JPWO2007072914A1 - Electroosmotic pump, pumping system, microchemical chip and fuel cell - Google Patents

Abstract

In particular, an electroosmotic flow pump capable of generating strong liquid feeding force over a long range of a flow path, a pumping system, a microchemical chip and a fuel cell using the electroosmotic flow pump are provided. At least a part of the surface of the flow path 15 through which the liquid flows is formed of the dielectric 11, and electrodes 14a and 14b are disposed on one side and the other side in the extending direction of the flow path 15 with respect to the dielectric 11, respectively. An electroosmotic pump that applies a voltage between the electrodes 14a and 14b on one side and the other side of the electric double layer generated between the liquid and the dielectric 11, and causes the liquid to flow. The electrodes 14a and 14b on one side and the other side are located on the bottom surface of the recess formed in the inner surface of the flow path 15 so that they face each other on both side surfaces facing each other in the extending direction of the flow path 15 of the recess. Are arranged.

Description

  The present invention relates to an electroosmotic flow pump using a phenomenon of electroosmotic flow generated between a liquid and a dielectric in contact with the liquid as a liquid feeding mechanism, a microchemical chip mounted with the electroosmotic flow pump, and The present invention relates to a fuel cell.

  In the field of chemical technology and biotechnology, research is being conducted to carry out reactions to reagents and analysis of samples in a microscopic area. Chemical and biochemical reactions using MEMS (Micro Electro Mechanical Systems) technology, Research and development have been conducted on a microchemical system in which a system for analyzing a sample is miniaturized.

  Reactions and analyzes in a microchemical system are performed using a single chip called a microchemical chip in which a microchannel, a micropump, a microreactor, and the like are formed. For example, a supply port for supplying a fluid such as a sample or a reagent (a mixture of a solute in a liquid such as water) to a single substrate made of silicon, glass, or resin, and for deriving the processed fluid A microchemical chip in which the supply port and the sampling port are connected by a microchannel having a small cross-sectional area, and a micropump for feeding liquid is disposed at an appropriate position in the microchannel. It has been proposed (see Patent Documents 1 and 2).

  Conventionally, micropumps that have used mechanical reciprocating motion such as piezoelectric micropumps as disclosed in Patent Documents 1 and 2 have been mainly employed. In conducting analysis, an electroosmotic flow pump has attracted attention because it is necessary to feed a very small amount of liquid containing a plurality of substances with higher accuracy.

  The electroosmotic pump is a pump that uses electroosmotic flow, and does not require a check valve that is required for piezoelectric micropumps. Therefore, the structure of the pump is simple and downsizing is possible. Since the pulsation of the liquid generated when the check valve operates does not occur, the liquid can be fed at a stable flow rate. Furthermore, since a flow velocity distribution caused by the friction between the liquid and the channel wall surface does not occur, a very small amount of liquid can be fed with high accuracy.

  Electroosmotic flow means that when a dielectric solid material such as aluminum oxide or silica is brought into contact with a liquid, an electric double layer is formed in the liquid in the vicinity of the interface with the solid. This refers to a phenomenon in which a charge is transferred in a layer by applying an electric potential from the outside, and the liquid moves in one direction along with this.

  For example, when a flow path is formed on a substrate made of silica and filled with a liquid, the silica wall surface has an excessive negative charge, so the positively charged ions in the liquid attract the negatively charged silica wall surface. An electric double layer is formed in the liquid in the vicinity of the interface with silica. In this state, when a voltage is applied from the external electrode, the positively charged layer in the liquid moves to the negative electrode, and the entire liquid moves from the positive electrode to the negative electrode along with the movement of this layer, thereby feeding the liquid.

  Conventional electroosmotic pumps are usually a pair of electrodes (positive electrode and negative electrode) that are formed on a substrate made of aluminum oxide or silica and apply a voltage for transferring electric charges to the wall surface of a flow channel for flowing a liquid. However, it has the structure formed and arrange | positioned with the metal plate etc., for example.

Note that the voltage is applied to the electrodes from, for example, an external power supply via wiring that electrically connects the external power supply and each electrode. (Refer to patent document 3 etc.).
Japanese Patent Laid-Open No. 2002-214241 (page 4-5, FIG. 1) Japanese Patent Laid-Open No. 2002-233792 (page 5-6, FIGS. 1 and 3) JP-T-2002-529235 (FIG. 1)

  However, the conventional electroosmotic flow pump has a problem in that it is difficult to increase the force of liquid feeding, particularly to obtain a strong liquid feeding force over a long range of the flow path.

  This is due to the following reason. The force that the electroosmotic pump pushes the liquid is proportional to the electric double layer potential (ζ potential) generated at the interface between the liquid and the solid and the electric field strength applied to the electric double layer. In order to increase the force of the liquid, it is necessary to shorten the distance between the electrodes or increase the voltage.

  When the distance between the electrodes is shortened, there is a possibility that a short circuit (electrical short circuit) may occur due to contact due to deformation of electrodes formed of metal plates, for example, and the electroosmotic pump may not be driven. .

  When the voltage between the electrodes is increased, the electrode potential becomes negatively higher than the oxidation-reduction potential of the metal material or the like forming the electrode, and the electrode is ionized. For this reason, the electrode components are eluted in the liquid and the electrodes are worn.

  To solve such a problem, a means of increasing the liquid feeding force by arranging a plurality of electroosmotic flow pumps composed of a pair of positive and negative electrodes along the length direction of the flow path can be considered.

  However, in this case, since the negative electrode (or positive electrode) of the adjacent pump is located near the positive electrode (or negative electrode) of a certain pump, it is opposite to the original liquid feeding direction between adjacent pumps. The liquid feeding force is generated in the direction. Therefore, it is difficult to effectively increase the liquid feeding force.

  The present invention has been devised in order to solve the above-described problems, and an object of the present invention is to provide an electroosmotic flow pump capable of producing a strong liquid feeding force over a long range of a flow path, and the electroosmotic flow pump. It is to provide a pumping system, a microchemical chip and a fuel cell.

  The electroosmotic flow pump of the present invention is disposed on a dielectric that forms at least a part of the surface of a flow path through which liquid flows, and on one side and the other side in the extending direction of the flow path with respect to the dielectric. And an electrode for applying a voltage to an electric double layer generated between the liquid and the dielectric, and the dielectric is located on a bottom surface of a recess formed in the inner surface of the flow path. The one-side electrode and the other-side electrode are arranged so as to face each other on both side faces of the recess facing each other in the extending direction of the flow path.

  In the electroosmotic pump according to the present invention, preferably, the electrodes on the one side and the other side are orthogonal to the bottom surface.

  In the electroosmotic flow pump of the present invention, preferably, the concave portion is formed concentrically with respect to the flow path.

  In the electroosmotic flow pump of the present invention, preferably, a protrusion facing the recess is formed on the inner surface of the flow path.

  In the electroosmotic pump according to the present invention, preferably, the dielectric is made of ceramics.

  The pumping system of the present invention has a plurality of electroosmotic flow pumps arranged in series along the direction in which the liquid flows or in parallel with the direction in which the liquid flows, and the plurality of electroosmotic flow pumps Each of them is disposed on one side and the other side in the extending direction of the flow path with respect to the dielectric that forms at least a part of the surface of the flow path through which the liquid flows, and the liquid and the An electrode for applying a voltage to the electric double layer generated between the dielectric and the dielectric is located on a bottom surface of a recess formed in the inner surface of the flow path, and the one side and The electrodes on the other side are disposed so as to face each other on both side faces of the recess facing each other in the extending direction of the flow path.

  In the pumping system of the present invention, preferably, a protrusion facing the recess is formed on the inner surface of the flow path, and in the plurality of electroosmotic pumps, the facing direction of the recess is alternately reversed. Thus, they are arranged in series along the direction in which the liquid flows.

  The microchemical chip of the present invention includes a substrate on which a supply unit for supplying a liquid is formed, a channel formed on at least one of the surface and the inside of the substrate so as to extend from the supply unit, The liquid processing unit formed in the middle and an electroosmotic flow pump for feeding the liquid in the flow path, and the electroosmotic flow pump forms at least a part of the surface of the flow path And a voltage applied to the electric double layer generated between the liquid and the dielectric, respectively, disposed on one side and the other side in the extending direction of the flow path with respect to the dielectric. The dielectric is located on the bottom surface of a recess formed in the inner surface of the flow path, and the one side electrode and the other side electrode are in the extending direction of the flow path in the recess. Place them on opposite sides so that they face each other. To have.

  The microchemical chip of the present invention is preferably equipped with a plurality of the electroosmotic pumps.

  The fuel cell of the present invention includes a base, a flow path for flowing fuel, an electrolyte member disposed in contact with a part of the flow path, and a flow path of the flow path. An electroosmotic pump for feeding the fuel, and the electroosmotic pump includes a dielectric that forms at least a surface of the flow path, and an extension of the flow path with respect to the dielectric. An electrode for applying a voltage to an electric double layer generated between the fuel and the dielectric, the dielectric being an inner surface of the flow path. The electrodes on the one side and the other side are disposed on opposite side surfaces facing each other in the extending direction of the flow path of the recess. .

  The fuel cell of the present invention is preferably equipped with a plurality of electroosmotic pumps.

  According to the electroosmotic flow pump of the present invention, the dielectric is located on the bottom surface of the recess formed on the inner surface of the flow path, and the electrodes on one side and the other side are in the extending direction of the flow path of the recess. Since the electrodes are arranged on opposite side surfaces so as to face each other, each electrode is reinforced by each side surface of the concave portion with which they are in contact, so that the occurrence of deformation or the like is effectively suppressed. . Therefore, it is possible to effectively suppress short-circuiting between electrodes and to form the electrodes with a small interval. As a result, a higher voltage can be applied between the electrodes to further enhance the pump function.

  In addition, since the electrodes on one side and the other side are arranged so as to oppose each other on both side surfaces facing each other in the extending direction of the flow path of the recess, the electrodes in the recess are formed in the vicinity of the surface of the dielectric. A voltage can be efficiently applied to the electric double layer generated in the liquid. Therefore, the liquid feeding force can be increased without increasing the voltage to such an extent that the metal material forming the electrode is dissolved.

  In addition, since the electrodes on one side and the other side are disposed on both side surfaces of the recess, for example, even if a plurality of such electroosmotic pumps are arranged along the length direction of the flow path, they are adjacent to each other. There is no liquid between the electrodes between the electroosmotic pumps. Therefore, it is effectively suppressed that the force of liquid feeding opposite to the original liquid feeding direction is generated between the adjacent electroosmotic pumps. Therefore, it is possible to arrange a plurality of electroosmotic flow pumps along the flow path, for example, by narrowing the interval between adjacent ones, so that an electroosmotic flow that can generate a strong liquid feeding force particularly over a long range of the flow path. A pump can be provided.

  In the electroosmotic pump according to the present invention, in a preferred embodiment, since the electrodes on one side and the other side are orthogonal to the bottom surface of the concave portion made of a dielectric, the electric double layer generated in the liquid in the concave portion In contrast, a voltage can be applied more efficiently, and a stronger liquid feeding force can be expressed.

  Further, in the electroosmotic flow pump of the present invention, when the concave portion is formed concentrically with respect to the flow path, the liquid feeding force is similarly generated over the entire circumference in the cross-sectional direction in the flow path. Can be made. Therefore, it can be set as the electroosmotic flow pump which can produce the force of stronger liquid feeding.

  Further, in the electroosmotic pump according to the present invention, when a protrusion facing the recess is formed on the inner surface of the flow path, a flow to the recess is generated by the protrusion, and it becomes easy to pour liquid between the electrodes. The liquid can be reliably delivered.

  Further, in the electroosmotic pump of the present invention, when the dielectric is made of ceramics, its productivity, work accuracy, etc. are improved.

  In other words, multilayer ceramic manufacturing technology can be applied when making an electroosmotic pump. For example, a green sheet having through holes with different diameters can be laminated and fired with high accuracy to facilitate a flow path having a recess. Can be formed. The electrodes can be easily formed with high precision such as dimensions by means of thick film or thin film forming means such as metallization or plating. Therefore, it is possible to provide an electroosmotic pump excellent in productivity, work accuracy, and the like.

  Moreover, it is easy to arrange a plurality of such electroosmotic flow pumps in the vertical and / or horizontal direction.

  In the pumping system of the present invention, a plurality of electroosmotic pumps having the above-described configuration are arranged in series along the direction in which the liquid flows or in parallel with the direction in which the liquid flows. Since the resultant force of the liquid feeding force of the osmotic flow pump acts on the liquid in the flow path, a stronger liquid feeding force can be obtained.

  In this case, since the electroosmotic pump of the present invention suppresses the generation of the reverse liquid feeding force between the adjacent ones as described above, the plurality of electroosmotic pumps are connected to the adjacent distance. Can be arranged short. Therefore, it can be set as the pumping system which can produce the force of a large liquid feeding with a small occupation area.

  Further, in the pumping system of the present invention, a protrusion facing the recess is formed on the inner surface of the flow path, and the plurality of electroosmotic pumps allow the liquid to flow so that the opposing directions of the recess are alternately reversed. When arranged in series along the direction of flow, the protrusions cause a flow to the recesses, making it easier for liquid to flow between the electrodes, and the outflow direction of one recess and the inflow direction of the next recess Therefore, it becomes easy to pour liquid into the next recess, and the liquid can be fed more reliably.

  Since the microchemical chip of the present invention is formed by forming a liquid flow path in the substrate and mounting the electroosmotic flow pump of any one of the above configurations as a liquid feeding means to the flow path, A microchemical chip having a small size and an excellent liquid feeding function can be provided.

  Moreover, in the microchemical chip of the present invention, when a plurality of electroosmotic pumps are mounted, a microchemical chip with a more excellent liquid feeding function can be obtained.

  The fuel cell of the present invention has a liquid channel formed in the base, and is formed by mounting the electroosmotic flow pump having any one of the above configurations as means for feeding the liquid to the channel. Thus, it is possible to provide a fuel cell having an excellent liquid feeding function.

  Further, in the fuel cell of the present invention, when a plurality of electroosmotic flow pumps are mounted, a fuel cell having a more excellent liquid feeding function can be obtained.

1A is a plan view showing an example of an embodiment of an electroosmotic flow pump of the present invention, and FIG. 1B is a cross-sectional view taken along a cross-sectional line AA in FIG. 1A. 2A is a plan view showing an example of an embodiment of the microchemical chip of the present invention, and FIG. 2B is a partial cross-sectional view showing a cross-sectional configuration taken along cross-sectional lines II, II-II, and III-III in FIG. 2A It is. It is a disassembled perspective view which shows the manufacturing method of the microchemical chip of this invention typically. 4A is a top perspective view showing an example of an embodiment of the fuel cell of the present invention, and FIG. 4B is a bottom perspective view thereof. It is sectional drawing in sectional line BB of the fuel cell in FIG. 4A. It is sectional drawing which shows an example of embodiment of the microchemical chip of this invention.

Explanation of symbols

11: Dielectrics 14, 14a, 14b: Electrodes 15, 15a, 15b, 27a, 27b, 102: Channel 26, 111: Electroosmotic flow pump

  FIG. 1A is a plan view showing a simplified example of the embodiment of the electroosmotic flow pump of the present invention. 1B is a cross-sectional view illustrating a cross-sectional configuration of the electroosmotic flow pump illustrated in FIG. 1A along a cross-sectional line AA.

  In this embodiment, the electroosmotic flow pump is disposed on the inner wall surface of a cylindrical flow path 15 formed in an insulating base material 12 such as a block shape or a plate shape.

  In other words, this electroosmotic pump has at least a part of the surface of the flow path 15 through which the liquid flows formed of the dielectric 11 and sandwiches the dielectric 11 in the extending direction of the flow path 15 so as to sandwich the pair of electrodes 14. An electroosmotic pump that is disposed and applies a voltage between a pair of electrodes 14 to an electric double layer generated between the liquid and the dielectric 11 to cause the liquid to flow. The pair of electrodes 14 are disposed on both side surfaces of the recess so as to be orthogonal to the surface of the dielectric 11 and to face each other.

  The insulating base 12 is formed of an insulating material such as an aluminum oxide sintered body, glass ceramics, or a glass material.

  For example, when the insulating base 12 is made of an aluminum oxide sintered body, it can be produced by laminating ceramic green sheets.

  In the present embodiment, a plurality of the flow paths 15 are formed in parallel so as to penetrate the insulating base material 12 in one direction.

  The shape of the cross section of the flow path 15 (the cross section perpendicular to the extending direction of the flow path) is not particularly limited as long as the liquid can pass as described later. In order to make it small, a circular shape or an elliptical shape is preferable.

  A liquid (not shown) flows through the flow path 15. For example, when the electroosmotic pump of the present invention is applied to a microchemical chip, the liquid flowing through the flow path 15 contains an analyte such as a substrate (biological material, etc.) or metal ions, a raw material compound for chemical synthesis, or the like. Solution, reagent, washing solvent (water, organic solvent) and the like. The liquid is subjected to processing such as mixing, separation, analysis, adsorption, and synthesis. When the electroosmotic pump of the invention is applied to a fuel cell, the liquid flowing through the flow path 15 is a fuel such as methanol, formic acid, dimethyl ether, a mixture of these fuels and water, or the like.

  For example, if the insulating base 12 is made of an aluminum oxide sintered body, the flow path 15 has through holes formed in each ceramic green sheet that becomes the insulating base 12, and the through holes The ceramic green sheets are stacked so as to communicate with each other, thereby forming a cylindrical shape penetrating the insulating base 12.

  The flow path 15 is not limited to a cylindrical shape, and may be a groove shape or the like. A groove-like flow path (not shown) is formed on the surface of a ceramic green sheet that is an insulating base 12 made of an aluminum oxide sintered body, for example, on a groove to be formed or processed using a laser device or the like. It can be formed by pressing a corresponding mold against a ceramic green sheet and denting it into a groove shape.

  Liquid feeding along the extending direction of the flow path is performed by an electroosmotic flow pump. The electroosmotic pump has a recess (not indicated) formed in the flow path 15, a dielectric 11 formed so as to be positioned on the bottom surface of the recess, and both side surfaces facing each other in the extending direction of the flow path of the recess. The electrode 11 is basically composed of a pair of electrodes 14 arranged so as to be orthogonal to the surface of the dielectric 11 and to face each other.

  In the present invention, the bottom surface of the recess means an inner surface parallel to the extending direction of the flow path 15, and the inner surface is constituted by the dielectric 11, so that the liquid can be liquid according to the charged state of the surface of the dielectric 11. An electric double layer is formed in the vicinity of the dielectric 11.

  In the present embodiment, the recess formed in the flow path 15 has a shape in which the wall surface of the flow path 15 is recessed outward from the central axis of the flow path 15 with the same depth.

  Such a concave portion is, for example, a through-hole having a large opening size, with each of the through-holes of the ceramic green sheet forming the flow path 15 having an opening size of a part of which is larger than the opening size of the others. Is formed by laminating such that the outer edge is positioned outside the outer edges of the other through holes.

  The dielectric 11 is formed on the bottom surface of the recess formed in the flow path 15. That is, the dielectric 11 is exposed on the bottom surface of the recess and is in contact with the liquid flowing in the flow path 15. Such a dielectric serves to supplement the generation of the electric double layer.

  As a material of the dielectric 11, an insulating material constituting the insulating base 12 may be used, but a dielectric material such as barium titanate or calcium titanate is used in order to form an electric double layer better. Good.

  For example, the dielectric 11 forms a dielectric green sheet by forming a powder of the above-described material (for example, barium titanate) together with an organic solvent and a binder to form a dielectric green sheet, and the dielectric green sheet becomes the flow path 15. Similarly to the through holes, cylindrical through holes can be formed, and a dielectric green sheet is sandwiched between ceramic green sheets, and the through holes are stacked so as to be connected vertically.

  In this case, the opening size of the through hole of the dielectric green sheet is larger than the through hole of the ceramic green sheet, and the outer edge of the through hole of the dielectric green sheet is larger than the outer edge of the through hole of the ceramic green sheet. Further, the dielectric 11 can be positioned on the inner surface of the recess by laminating the layers so as to be positioned on the outer side.

  The electrodes 14 are respectively formed on one side and the other side in the extending direction of the flow path 15 with respect to the dielectric 11. That is, the electrode 14 is composed of a pair, and one electrode 14 is located on the upstream side of the flow path 15 from the dielectric 11, and the other electrode 14 is located on the downstream side.

  The electrode 14 serves to apply a voltage to the electric double layer portion. As the electrode material, tungsten, molybdenum, platinum, or the like is used, and platinum that is excellent in chemical resistance and does not limit the liquid distributed to the microchemical chip or the fuel cell is particularly desirable. In this case, at least the exposed surface of the electrode 14 may be formed of platinum.

  If the electrode 14 is made of platinum, for example, it can be formed on a green sheet by a printing method using a platinum paste, or can be formed on a conductor surface made of tungsten, molybdenum, or the like by platinum plating.

  In the electroosmotic pump of the present invention, a recess (pump chamber 13) is formed so as to be surrounded by a pair of electrodes 14 (upper electrode 14 a and lower electrode 14 b) and dielectric 12. As a result, a liquid electric double layer is formed inside the recess, and the electric double layer is directly sandwiched between the pair of electrodes 14, whereby a voltage is directly applied to the electric double layer. can do.

  The pump chamber 13 formed in the concave portion of the flow path is formed in the electric double layer generated in the liquid near the surface of the dielectric 11 by applying a voltage between the electrodes 14a and 14b arranged to face each other. The liquid in the pump chamber 13 can be sent along with the movement of the electric charge. Supply of voltage to the electrodes 14a and 14b is performed using, for example, an external electric load device.

  According to the electroosmotic flow pump of the present invention, the dielectric 11 is located on the bottom surface of the recess formed in the flow path 15, and the electrodes 14 a and 14 b on one side and the other side of the recess 15 Since the electrodes 14a, 14b are reinforced by the side surfaces of the recesses with which the electrodes 14a, 14b are arranged so as to be opposed to each other on both side surfaces facing in the extending direction, deformation or the like occurs. Is effectively suppressed. Therefore, it is possible to effectively suppress short-circuiting between the electrodes 14a and 14b and to form the electrode 14a and 14b with a small interval. As a result, a higher voltage is applied between the electrodes 14a and 14b to further enhance the pump function. be able to.

  In addition, the pair of electrodes 14a and 14b are disposed on both side surfaces facing each other in the extending direction of the flow path 15 of the recess so as to face each other. A voltage can be efficiently applied to the electric double layer generated in the liquid. Therefore, the liquid feeding force can be increased without increasing the voltage to such an extent that the metal material forming the electrodes 14a and 14b is dissolved.

  In addition, since the pair of electrodes 14a and 14b are disposed on both side surfaces facing each other in the extending direction of the channel of the recess, for example, a plurality of such electroosmotic pumps are provided along the length direction of the channel. Even if they are arranged, no liquid is interposed between the electrodes 14 between the adjacent electroosmotic pumps. Therefore, it is effectively suppressed that the force of liquid feeding opposite to the original liquid feeding direction is generated between the adjacent electroosmotic pumps. Accordingly, a plurality of electroosmotic flow pumps can be arranged along the flow path, for example, with a small interval between adjacent ones. Therefore, electroosmosis that can generate a strong liquid feeding force over a long range of the flow path 15 in particular. A flow pump can be provided.

  Further, in the electroosmotic pump of the present invention, it is preferable that the electrodes 14 a and 14 b on one side and the other side are orthogonal to the bottom surface of the recess made of the dielectric 11. Thereby, a voltage can be more efficiently applied to the electric double layer generated in the liquid in the recess, and a stronger liquid feeding force can be expressed.

  In the electroosmotic flow pump of the present invention, when the recess is formed concentrically with respect to the flow path, the liquid feeding force can be similarly generated over the entire circumference of the flow path 15 in the cross-sectional direction. it can. Therefore, it can be set as the electroosmotic flow pump which can produce the force of stronger liquid feeding.

  In the form of FIG. 1A, the flow path 15 is formed so as to penetrate in the thickness direction of the insulating base 12. The flow path 15 is not limited to a cylindrical shape as illustrated, and may be a cylindrical shape having a cross section (elliptical shape, square shape) other than a circular shape as described above.

  The cross-sectional shape of the electroosmotic pump is preferably similar to the cross-sectional shape of the flow path 15, but may be other shapes.

  The through-hole serving as the flow path is formed in the green sheet serving as the insulating substrate 12 by using a processing method such as mechanical punching or laser processing. Laser processing is preferably used for forming fine through holes with high accuracy such as dimensional accuracy.

  In addition, in order to form the recess concentrically with respect to the flow path 15, a through hole having a larger opening diameter than the through hole serving as the flow path 15 is formed in the green sheet, and the through hole serving as the recess is formed. Means such as laminating green sheets so that the outer edge of the hole is located outside (concentrically) the outer edge of the through-hole serving as another part of the flow path 15 can be used. In order to perform this lamination with high accuracy, for example, an image laminating machine or the like is used. The concentric shape in this case means that the center of the cross section perpendicular to the length direction of each of the flow path 15 and the concave portion is located on the same line, and if the flow path is a cylindrical shape, In a cross section perpendicular to the length direction, it means concentric circles.

  In the pumping system of the present invention, a plurality of electroosmotic pumps having the above-described configuration are arranged in series along the direction in which the liquid flows or in parallel with the direction in which the liquid flows.

  Note that the electroosmotic flow pumps are arranged in parallel to the direction in which the liquid flows, as shown in FIGS. 1A and 1B, the flow paths 15 are arranged in parallel and the respective flow paths are arranged. 15 is a state in which an electroosmotic flow pump is provided in parallel with each other. As a result, the electrodes 14 of the adjacent electroosmotic pumps are arranged in the same layer. Therefore, when the ceramic green sheet lamination method is used, the electrodes can be printed on the ceramic green sheet at a time, thereby simplifying the process.

  1A and 1B show an example in which a pumping system is formed by arranging a plurality of electroosmotic pumps in both series and parallel directions.

  According to such a pumping system, the resultant force of the liquid feeding forces of the plurality of electroosmotic pumps acts on the liquid in the flow path, so that a stronger liquid feeding force can be obtained.

  In this case, since the electroosmotic pump of the present invention suppresses the generation of the reverse liquid feeding force between the adjacent ones as described above, the plurality of electroosmotic pumps are connected to the adjacent distance. Can be arranged short. Therefore, it can be set as the pumping system which can produce the force of a large liquid feeding with a small occupation area. In addition, the series expressed here is the thickness direction of the insulating base material 12, and the parallel is the plane direction of the insulating base material 12.

  For example, when the viscosity of the liquid to be fed is about 1 m · Pa · s, the cross-sectional area of the pump chamber 13 (the cross-sectional area in the direction perpendicular to the liquid feeding direction) in order to drive the electroosmotic pump efficiently. It is desirable that the distance between the electrodes is 3000 microsquare centimeters to 10,000 microsquare centimeters, and the distance between the electrodes is 100 micrometers to 200 micrometers. Further, in the pumping system, it is desirable that 10 to 20 electroosmotic flow pumps connected in series are arranged in an array of 100 to 500 rows in order to perform liquid feeding more efficiently.

  The microchemical chip of the present invention is formed by forming a liquid flow path in the substrate 21 and mounting the electroosmotic flow pump having any one of the above configurations as means for feeding the liquid to the flow path. Therefore, it is possible to provide a microchemical chip that is small and has an excellent liquid feeding function.

  Moreover, in the microchemical chip of the present invention, when a plurality of electroosmotic pumps are mounted, a microchemical chip with a more excellent liquid feeding function can be obtained.

  Hereinafter, the embodiment of the microchemical chip of the present invention will be described in detail by taking as an example the case of mounting a plurality of electroosmotic pumps.

  In this embodiment, the flow path is formed in such a form that two supply flow paths having a cylindrical region merge in the middle, and the electroosmotic pump is formed in a part of the cylindrical region. The base of the microchemical chip is formed so as to include an insulating base material and a dielectric in which these electroosmotic pumps and flow paths are formed.

  2A is a plan view showing an example of an embodiment of the microchemical chip of the present invention, and FIG. 2B is a cross-sectional line II, II-II, and III-III of the microchemical chip shown in FIG. 2A. The cross-sectional configurations in are shown side by side.

  2A and 2B, the microchemical chip includes a substrate 21 provided with a liquid supply unit 23a, 23b and a collection unit 24 for leading the mixed liquid to the outside. The supply unit 23a includes a supply channel 27a, a supply port 25a provided at an end of the supply channel 27a, and an electroosmotic pump 26a provided upstream of the connection unit 22 in the liquid flow direction. Similarly, the supply unit 23b includes a supply flow path 27b, a supply port 25b, and an electroosmotic flow pump 26b. The supply ports 25a and 25b are opened so that liquid can be injected into the supply channels 27a and 27b from the outside. The collecting unit 24 is realized by an opening so that the liquid that has flowed in can be taken out.

  The material of the base body 21 is formed of, for example, a ceramic material mainly composed of alumina or glass ceramics. In this example, the insulating base 12 of the electroosmotic flow pump is formed by a part of the base 21.

  The flow passage area of the connection portion between the supply flow passages 27a and 27b and the electroosmotic flow pumps 26a and 26b is wide enough to cover the region where the electroosmotic flow pump is disposed.

  The microchemical chip of the present invention is used for testing with viruses, bacteria, or body fluid components in body fluids such as blood, saliva, urine, etc., reaction experiments with viruses, bacteria, and drug solutions, and biological reaction experiments with viruses, bacteria, drug solutions, and somatic cells. It can be used for blood identification, separation / decomposition and decomposition of chemicals with chemicals, decomposition and precipitation of chemical substances in solution, and mixing of multiple chemicals. Moreover, by mounting the pumping system of the present invention, the liquid to be fed is not physically impacted, and the liquid is driven at a low voltage, so that the electrical shock can be minimized and the liquid can be fed.

  Next, a manufacturing method of the electroosmotic flow pump 26 of the microchemical chip shown in FIGS. 2A and 2B will be described. In the present embodiment, a case where the base 21 is made of a ceramic material will be described. 3A and 3B are diagrams showing the processed state of the ceramic green sheets 31, 32, and 33. FIG.

  First, an appropriate organic binder and solvent are mixed into the raw material powder, and a plasticizer or dispersant is added as necessary to form a slurry, which is then formed into a sheet by the doctor blade method or calendar roll method. A ceramic green sheet is formed. As the raw material powder, for example, aluminum oxide, silicon oxide, magnesium oxide, calcium oxide, or the like is used when the substrate 21 is made of an aluminum oxide sintered body.

  In the present embodiment, the base 21 is formed using the ceramic green sheet formed in this way. First, as shown in FIG. 3A, the ceramic green sheet 31 is formed with a through hole 34 serving as the upper flow path 15a, a through hole 36 serving as the lower flow path 15b, and a through hole 35 serving as the pump chamber 13 of the electroosmotic flow pump. Since these through holes need to have a diameter of 50 micrometers or less, it is preferable to use a laser. The diameter of the through hole 35 is formed to be larger than the diameter of the through holes 34 and 36. Further, the through holes 34, 35, and 36 are formed according to a predetermined number of electroosmotic pumps that are formed in parallel. Further, the green sheets 31, 32, 33 are formed in a number corresponding to a predetermined number of electroosmotic pumps formed in series.

  Next, as shown in FIG. 3B, a conductive paste prepared by mixing a metal powder, an organic binder, and a solvent in a peripheral portion of the through hole 34 on the back surface of the ceramic green sheet 31 is predetermined by a screen printing method or the like. The pattern 37 used as the upper electrode 14a of an electroosmotic flow pump is formed by apply | coating to the shape of this. Next, as shown in FIG. 3B, a conductive paste is applied in a predetermined shape to the outer peripheral portion of the through hole 36 on the surface of the ceramic green sheet 33 by a screen printing method or the like. A pattern 38 is formed. In this embodiment, tungsten, molybdenum, platinum, or the like is used as a raw material for the metal powder, but platinum that is excellent in chemical resistance and does not restrict the liquid that flows through the microchemical chip is particularly desirable.

  Next, the ceramic green sheets 31, 32, and 33 are stacked, and the stacked green sheets are sintered at about 1,600 ° C. As described above, the electroosmotic pump 26 in the insulating base 21 shown in FIGS. 2A and 2B is formed.

  The fuel cell of the present invention is formed by forming a liquid flow path in a substrate and mounting the electroosmotic flow pump having any one of the above configurations as means for feeding the liquid to the flow path. Therefore, it is possible to provide a fuel cell that is small and has an excellent liquid feeding function.

  Further, in the fuel cell of the present invention, when a plurality of electroosmotic flow pumps are mounted, a fuel cell having a more excellent liquid feeding function can be obtained.

  Hereinafter, embodiments of the fuel cell of the present invention equipped with an electroosmotic flow pump will be described in detail.

  4A is a top perspective view showing an example of an embodiment of the fuel cell of the present invention, and FIG. 4B is a bottom perspective view thereof. FIG. 5 shows a cross-sectional view of the fuel cell shown in 4A along the cross-sectional line BB.

  In FIG. 5, the fuel cell includes a base body 101 in which a flow path 102 for supplying fuel to the electrolyte member 105 is formed. The base 101 is provided with the electroosmotic flow pump 111 of the present invention as a fuel feeding means.

  In this embodiment, a fuel storage unit 110 comprising a cavity for storing fuel is provided in the base 101, and the electrolyte is passed through the flow path 102 while feeding the fuel in the fuel storage unit 110 by the electroosmotic flow pump 111. Fuel is supplied to the member 105.

  The electrolyte member 105 is accommodated in a recess 117 provided in the base 101, and a lid 107 having a flow path 108 for allowing air to flow into the electrolyte member 105 is attached. The electrode 103 formed on one main surface of the electrolyte member 105 is in contact with the fuel supply flow path 102 and is electrically connected to a connection conductor 106 a formed of a part of the wiring conductor 106 formed on the base 101. ing. The connection conductor 106 a is connected to an external connection pad 109 a formed on the surface of the base 101 through the wiring conductor 106.

  The electrode 103 formed on the other main surface of the electrolyte member 105 is in contact with the flow path 108 and is electrically connected to the connection conductor 106 b connected to the wiring conductor 106 formed on the lid 108. The connection conductor 106 b is connected to an external connection pad 109 b formed on the surface of the base 101 through the wiring conductor 106.

  Further, in the present embodiment, the cavities 112 are formed on the surface of the base 101 to mount the electronic components 113 to 116. Such electronic components are, for example, a power supply device such as a DC / DC converter, a control device such as a CPU, ROM, and RAM, a capacitor, an antenna, and the like.

  The material of the base 101 is made of, for example, a ceramic material mainly composed of alumina or glass ceramics. In this example, the substrate 101 is formed by laminating insulating layers 101a to 101g made of ceramics or the like. Further, an insulating base material 12 of the electroosmotic pump is formed by a part of the base 101.

  This invention is not limited to the above embodiment, You may implement in a various aspect. For example, although the microchemical chip and the fuel cell of the present embodiment are made of aluminum oxide ceramics, any material that causes an electroosmosis phenomenon may be used, and for example, glass ceramics containing silica may be used. Furthermore, as long as the material constituting the pump chamber of the electroosmotic flow pump is a material that causes an electroosmosis phenomenon, the other part may be formed of another material.

  In the present embodiment, the electroosmotic pump is formed so that the liquid flows in a direction perpendicular to the insulating base 12, but the liquid flows in the flow path 15 and the electroosmotic pump in the plane direction of the insulating base 12. You may form in.

  Furthermore, the electrodes 15a and 15b constituting the electroosmotic flow pump may be embedded in the dielectric 11 or the insulating base 12 at a portion other than the portion that is exposed to the pump chamber formed of the recess and is in contact with the liquid.

  In the present embodiment, the electroosmotic pump is disposed in the linear portion of the flow path. However, the electroosmotic flow pump may be disposed in the bent portion of the flow path. In this case, the side projecting to the outside of the flow path (the outer peripheral side of the bent portion) may be regarded as an example of the recess of the present invention, and a pair of electrodes may be attached to the recess.

  FIG. 6 shows an example in which an electroosmotic flow pump is arranged at the bent portion of the flow path. The channel 215 is formed linearly as a whole. The flow path 215 is provided with a bent portion 215a that returns to the flow path 215 after being shifted to the side so as to meander the flow path 215.

  The bent portion 215a is configured, for example, by forming a recess 216 on the inner surface of the flow channel 215 and forming a protrusion 217 on the inner surface of the flow channel 215 facing the recess 216. The bottom surface of the recess 216 is formed by a dielectric 218. In the recess 216, opposite electrodes 219 are arranged on both side surfaces facing each other in the extending direction of the flow path 215. Then, by applying a voltage to the pair of electrodes 219, liquid feeding is performed in the flow path 215 as in the embodiment.

  In this way, when the electroosmotic pump is disposed with the outer peripheral side of the bent portion regarded as a concave portion, the liquid easily flows between the electrodes along the bent portion as shown by the arrow 221 in FIG. Liquid feeding can be performed.

  As shown in FIG. 6, a plurality of bent portions 215 a may be provided along the extending direction of the flow path 215. Further, in this case, the concave portions 216 may be provided so that the opposing directions are alternately reversed. By doing so, the outflow direction of one concave portion 216 and the inflow direction of the next concave portion 216 are close to each other, so that the liquid can be easily poured into the next concave portion 216 and the liquid can be fed effectively.

  For example, as in the embodiment shown in FIG. 1, such a bent portion 215 a is formed by laminating a ceramic green sheet and a dielectric green sheet in the extending direction of the flow path 215, so that the ceramic green sheet and the dielectric green sheet are stacked. When the through holes of the sheet are connected to form the flow path 215, the position of the through hole of the dielectric green sheet is shifted from the position of the through hole of the ceramic green sheet in the radial direction of the through hole. it can.

Claims (11)

A dielectric that forms the surface of at least a portion of the flow path through which the liquid flows;
An electrode that is arranged on one side and the other side in the extending direction of the flow path with respect to the dielectric, and that applies a voltage to the electric double layer generated between the liquid and the dielectric. ,
The dielectric is located on the bottom surface of a recess formed on the inner surface of the flow path,
The electroosmotic pump according to claim 1, wherein the electrodes on the one side and the other side are arranged so as to face each other on both side faces of the recess facing each other in the extending direction of the flow path.   The electroosmotic pump according to claim 1, wherein the electrodes on the one side and the other side are orthogonal to the bottom surface.   The electroosmotic pump according to claim 1, wherein the recess is formed concentrically with respect to the flow path. The electroosmotic pump according to claim 1, wherein a protrusion facing the recess is formed on the inner surface of the flow path.   The electroosmotic pump according to claim 1, wherein the dielectric is made of ceramics. A plurality of electroosmotic pumps arranged in series along the direction in which the liquid flows or in parallel with the direction in which the liquid flows;
Each of the plurality of electroosmotic flow pumps is
A dielectric that forms a surface of at least a portion of the flow path through which the liquid flows;
An electrode that is arranged on one side and the other side in the extending direction of the flow path with respect to the dielectric, and that applies a voltage to the electric double layer generated between the liquid and the dielectric. ,
The dielectric is located on the bottom surface of a recess formed on the inner surface of the flow path,
The one side electrode and the other side electrode are arranged so as to face each other on both side faces of the recess facing each other in the extending direction of the flow path. On the inner surface of the flow path, a protrusion facing the recess is formed,
The pumping system according to claim 6, wherein the plurality of electroosmotic flow pumps are arranged in series along a direction in which the liquid flows such that opposing directions of the recesses are alternately reversed. A base on which a supply unit for supplying a liquid is formed;
A flow path formed on at least one of the surface and the inside of the base so as to extend from the supply section;
A treatment section of the liquid formed in the middle of the flow path;
An electroosmotic flow pump for feeding the liquid in the flow path,
The electroosmotic flow pump is
A dielectric that forms a surface of at least a portion of the flow path;
An electrode that is arranged on one side and the other side in the extending direction of the flow path with respect to the dielectric, and that applies a voltage to the electric double layer generated between the liquid and the dielectric. ,
The dielectric is located on the bottom surface of a recess formed on the inner surface of the flow path,
The one side electrode and the other side electrode are arranged so as to face each other on both side faces of the recess facing each other in the extending direction of the flow path.   The microchemical chip according to claim 8, wherein a plurality of the electroosmotic pumps are mounted. A substrate;
A flow path for flowing fuel provided in the substrate;
An electrolyte member disposed in contact with a part of the flow path;
An electroosmotic flow pump for feeding the fuel in the flow path,
The electroosmotic flow pump is
A dielectric that forms a surface of at least a portion of the flow path;
An electrode that is arranged on one side and the other side in the extending direction of the flow path with respect to the dielectric and applies voltage to the electric double layer generated between the fuel and the dielectric. ,
The dielectric is located on the bottom surface of a recess formed on the inner surface of the flow path,
The electrodes on the one side and the other side are arranged so as to face each other on both side faces of the recess facing each other in the extending direction of the flow path.   The fuel cell according to claim 10, wherein a plurality of the electroosmotic pumps are mounted.

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