from the central axis, that is, θ is 0 ^. ,
Or 180 ^. It is desirable to make an angle other than. Thereby, the shape of each degassing membrane element can be made the same. In addition to the representative example shown in FIG. 1, it is particularly suitable for the spiral type degassing membrane element of FIG. 13, for example, a porous center connected to a vacuum line installation port 10 as shown in FIGS. 4 and 5. The tube 11 may be arranged at the center of the degassing membrane elements 3 and 4. Further, the raw water and the degassed water bypass passage provided in the degassing membrane module are not particularly limited, and the raw water to be supplied is branched into a plurality of parts to be sent to each degassing membrane element. It is sufficient that the degassed water is collected, and for example, as shown in FIGS. 6 and 7, it may have bypass passages 6 and 8 on the outer surface of the element. At this time, 2
The positional relationship between the two bypass channels is not particularly limited, but for convenience of module installation, as shown in the upper sectional view of FIG.
It is preferable to provide two bypasses at the same position. Further, as shown in FIG. 9, the sealing portion 18 and the bypass flow path 6,
It is also possible to use a casing with 8.

The number of membrane elements connected in the module of the present invention is not particularly limited. Considering the ease of manufacturing the module, the cost, the effect on the performance, etc., it is generally appropriate to connect two degassing membrane elements, but as shown in FIG. It is also possible to connect the above degassing membrane elements. This is particularly effective when the length of the degassing membrane element required for performance is short.

The degassing membrane element used in the present invention is of a flat membrane type, a hollow fiber membrane type, a spiral type or the like, and its type is not particularly limited, but it has a structure in which the permeate side is hard to be condensed or is easily removed even if it is condensed. Some are more preferred. Particularly preferred are spiral type elements or hollow fiber membrane type elements. The spiral element has, for example, a basic structure in which an envelope-shaped membrane as shown in FIG. 11 is wrapped around a porous central tube together with a net-shaped channel material, and is widely known as a membrane separation element. There is something. The hollow fiber membrane element is not particularly limited in type, but it is desirable that the hollow fiber membrane element has a structure in which the supply water hardly causes a nonuniform flow and the gas permeation side can sufficiently reduce the pressure. For example,
A hollow fiber membrane 24 as shown in FIG. 12 generally has a shape in which both ends are fixed by adhesion. In this case, raw water passes through the inside of the hollow fiber membrane 24, and the outside is vacuumed, The mainstream method is to remove the dissolved gas in the raw water by removing the dissolved gas in the raw water. Further, the degassing membrane module according to the present invention, if necessary,
It is also possible to load degassing membrane elements with different types and membrane characteristics into one module. For example, when three kinds of hollow fiber membrane type degassing membrane elements having different hollow fiber diameters are used as a module of two-unit connection, a total of 6 different degassing characteristics are obtained.
Since various types of modules can be obtained, it is easy to create a variety of modules that meet the requirements.

By the way, the membrane used in the spiral wound type membrane module is generally an asymmetric membrane or a composite membrane, but the composite membrane is particularly common. The membrane structure called a composite membrane has a flat membrane shape and is composed of a porous support layer and a polymer homogeneous layer or a dense layer provided thereon. The porous support layer has a role of preventing mechanical deformation of the polymer homogeneous layer as a support layer of the polymer homogeneous layer that most affects the performance of the hydrophobic gas permeable membrane, and has sufficient gas permeability. It is necessary to have In order to further increase the strength of the support layer, it is preferable to have a reinforcing layer such as a polyester woven fabric or a non-woven fabric under the support layer. Examples of the preferred polymer for the porous support layer include polyester, polyamide, polyolefin, polyacrylate, polymethacrylate, polytetrafluoroethylene, polysulfone, and polycarbonate. Particularly preferred is polysulfone or polypropylene. .

Specific examples of the polymer homogeneous layer formed on the porous support layer include polyorganosiloxane, cross-linking polyorganosiloxane, polyorganosiloxane /
Polycarbonate copolymer, polyorganosiloxane /
Polyphenylene copolymer, polyorganosiloxane / polystyrene copolymer, polytrimethylsilylpropyne,
Poly 4-methyl pentene, etc. are mentioned. Among these, crosslinked polydimethylsiloxane is most preferable because it has high mechanical strength and a large oxygen transmission coefficient. This cross-linked polydimethylsiloxane differs in the performance of the thin film obtained depending on the production method, and is disclosed in JP-A-60-257803 and JP-A-62-62803.
-216624, according to the production method described in JP-A-62-216623, the crosslinked polydimethylsiloxane thin film obtained is preferable because it has excellent gas permeability and few pinholes.
Further, in the composite film, a polymer homogeneous film whose main component is the above-mentioned cross-linked polydimethylsiloxane is called a cross-linked silicone-based composite film. The cross-linked silicone-based composite film is a film characterized by forming a cross-linked silicone-based thin film on the surface of the base material film, and the surface state is so dense that it is generally called a non-porous film. There are many. For this reason, in addition to the hydrophobic property of silicone itself, it has the excellent property of being able to suppress the adsorption of dirt components. It is also possible to further improve the hydrophobicity by forming a fluororesin-based ultra-thin film on the surface of the silicone film.

The membrane used in the hollow fiber membrane module is only required to be hydrophobic and in the form of a hollow fiber, and polyethylene, polypropylene, polytetrafluoroethylene, polyvinylidene fluoride, poly (4 methylpentene), etc. are preferable, but especially Preferred is a polymer composed of polyvinylidene fluoride or 4-methylpentene.
Further, in order to further increase the hydrophobicity, it is possible to form a silicone-based or fluororesin-based thin film on one or both of the inner and outer surfaces of the hollow fiber.

[0025]

The present invention will be described more specifically with reference to the following examples. However, the present invention is not limited to this.

Example 1 A degassing membrane module of the type shown in FIG. 1, which is an example of the present invention, was produced. This module has an inner diameter of 100 μm and an outer diameter of 12
It is composed of two degassing membrane elements with a diameter of 10 cm and a length of 25 cm, which are loaded with 200,000 polyvinylidene fluoride hollow fiber membranes of 5 μm. Use this module to connect the vacuum line
35 Torr, as raw water, water temperature 25 ℃, dissolved oxygen concentration 8.0p
When pure water of pm was flown under the condition that the pressure loss was 0.5 kgf / cm2, the treated water amount was about 15 liters / minute, and the dissolved oxygen concentration at the module outlet was 0.30 ppm.

Comparative Example 1 A conventional degassing membrane module as shown in FIG. 13 was produced. This module has a diameter of 65000 polyvinylidene fluoride hollow fiber membranes with an inner diameter of 180 μm and an outer diameter of 220 μm.
It is a module with a length of 10 cm and a length of 55 cm. When a deaeration test was conducted using this module under the same conditions as in the examples, the amount of treated water was about 9 liters / minute, and the dissolved oxygen concentration at the module outlet was 0.33 ppm.

[0028]

EFFECTS OF THE INVENTION In the present invention, a hydrophobic gas permeable membrane is used. In a degassing membrane module for removing dissolved gas in raw water by flowing raw water through one of the membranes and depressurizing the other, A degassing membrane in which the raw water passes through each degassing membrane element only once by providing a raw water and degassing water bypass flow path inside each element while taking a form in which a plurality of membrane elements are connected in series. The module greatly reduced the amount of degassed water treated, and made it possible to downsize the equipment.

[Brief description of drawings]

FIG. 1 is an example of a degassing membrane module according to the present invention.

FIG. 2 is a cross-sectional view of an example of a degassing membrane module according to the present invention.

FIG. 3 is a cross-sectional view of an example of a degassing membrane element according to the present invention.

FIG. 4 is an example of a degassing membrane module having a central tube for pressure reduction according to the present invention.

FIG. 5 is a cross-sectional view of an example of a degassing membrane module having a central tube for pressure reduction according to the present invention.

FIG. 6 is an example of a degassing membrane module having a flow path on the outer surface according to the present invention.

FIG. 7 is a cross-sectional view of an example of a degassing membrane module having a flow path on the outer surface according to the present invention.

FIG. 8 is a top cross-sectional view of another example of the degassing membrane module having a flow path on the outer surface according to the present invention.

FIG. 9 is a cross-sectional view of an example of a case-loading type degassing membrane module according to the present invention.

FIG. 10 is a cross-sectional view of an example of a multi-linkage type degassing membrane module according to the present invention.

FIG. 11 is an example of a typical spiral type degassing membrane element.

FIG. 12 is a cross-sectional view of an example of a typical hollow fiber membrane type degassing membrane element.

FIG. 13 is a cross-sectional view of an example of a conventional degassing membrane module.

[Explanation of symbols]

 1: Raw water supply port 2: Degassed water outlet 3: First degassing membrane element 4: Second degassing membrane element 5: Third degassing membrane element 6: Raw water bypass channel for second degassing membrane element 7: Raw water bypass flow passage for third degassing membrane element 8: Degassing water bypass passage for first degassing membrane element 9: Degassing water bypass passage for second degassing membrane element 10: Arrangement port of vacuum line 11 : Porous central tube 12: Cap 13: Porous central tube connecting part 14: Module end plate 15: Module case 16: Element connecting part 17: Element cap 18: Sealing part 19: Degassing film 20: Supply side flow path Material 21: Channel material on permeate side 22: Raw water supply 23: Permeate gas 24: Hollow fiber membrane 25: Adhesive part

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification number Office reference number FI technical display location B01D 71/34 9153-4D 71/70 500 9153-4D C02F 1/20 ZAB A

Claims (5)

[Claims] 1. A degassing membrane module for removing a dissolved gas in raw water by using a hydrophobic gas permeable membrane and flowing the raw water through one side of the membrane while depressurizing the other side. By providing a plurality of raw water and degassed water bypass channels inside each element while taking a form in which they are connected in series, at least a part of the raw water passes through the degassing membrane element in an amount less than the number in series. Degassed membrane module. 2. The degassing membrane module according to claim 1, wherein the whole raw water is passed through the degassing membrane element only once. 3. The degassing membrane module according to claim 1, wherein the degassing membrane element is a spiral type element, and the membrane material constituting the module is a silicone-based hydrophobic gas permeable membrane. 4. The degassing membrane according to claim 1, wherein the degassing membrane element is a hollow fiber type element, and the hollow fiber membrane material is a polymer made of polyvinylidene fluoride or 4-methylpentene. module. 5. The effective length of the degassing membrane element is 5 cm or more and 50 cm.
The degassing membrane module according to claim 4, wherein the hollow fiber inner diameter is 50 μm or more and 300 μm or less.