1. Field of the Disclosure
The present disclosure relates to a flow channel plate having an electrode in a flow channel, and more particularly to a flow channel plate, having an electrode in a flow channel, that continuously causes an electrochemical reaction by applying a voltage to the electrode.
2. Description of the Related Art
A flow channel plate formed by a joined member with two base materials joined together is used as a microreactor or a chip for use in analysis.
For example, PCT Japanese Translation Patent Publication No. 2012-504243 discloses a microfluidic device that is used to flow a fluid including particles to be captured so that fine eddies are formed in the fluid by flowing the fluid through grooves defined on the surface of a wall of a microchannel.
By contrast, a flow channel plate that causes an electrochemical reaction as a microreactor has an electrode in a flow channel. An electrochemical oxidation reduction reaction is performed on a surface of the electrode by applying a voltage to the electrode provided in the flow channel. An electrochemical reaction can be continuously performed by flowing a fluid through the flow channel.
The microfluidic device described in PCT Japanese Translation Patent Publication No. 2012-504243 has no electrode, so the microfluidic device has been unable to cause an electrochemical reaction. Therefore, it can be thought that electrodes are added to the upstream and downstream of the flow channel.
However, in the flow channel plate that causes an electrochemical reaction as a microreactor, a flow is likely to become a laminar flow due to the effects of viscosity and the flow channel size. It is difficult to add electrodes to portions at which the grooves 135 are formed in the flow channel in the microfluidic device 100 described in PCT Japanese Translation Patent Publication No. 2012-504243; when electrodes are added only to the upstream and downstream of the grooves 135, a flow on the electrode surface becomes a laminar flow, so the agitation efficiency could not be increased. Therefore, there has been the problem that, with the electrodes provided at different places from the grooves 135, the fluid contributes to an electrochemical reaction only when the fluid flows near surfaces of the electrodes, so it is not possible to cause the fluid to sufficiently react.
In a flow channel plate in which a first base material and a second base material are joined together so that a recessed portion formed at least in any one of the first base material and second base material is used as a flow channel. An electrode having a recessed and projected shape that encourages a fluid flowing through the flow channel to become a turbulent flow is formed at least on part of a portion corresponding to the flow channel, the portion being part of the second base material, and that the second base material is provided with an electrode extraction section that is brought into conduction with the electrode.
According to this structure, due to the electrode having a recessed and projected shape, the fluid flowing through the flow channel becomes a turbulent flow and the agitation efficiency can thereby be increased on the electrode. In addition, the side surfaces of the electrode having a recessed and projected shape also function as an electrode, so the electrode having a recessed and projected shape can have a larger electrode area than a flat-plate electrode. Therefore, it is possible to cause a sufficient electrochemical reaction.
Embodiments of the present invention will be described below in detail with reference to the drawings. For easy comprehension, dimensions on the drawings have been appropriately changed.
In the flow channel plate 1 in the embodiment of the present invention, a first base material 10 and the second base material 20 are joined together to form a flow channel 5 through which a fluid is caused to flow, as illustrated in
The first base material 10 is formed by injection molding of cycloolefin polymers. As illustrated in
The second base material 20 is formed by injection molding of cycloolefin polymers. As illustrated in
As illustrated in
Furthermore, an electrode extraction section 40 is provided on another surface 20b of the second base material 20, the other surface 20b being opposite to the one surface 20a on the same side as the flow channel 5. The electrode extraction section 40 has an external electrode (bus electrode 41) formed on the other surface 20b of the second base material 20 and also has through-electrodes 42 formed so as to pass through the second base material 20 from the other surface 20b to the one surface 20a. The electrode extraction section 40 is electrically connected to the electrode 30 through the through-electrodes 42 in the vicinity of their corresponding vertexes 32a of the ridges 32. The through-electrode 42 and bus electrode 41 in this embodiment are formed by printing a conductive paste that includes carbon.
In this embodiment, since the electrode extraction section 40 is not exposed to the flow channel 5, the electrode extraction section 40 does not hinder the flow of the fluid that flows in the flow channel 5. In addition, the bus electrode 41 is provided on the other surface 20b opposite to the one surface 20a on the same side as the flow channel 5, with the through-electrodes 42 intervening between bus electrode 41 and the one surface 20a, so it is easy to reduce the resistance values of the through-electrodes 42 and bus electrode 41. Therefore, a resistance loss can be reduced without hindering the flow of the fluid.
Although, in this description, an aspect in which only one electrode 30 is disposed together with the electrode extraction section 40, which is electrically connected, is described, a plurality of electrodes are disposed in the flow channel plate 1. For example, the electrode 30 in this embodiment is provided and another electrode that forms a pair with the electrode 30 is further provided at the upstream or downstream of the flow channel 5; the other electrode is also formed in the same shape as the electrode 30 in this embodiment. The other electrode that forms a pair with the electrode 30 in this embodiment may be in a different shape from the electrode 30.
Next, the flow of a fluid in the flow channel plate 1 in this embodiment will be described.
It will be assumed that at the average flow velocity Vy of a fluid flowing in the flow channel 5, on a boundary (wall surface of the flow channel 5) with the electrode film 31, the flow is a laminar flow with a flow velocity of zero. Since the electrode 30 having a recessed and projected shape is provided, when the fluid is near the boundary with the electrode film 31 in the height direction of the flow channel 5 (Z1-Z2 direction), the flow of the fluid in the Y2 direction is hindered by the ridges 32. Therefore, a flow velocity component Vx along the side surface 32b of the ridge 32 and a flow velocity component Vz that attempts to pass over the ridge 32 toward the Z2 side are generated. The flow velocity component Vx and flow velocity component Vz vary depending on the position. On the X1 side and X2 side of the vertex 32a of the ridge 32, the fluid flows so that it is separated into a fluid in which the flow velocity component Vx is orientated toward the X1 side and a fluid in which the flow velocity component Vx is oriented toward the X2 side. By contrast, on the downstream side of the ridge 32 on which the fluid has passed over the ridge 32, a flow in the opposite direction is generated so as to compensate the flows of these fluids. As a result of these flows being combined, a spiral flow in directions (X1-X2 direction and Z1-Z2 direction) perpendicular to the direction (Y-Y2 direction) of the flow in the flow channel 5 is generated. Since, in this embodiment, a plurality of ridges 32 are provided, a flow having these flow velocity components Vx and Vz is repeatedly generated, so the vicinity of the electrode 30 having a recessed and projected shape is in a state in which the laminar flow is disturbed. Therefore, the fluid in the vicinity of the boundary between the electrode film 31 and the side surface 32b of the ridge 32 is agitated, so the fluid is easily exchanged and the flow velocity is increased when compared with a case in which there is only a laminar flow. If the height h32 of the ridge 32 falls within a range from one-third to two-thirds of the height h5 of the flow channel 5 in the height direction, a sufficient agitation effect is obtained.
The flow channel plate 1 in this embodiment was manufactured as described below.
The first base material 10 was formed in a flat-plate shape by injection molding of cycloolefin polymers. As illustrated in
The second base material 20 was formed in a flat-plate shape by injection molding of cycloolefin polymers. As illustrated in
The bus electrode 41 was formed on the other surface 20b of the second base material 20, the other surface 20b being opposite to the one surface 20a, by printing a conductive paste that includes carbon and then firing the printed conductive paste. Then, a conductive paste that includes carbon was injected into the through-holes 21 from the one surface 20a of the second base material 20 by using a dispenser, after which the injected conductive paste was fired. Due to these processes, the electrode extraction section 40 was formed on the second base material 20, as illustrated in
Furthermore, as illustrated in
The flow channel plate 1 was obtained by bringing a surface of the first base material 10, the recessed portion 11 being formed in the surface, and the one surface 20a of the second base material 20, the electrode 30 being formed on the second base material 20, into tight contact with each other through an adhesive that includes paraffin as the main component and then bonding these surfaces so that the flow channel 5 is formed. The bonding method is not limited to this type of method in which adhesion is performed through an adhesion layer; thermal welding and the like are possible.
In the flow channel plate 1, a fluid is transferred through the flow channel 5 so that the vertex 32a of the ridge 32 is oriented toward the upstream side. To obtain a desired electrochemical reaction, a voltage is applied from the bus electrode 41 to the electrode 30, and a current due to the electrochemical reaction is passed. It is preferable to use a carbon material for the flow channel plate 1 because a potential window in an oxidation-reduction reaction is wide, chemical resistance to a liquid to be used is high, the flow channel plate 1 can be formed in a desired pattern by, for example, screen printing, and the like.
With the flow channel plate 1 in this embodiment, the fluid flowing in the flow channel 5 becomes a laminar flow due to the electrode 30 having a recessed and projected shape, so the agitation efficiency can be increased on the electrode 30 and the fluid can be sufficiently supplied to the surface of the electrode 30. In addition, the electrode 30 having a recessed and projected shape can have a larger electrode area than a flat-plate electrode because the side surfaces 32b also function as an electrode. Therefore, a sufficient electrochemical reaction can be caused by flowing the fluid through the flow channel 5 while agitating the fluid and applying a voltage to the electrode 30.
The flow channel plate 1 in this embodiment and a flow channel plate in a shape without recessed and projected parts were used to transfer water and dodecane (CH3-(CH2)10-CH3) from the upstream in a state in which they are separated, and mixture degrees at the downstream were compared. A difference of 10 times and more in the mixture degree of water and dodecane (CH3-(CH2)10-CH3) was obtained between the flow channel plate 1 in this embodiment and the flow channel plate in a shape without recessed and projected parts.
Effects obtained from this embodiment will be described below.
According to the present invention, in the flow channel plate 1 in which the first base material 10 and second base material 20 joined together so that the recessed portion 11 formed in the first base material 10 is used as the flow channel 5, the electrode 30 having a recessed and projected shape is formed on part of a portion corresponding to the flow channel 5, the portion being part of the second base material 20.
According to this structure, due to the electrode 30 having a recessed and projected shape, the fluid flowing through the flow channel 5 becomes a turbulent flow and the agitation efficiency can be increased on the electrode 30. In addition, the side surfaces 32b of the electrode 30 having a recessed and projected shape also function as an electrode, so the electrode 30 can have a larger electrode area than a flat-plate electrode. Therefore, it is possible to cause a sufficient electrochemical reaction by flowing the fluid through the flow channel 5 and applying a voltage to the electrode 30 provided in the flow channel 5.
In the flow channel plate 1 in the present invention, the first base material 10 may be a flat-plate shape and the recessed portion 11 may be formed in the first base material 10, and the second base material 20 may be in a flat-plate shape and the recessed and projected shape of the electrode 30 may be comprised of a plurality of ridges 32, each of which has a predetermined angle with respect to the liquid transfer direction of the flow channel 5, and of the electrode film formed 31 among the plurality of ridges 32.
According to this structure, it is easy to form the electrode 30 having a recessed and projected shape.
In the flow channel plate 1 in the present invention, each of the plurality of ridges 32 may be in a V-shape that has the vertex 32a oriented toward the upstream 5a of the fluid flowing through the flow channel 5.
According to this structure, the agitation efficiency can be further increased on the electrode 30.
In the flow channel plate 1 in the present invention, assuming that a direction perpendicular to the one surface 20a of the second base material 20 is the height direction of the flow channel 5, the plurality of ridges 32 may be formed so that their height falls within a range from one-third to two-thirds of the height h5 of the flow channel 5 in the height direction.
According to this structure, the agitation efficiency can be further increased on the electrode 30 without the flow of the fluid being largely hindered.
In the flow channel plate 1 in the present invention, the electrode extraction section 40 may have the bus electrode 41 formed on the other surface 20b of the second base material 20, the surface being on the opposite side to the one surface 20a on the same side as the flow channel 5, and may also have the through-electrodes 42 formed so as to pass through the second base material 20 from the other surface 20b to the one surface 20a; the electrode extraction section 40 may be electrically connected to the electrode 30 through the through-electrodes 42.
According to this structure, the electrode 30 can be extracted without the flow channel 5 being affected and the structure does not hinder the fluid flowing through the flow channel 5 from increasing the agitation efficiency on the electrode 30 by becoming a laminar flow.
In the flow channel plate 1 in the present invention, the electrode 30 and electrode extraction section 40 may be formed by printing a conductive paste that includes carbon.
According to this structure, since a conductive paste that includes carbon is printed, the electrode 30 can be easily formed.
So far, the flow channel plate 1 in the present invention has been specifically described, but the present invention is not limited to the above embodiment. Various changes are possible without departing from the intended scope of the present invention. For example, the present invention can also be practiced by making variations as described below. These variations are also included in the technical range of the present invention.
(1) Although, in this embodiment, as for the electrode 30, the electrode film 31 has been formed among the plurality of ridges 32, the electrode 30 may be comprised of only a plurality of ridges 32.
(2) Although, in this embodiment, two sets of a plurality of ridges 32 have been combined, the position of the vertex 32a being different between the two sets, three sets or more may be combined.
(3) Although, in this embodiment, the recessed portion 11 has been formed in the first base material 10, the recessed portion 11 and through-holes 21 may be formed in the second base material 20. In addition, although cycloolefin polymers have been used to form the first base material 10 and second base material 20, cycloolefin copolymers may be used instead of cycloolefin polymers. Furthermore, the shape of the electrode extraction section 40 may be in another aspect. Moreover, the electrode 30 and electrode extraction section 40 may be formed by a manufacturing method other than printing.
Number | Date | Country | Kind |
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2014-016538 | Jan 2014 | JP | national |
This application is a Continuation of International Application No. PCT/JP2015/051540 filed on Jan. 21, 2015, which claims benefit of priority to Japanese Patent Application No. 2014-016538 filed on Jan. 31, 2014. The entire contents of each application noted above are hereby incorporated by reference.
Number | Date | Country | |
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Parent | PCT/JP2015/051540 | Jan 2015 | US |
Child | 15219689 | US |