JPH044817Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) The dialysis device of the present invention is a laboratory-sized dialysis device used as a diffusion dialysis device or an electrodialysis device, especially for desalting and purifying various samples in laboratories. Regarding.

(Prior Art) In a known dialysis device, ion exchange membranes or semipermeable membranes are stacked alternately with gaskets, and the entire membrane is sandwiched between two press plates, and the press plates are tightened with bolts, nuts, or a center press. Therefore, a common method is to tighten the ion exchange membrane or semipermeable membrane and gasket to prevent liquid leakage.

In industrial equipment, a hydraulic press or the like is used to tighten with sufficient pressure. on the other hand,
In lab-scale devices, the method used is to use a wrench or screwdriver to tighten as tightly as possible. Furthermore, some devices do not use a gasket, but instead employ a method of fitting an O-ring into the dialysis cell to prevent liquid leakage.

(Problems that the invention aims to solve) In lab-scale devices, dialysis cells are tightened using tools such as spanners and screwdrivers, but handling is cumbersome, and the tightening force and uniformity of tightening are not uniform. This is not preferable because individual differences tend to occur.

Although the center press method requires less handling than the bolt and nut method,
Even small devices need to be tightened quite strongly, and it is dangerous if the device is not secured during tightening, so it is rarely used in laboratory-sized devices in practice.

In addition, in the method of fitting an O-ring into a dialysis cell, although it is possible to prevent liquid leakage with a relatively weak tightening force, in most cases only one ion exchange membrane or semipermeable membrane is inserted. When a plurality of ion exchange membranes or semipermeable membranes are stacked and sandwiched between gaskets, the tightening force becomes weak, which is not preferable. Further, there are disadvantages in that the number of required parts increases, and in the case where the shape of the liquid-contacted part is complicated, machining and handling are troublesome.

(Purpose of the invention) This invention is a dialysis device that can easily and reliably prevent fluid leakage without using tools such as spanners or screwdrivers when tightening, and is easy to work with, especially a small dialysis device of laboratory size. The purpose is to provide.

(Structure of the invention) The gist of the invention is to provide a membrane cartridge that integrates an ion exchange membrane or semipermeable membrane and a gasket.
A dialysis device mounted on a dialysis cell, characterized in that at least one of the surfaces of the dialysis cell in contact with a membrane cartridge is provided with a convex portion that is smaller in area than that surface and has a liquid contact portion. .

The ion exchange membrane, semipermeable membrane, and gasket used in the present invention are not particularly limited, and known ones can be used. Examples of ion exchange membranes or semipermeable membranes include hydrocarbon cation exchange membranes and anion exchange membranes, fluorine ion exchange membranes, amphoteric ion exchange membranes,
There are mosaic charged membranes, regenerated cellulose membranes, polyvinyl alcohol membranes, etc. The gasket can be made of synthetic rubber such as styrene-butadiene rubber, natural rubber, polyethylene, EVA (ethylene vinyl acetate), EEA (ethylene ethyl acrylate), soft PVC, polypropylene, silicone, or other synthetic resins. In particular, in order to integrate the membrane and gasket, it is desirable to use a heat-sealable synthetic resin. In order to form a membrane cartridge by integrating the membrane and gasket, a method of integrating them using a welding agent may be used, but a thermal welding method is more preferable in terms of chemical resistance and simplification of the manufacturing process.

The membrane cartridge to which the present invention is applied may be one in which gaskets are attached to both or one side of a single membrane, but in particular two or more membranes are stacked alternately with three or more gaskets to form a single unit. It is effective in cases where This is because the shape of the wetted part of the dialysis cell is often complicated due to the passage of fluid between the membranes, and O-rings require complicated machining and an increased number of parts, making handling difficult. .
Furthermore, as the number of membranes increases from two, it is more likely that there will be parts where the convex portions provided on the dialysis cell are insufficiently pressed, so it is desirable that the number of membranes be small. In particular, it is desirable to limit the number to 20 or less.

A dialysis cell equipped with these integrated membrane cartridges must be provided with a convex portion having a liquid contact portion and having a smaller area than that surface on at least one surface that contacts the membrane cartridge. By providing the convex portion, the area under pressure can be reduced compared to known devices, so even if tightening is performed with the same total pressure, it is possible to tighten locally with stronger pressure. Even lab-sized dialysis cells, which have a small clamping area, are surprisingly effective. The protrusions may be provided on both sides of the dialysis cell that are in contact with the membrane cartridge, but if the number of membranes is small, a sufficient effect can be achieved even if the protrusions are provided on only one side. For the purpose of preventing liquid leakage, the convex portion must be provided so as to have a liquid contact area. In this case, it is preferable that the convex portion be provided so as to surround the periphery of the liquid-contacted portion. In addition, if there are multiple parts in contact with liquid, it is not necessary to provide the protrusions so as to surround the entire part, but only around the parts that are likely to leak, such as areas that are subject to particularly strong pressure. It's okay. In particular, if a band-shaped convex portion is provided around the liquid-contacted part, the area to which pressure is applied is reduced and the tightening is performed uniformly around the liquid-contacted part, so that liquid leakage can be effectively prevented. The protrusions can be provided by attaching a thin plate of plastic or metal in the shape of a protrusion to the inner surface of the dialysis cell, or by scraping off the periphery of the protrusion.

Although the dialysis cell of the present invention is effective in general membrane separation devices such as diffusion dialysis devices and ultrafiltration devices, it is particularly effective in electrodialysis devices having at least two membranes. This is because O-rings tend to be insufficiently tightened due to the large number of membranes, and the parts in contact with the liquid tend to be complicated.

Particularly in small electrodialysis machines with an effective current-carrying area of 100 ^cm2 or less, it is desirable to integrate the ion exchange membrane and gasket in order to improve handling. It is preferable to adopt a simple center press method or thumbscrew method.

Although the membrane cartridge and dialysis cell may be attached and tightened using bolts and nuts, the dialysis device of the present invention can effectively prevent fluid leakage even at a relatively low total pressure. Tightening with screws alone is sufficient.
Furthermore, the center press method is more desirable because it is easier to handle.

Next, the dialysis apparatus of the present invention will be explained with reference to the drawings. FIG. 1 shows an example of an electrodialysis apparatus consisting of one membrane cartridge 3 and two dialysis cells 2, 2' sandwiching this membrane cartridge. The membrane cartridge integrates two ion exchange membranes 4 and three gaskets 5. A convex portion 6 is provided on the surface of the dialysis cell 2 that comes into contact with the membrane cartridge. The convex portion 6 has a liquid supply port 7 and an electrode 8. FIG. 2 shows another example, in which the convex portion 6 is provided in a band shape around the liquid contact portion. FIG. 3 shows a conventional dialysis apparatus, in which both surfaces of the dialysis cells 2, 2' in contact with the membrane cartridge 3 are flat and do not have any protrusions. Figures 4 and 5 are
The method of mounting and tightening the dialysis cells 2, 2' and the membrane cartridge 3 in the dialysis apparatus 1 of the present invention is shown. 4 shows a method using a center press 9, and FIG. 5 shows a method using a thumb screw 10. FIG. 6 shows a conventional type of dialysis apparatus 1, in which a membrane cartridge 3 and dialysis cells 2, 2' are attached by press plates 11 and bolts 12.

(Example) The present invention will be described below with reference to Examples. Note that the numerical values used in the examples were determined as follows.

(1) Total pressure; W (Kg) W = Torque (Kg cm) x 2 ÷ Thread diameter (cm) ÷ Tan (θ + 0.1) θ = arctan [Thread pitch (cm) ÷ π ÷ Thread diameter (cm)] (2) Pressure strength: F (Kg/cm ² ) F=W/SS S: Contact area between dialysis cell and membrane cartridge (cm ² ) (3) Gasket hardness Spring type hardness listed in JIS K6301 Based on test method (Type A).

(Example 1) An electrodialysis apparatus having a dialysis cell structure provided with a convex portion as shown in FIG. 1 was used. The dialysis cell is made of acrylic resin, and the contact area of the membrane cartridge is approximately 16 ^cm2 .
The convex portion was provided by cutting off the periphery of the acrylic resin. The effective current-carrying area of the dialysis cell is 10cm ² . The membrane cartridge used was one in which one cation exchange membrane and one anion exchange membrane were stacked alternately with three EEA resin gaskets, and the gaskets were thermally welded to integrate them. Gasket hardness is 75
The thickness was 0.5 mm. The dialysis cell was tightened using the center press method. Torque is 25
The total tightening pressure is 400Kg even in weak conditions of Kg/cm.
The strength of the pressure was 26Kg/cm ² . 20c.c./ with pump
A liquid leakage test was conducted by feeding the liquid at a flow rate of 100 mL, but no liquid leakage occurred at all.

(Example 2) An electrodialysis device was used in which the convex portion shown in FIG. 2 was provided in a band shape with a width of 4 mm around the liquid contact portion. A liquid leakage test was conducted under all other conditions as in Example 1. The contact area between the dialysis cell and membrane cartridge is 12
cm ² , and no liquid leakage occurred even at a torque of 20 kg/cm.

(Comparative Example 1) A test was conducted using a conventional type electrodialysis device in which the dialysis cell shown in FIG. 3 is not provided with a convex portion. The area of the dialysis cell in contact with the membrane cartridge was approximately 27 cm ² .
The same membrane cartridge as in Example 1 was used, and the torque was increased to 40 kg·cm. The total pressure is
Although the size is 640Kg, the pressure strength is 24Kg/cm ²
It was nothing more than When a liquid leakage test was conducted by feeding the liquid in the same manner as in Example 1, a liquid leakage of 0.4 cc/h or more occurred.

(Effect of the invention) According to the invention, liquid leakage of the dialysis cell can be effectively prevented. Particularly in dialysis cells that use a membrane cartridge that integrates a membrane and a cartridge, fluid leakage can be prevented with a relatively low total pressure, so there is no need to use tools such as spanners or screwdrivers, and a thumbscrew is sufficient. Tightening pressure can be obtained. There is no danger when tightening, and there is no need to particularly fix the device when tightening. Therefore, a center press method that is easy to handle can be adopted. Further, parts such as O-rings are not required, and machining is easy.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram showing one example of the dialysis apparatus of the present invention, and FIG. 2 is an explanatory diagram showing another example of the dialysis apparatus of the present invention. FIG. 3 is an explanatory diagram of a conventional dialysis device.
FIG. 4 is an explanatory diagram of the dialysis apparatus of the present invention which employs a center press method. FIG. 5 is an explanatory diagram of the dialysis apparatus of the present invention that employs a thumbscrew tightening method. FIG. 6 is an explanatory diagram of a conventional type dialysis apparatus using a press plate. 1... Dialysis device, 2, 2'... Dialysis cell, 3...
...Membrane cartridge, 4...Ion exchange membrane, 5...
Gasket, 6...Protrusion, 7...Liquid supply port, 8...
Electrode, 9...center press, 10...thumb screw,
11...Press plate, 12...Bolt.

Claims (1)

[Scope of Claim for Utility Model Registration] 1. In a dialysis device in which a membrane cartridge formed by integrating an ion exchange membrane or a semipermeable membrane and a gasket is attached to a dialysis cell, at least one surface of the dialysis cell in contact with the membrane cartridge, A dialysis device comprising a convex portion having a smaller area than the surface and having a liquid contact portion. 2. The dialysis apparatus according to claim 1, wherein the convex portion is provided in a band shape around the liquid contact portion of the dialysis cell. 3. The dialysis apparatus according to claim 1 or 2, wherein the dialysis cell has an effective current-carrying area of 100 cm ² or less. 4. The dialysis apparatus according to any one of claims 1 to 3, in which the dialysis cell and membrane cartridge are installed in a center press manner.