WO2012157052A1 - 光反応マイクロリアクタ - Google Patents
光反応マイクロリアクタ Download PDFInfo
- Publication number
- WO2012157052A1 WO2012157052A1 PCT/JP2011/061112 JP2011061112W WO2012157052A1 WO 2012157052 A1 WO2012157052 A1 WO 2012157052A1 JP 2011061112 W JP2011061112 W JP 2011061112W WO 2012157052 A1 WO2012157052 A1 WO 2012157052A1
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- WO
- WIPO (PCT)
- Prior art keywords
- microreactor
- photoreaction
- fluid
- plate
- flow path
- Prior art date
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Images
Classifications
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- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J19/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J19/0093—Microreactors, e.g. miniaturised or microfabricated reactors
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
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- B01J19/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J19/08—Processes employing the direct application of electric or wave energy, or particle radiation; Apparatus therefor
- B01J19/12—Processes employing the direct application of electric or wave energy, or particle radiation; Apparatus therefor employing electromagnetic waves
- B01J19/122—Incoherent waves
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
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Definitions
- the present invention relates to a photoreaction microreactor for advancing a reaction using energy by light.
- microreactor which is a device that mixes fluids in a minute flow path, produced by micromachining technology, to the field of biotechnology, medical treatment, or chemical reaction.
- photoreaction photochemical reaction
- reaction section formed by a tube-like light-transmitting flow path and a light source section including a light source that causes a photoreaction (see, for example, Patent Document 1).
- a fourth method is to use a material having a refractive index similar to that of a fluid or to provide an antireflection film for the purpose of improving the accuracy and resolution of DNA microarray synthesis (see, for example, Patent Document 4).
- a method is known in which an antireflection film is used or a light absorption layer coated with spray paint is provided opposite to the irradiation / detection unit (see, for example, Patent Document 5). ).
- Non-Patent Document 1 when a microreactor on a flat substrate is used and a substrate made of SUS316 is used, reflected light is used.
- a PTFE substrate is used, reflected light is suppressed, but there is a problem that temperature control becomes difficult because of low thermal conductivity.
- Patent Documents 2, and 3 problems in the case where reflected light is used as in the techniques described in Non-Patent Document 1, Patent Documents 2, and 3 will be described below.
- the wavelength of the reflected light depends on the surface condition such as the material and shape of the reflecting surface.
- the processing error also affects the wavelength.
- the wavelength of the light emitted from the light source and the wavelength of the reflected light are not the same, and if the light having a wavelength causing a side reaction is amplified, the yield is lowered. Also, if the flow path surface changes over time due to a cleaning method or the like, the reproducibility of the results cannot be obtained.
- the reflected light reaches the light source, the light source is heated by the reflected light. It is known that the intensity of emitted light and the wavelength range of light change depending on the temperature of the light source.
- the wavelength of the light used for the reaction is not constant. For this reason, reproducibility cannot be obtained particularly when an experiment is performed for a long time, leading to a decrease in yield.
- An object of the present invention is to realize a photoreactive microreactor that can suppress reflected light without using an antireflection film, has high thermal conductivity, and can improve the reproducibility of the resulting product.
- the present invention is configured as follows.
- a channel plate made of a material having a high heat conductivity and suppressing light reflection is formed with a channel for passing the object to be reacted Is provided.
- a flow path for allowing the reactant to pass through is formed, a through flow path plate made of a material that transmits light, and fixed to the through flow path plate, has high thermal conductivity, and reflects light. And a bottom plate made of a suppressing material.
- the present invention it is possible to realize a photoreaction microreactor that can suppress reflected light without using an antireflection film, has high thermal conductivity, and can improve the reproducibility of the resulting product.
- FIG. 1 is a transmission diagram of a photoreaction microreactor device according to a first embodiment of the present invention.
- FIG. It is explanatory drawing of the photoreaction microreactor apparatus using the photoreaction microreactor of FIG. 2, a light source module, and a temperature control module. It is the figure which showed the photoreaction microreactor apparatus in the case of using two photoreaction microreactor units shown in FIG.
- Example 3 is the external appearance and exploded perspective view of the photoreaction microreactor by Example 3 of this invention.
- FIG. 1 is an external view and an exploded perspective view of a photoreaction microreactor according to Example 1 of the present invention.
- a photoreactive microreactor 101 includes an upper housing portion 102, a lid plate 103 made of a material that transmits light, a flow path plate 104 made of a material that suppresses reflection of light and has high thermal conductivity, and a housing. And a lower portion 105.
- the housing upper part 102 is formed with a window part at the center thereof, and has a window frame shape. Light is applied to the flow path 109 of the flow path plate 104 through the window and the lid plate 103 which is a light transmitting member.
- Examples of dimensions of the housing upper part 102, the lid plate 103, the flow path plate 104, and the housing lower part 105 are shown below. However, the dimensions shown below can be appropriately changed in consideration of convenience of use and the like.
- the overall dimensions of the housing upper part 102 are 80 mm long ⁇ 50 mm wide ⁇ 5 mm high, and the window is 40 mm long ⁇ 22 mm wide.
- the overall dimensions of the lid plate 103 are 70 mm long ⁇ 28 mm wide ⁇ 1 mm high.
- the overall dimensions of the flow path plate 104 are vertical 70 mm ⁇ width 28 mm ⁇ height 1.4 mm, and flow path depth 0.2 mm.
- the overall size of the housing lower portion 105 is 80 mm long ⁇ 50 mm wide ⁇ 5 mm high.
- the lid plate 103 is formed with two fluid inlets / outlets 108 penetrating up and down the plate 103.
- the flow path plate 104 is provided with a flow path 109. Both ends of the channel 109 are a fluid inlet and a fluid outlet.
- the lid plate 103 and the flow path plate 104 are fixed (preferably welded) to each other to form an integral plate, so that both ends of the two fluid inlet / outlet ports 108 and the flow path 109 coincide with each other and the fluid flows. It is like that.
- the fluid that is the reaction product introduced from one fluid inlet / outlet 108 of the lid plate 103 is discharged from the other fluid inlet / outlet 108 via the flow path 109.
- the lid plate 103 is made of a material that transmits light. For this reason, light is irradiated from the upper surface of the lid plate 103 and light is transmitted through the fluid flowing in the flow path 109, so that the fluid as the reaction object passes through the flow path 109 in the fluid. Photoreaction proceeds.
- the lid plate 103 and the flow path plate 104 are sandwiched between the housing upper part 102 and the housing lower part 105, and pass through a screw hole 106 formed in the housing upper part 102 and a screw hole 110 formed in the housing lower part 105. It is fixed by screws (not shown).
- a screw hole for fitting is formed in the upper portion 102 of the housing as a tube connecting portion (fluid inlet, fluid outlet) 107.
- a flat bottom fitting (not shown), fluid of the lid plate 103 can be obtained.
- a tube (connecting tube 405 as shown in FIG. 4) can be directly connected to the entrance 108.
- the lid plate 103 made of a material that transmits light and the flow path plate 104 made of a material that suppresses reflection of light and has high thermal conductivity are welded and integrated with each other.
- other configurations are also applicable.
- a packing groove is formed in one of the plates facing each other, and the lid plate 103 and the flow path plate are sandwiched by sandwiching the lid plate 103 and the flow path plate 104 between the housing upper part 102 and the housing lower part 105 using the packing.
- the plate 104 can be brought into close contact with each other to form a flow path.
- screw holes are provided in the lid plate 103 and the flow path plate 104, and a packing groove is formed in one of the opposing plates 103 and 104.
- the packing By using the packing, the housing upper part 102 and the housing lower part 105 are used. Even if it is not, it is possible to form the flow path only by the lid plate 103 and the flow path plate 104.
- the material of the housing upper part 102 and the housing lower part 105 can be appropriately changed as long as the material does not directly contact the reaction solution.
- stainless steel, silicon, hastelloy, silicon resin, fluorine resin, engineering plastic, or the like can be used as the material of the housing upper part 102 and the housing lower part 105.
- the material of the housing lower part 105 is preferably metal from the viewpoint of thermal conductivity, and from the viewpoint of ensuring strength, both the material of the housing upper part 102 and the material of the housing lower part 105 are metal. Is desirable.
- the channel depth of the channel 109 formed in the channel plate 104 is desirably several mm or less, and more preferably in the range of several tens of ⁇ m to 1 mm.
- the light transmitted through the lid plate 103 made of a material that transmits light can reach the bottom surface of the lowermost portion of the flow path 109.
- the channel width of the channel 109 is preferably as large as possible. This is because the light irradiation area can be ensured and the reaction time by light can be ensured.
- the channel 109 is a channel into which one type of fluid is introduced, but two or more types of fluid are introduced, and for example, two or more types of fluids such as a Y shape and a T shape are mixed. Such a flow path shape may be provided.
- the material of the lid plate 103 made of a material that transmits light can be appropriately changed according to the type of reaction as long as it transmits light and does not adversely affect the reaction.
- glass, quartz glass, Pyrex (registered trademark) glass, transparent ceramics, and the like can be used.
- the material of the flow path plate 104 made of a material that suppresses reflection of light and has high thermal conductivity can be selected according to the type of reaction as long as it reflects light and has high thermal conductivity.
- black alumina reflectance: 5.1 to 15.3% at a wavelength of 240 to 2600 nm, thermal conductivity: 31.2 W / (m ⁇ K)
- thermal conductivity 31.2 W / (m ⁇ K)
- the thermal conductivity is as low as about 1 W / (m ⁇ K), and thus it is generated by reaction. The reaction heat is not released well.
- the material of the lid plate 103 and the reaction plate 104 is a metal, that is, a material having a thermal conductivity of about 10 W / (m ⁇ K) or more.
- the thermal conductivity of transparent ceramics is 41 W / (m ⁇ K).
- the thermal conductivity of black alumina is known to be 12 to 31 W / (m ⁇ K), and it is expected to have a heat removal effect compared to conventional glass such as quartz glass and Pyrex (registered trademark) glass. it can.
- the transparent sapphire lid plate 103 and the black alumina channel plate 104 are produced by placing powder (raw material) in a mold and molding it by heat treatment (sintering) at a high temperature.
- an appropriate production method varies depending on the type of ceramic.
- it is represented by a pressure molding method in which powder (raw material) is pressed into a mold and molded.
- a dry molding method, a plastic molding method, a cast molding method, a tape molding method, and the like can also be used.
- FIG. 2 is an exploded view of a photoreaction microreactor apparatus including a photoreaction microreactor unit in which the photoreaction microreactor 101, the light source module 201, and the temperature control module 202 of FIG. 1 are combined.
- FIG. 3 shows the light shown in FIG. It is a permeation
- a light source module 201 includes a substrate 206 on which a light source 207 and a power supply unit 204 for irradiating light to a photoreaction microreactor, a case 203 made of a heat insulating material into which the substrate 206 is placed, and a substrate A pin 205 is provided to prevent 206 from directly contacting the case 203.
- the temperature control module 202 includes a heat transfer plate 210, a circulating fluid circulation unit 211, and a case 209 made of a heat insulating material into which these are contained. In this case 209, the photoreaction microreactor 101 can be accommodated on the heat transfer plate 210.
- a tube outlet (fluid inlet, fluid outlet) 208 is formed in the case 209, and a tube connected to the tube connecting portion 107 of the upper portion 102 of the photoreaction microreactor 101 is taken out from the tube outlet 208. be able to. Then, a fluid 301 as a raw material (reactant) is introduced into the photoreaction microreactor 101 through a tube connected to the tube takeout port 208, and the reaction proceeds by light to become a product 302 into the tube takeout port 208. It is discharged through the connected tube.
- a circulating fluid inlet / outlet 212 is formed in the case 209, and the circulating fluid (heat medium) 213 discharged from the outside of the circulating thermostat or the like is introduced from one circulating fluid inlet / outlet 212, and the circulating fluid circulating unit It is discharged from the other circulating fluid inlet / outlet 212 via 211.
- the circulating fluid circulation unit 211 is maintained at a predetermined temperature by the circulating fluid (heat medium) 213, and heat is transferred to the photoreaction microreactor 101 via the heat transfer plate 210 to adjust the temperature of the photoreaction microreactor 101. It can be performed.
- a cooling device such as a cooling fan may be attached to the light source module 201 in order to stabilize the light source 207.
- a cooling device such as a cooling fan may be attached to the light source module 201 in order to stabilize the light source 207.
- the reaction temperature to be used is close to room temperature, it is not always necessary to use a heat insulating material as the material of the case 203 surrounding the substrate 206.
- the temperature control module 202 is combined with the light source module 201, the temperature of the photoreaction microreactor 101 can be adjusted effectively by using a heat insulating material as the material of the case 203.
- the substrate 206 or the power supply unit 204 touches the case 203 it is preferable to use a non-conductive material for the case 203.
- the type of the light source 207 can be changed as appropriate according to the wavelength and intensity of light necessary for advancing the fluid reaction in the photoreaction microreactor 101.
- an LED lamp, a mercury lamp, an incandescent bulb, an infrared bulb, a far-infrared lamp, or the like can be used.
- the type of circulating fluid (heat medium) 213 can be changed as appropriate according to the reaction temperature to be set.
- water, a water-ethanol mixed solvent, ethylene glycol, or the like can be used.
- the reaction temperature is room temperature, since the material having high thermal conductivity is used for the flow path plate 104, the circulating fluid 213 is not necessarily required depending on the heat due to light absorption and the reaction heat. There is also.
- the heat generated by the absorption of light in the flow path plate 104 is the circulating fluid (heat medium).
- heating is required by 213, it can be efficiently used as a heat source for heating.
- the material of the heat transfer plate 210 can be changed as appropriate according to the thermal conductivity and the physical properties of the circulating fluid (heat medium) 213.
- the thermal conductivity is high in order to play the role of the original heat transfer plate.
- FIG. 4 is a photoreaction microreactor device using the photoreaction microreactor, light source module, and temperature control module of FIG. 2, and shows an example applied when two kinds of raw materials (reactants) are mixed in advance. It is.
- a photoreaction microreactor device 401 includes a mixing microreactor 404, a light source module 201, a temperature control module 202, a photoreaction microreactor 101 disposed between the light source module 201 and the temperature control module 202, and a mixing microreactor 404. And a connection tube 405 for connecting the photoreaction microreactor 101.
- the mixing microreactor 404 has two raw material inlets, and is configured to mix the raw materials introduced from the two raw material (reacted substances) inlets and to flow out from the outlets.
- the first raw material (reacted material) 402 and the second raw material (reacted material) 403 are introduced into the mixing microreactor 404 and mixed by a flow path inside the mixing microreactor 404.
- the raw materials mixed in the mixing microreactor 404 are introduced into the photoreaction microreactor 101 via the connection tube 405. Inside the photoreaction microreactor 101, the photoreaction proceeds while the raw material passes through the flow path by being irradiated with light, and a product 406 is generated.
- the first raw material (reacted material) 402, the second raw material (reacted material) 403, and the circulating liquid (heat medium) 213 are introduced into the temperature control module 202 by some liquid feeding means.
- the liquid feeding means for example, a syringe pump, a manual syringe, a plunger pump, a diaphragm pump, a screw pump, or the like can be used.
- the liquid feeding means using a water head difference may be used.
- the material of the connecting tube 405 can be changed as appropriate according to the temperature and physical properties of the solution flowing in the tube 405 as long as it does not adversely affect the reaction of the solution.
- stainless steel, silicon, glass, hastelloy, silicon resin, fluorine resin, or the like can be used.
- a glass lining, a surface of stainless steel, silicon, or the like coated with nickel or gold, or a silicon surface that has been improved in corrosion resistance, such as an oxidized surface can also be used.
- the mixing microreactor 401 two types of raw materials (reacted substances) are mixed, but three or more types of raw materials may be mixed.
- a mixing microreactor 404 having a flow path for mixing three kinds of raw materials can be provided instead of the mixing microreactor 404, or a mixing microreactor 404 for mixing two kinds of raw materials. By connecting a plurality of these in series, the raw materials can be mixed in order and the desired types (number) of raw materials can be mixed.
- a product obtained via the photoreaction microreactor 101 can be used for the first raw material (reactant) 402, the second raw material (reactant) 403, or both.
- the raw materials may be mixed uniformly or may not be mixed and become non-uniform (so-called emulsified state).
- FIG. 5 is a diagram showing a photoreaction microreactor apparatus when two photoreaction microreactor units shown in FIG. 2 are used.
- the optical microreactor 101 is disposed between the light source module 201 and the temperature control module 202.
- the circulating fluid (heat medium) 213 flows into one temperature control module 202 and flows out, and then flows into another temperature control module 202 and flows out.
- two photoreactive microreactor units are connected in series, and the product 501 obtained by the first photoreactive microreactor 101 is introduced into the second photoreactive microreactor 101. It is possible to lengthen the reaction time by light.
- the flow path plate 104 can suppress light reflection and uses a material having high thermal conductivity. The reproducibility of the product obtained can be improved.
- FIG. 6 is an external view and an exploded perspective view of the photoreaction microreactor according to Example 2 of the present invention.
- a photoreactive microreactor 601 is made of a housing upper part 102, a lid plate 103 made of a material that transmits light, a through-flow path plate 602, and a material that suppresses reflection of light and has high thermal conductivity.
- a bottom plate 604 and a housing lower part 105 are provided.
- the difference between the first embodiment shown in FIG. 1 and the second embodiment shown in FIG. 6 is that, in place of the flow path plate 104 in the first embodiment, in the second embodiment, the through flow path plate 602 and the bottom surface The plate 604 is disposed.
- the other configurations are the same as in the first and second embodiments.
- the through flow passage plate 602 is formed with a through flow passage 603 penetrating from the upper surface to the bottom surface of the plate 602, and the lid plate 103, the through flow passage plate 602, and the bottom plate 604 are welded to each other ( Fixed).
- the lid plate 103, the through-flow path plate 602, and the bottom plate 604 form an integral plate, and the two fluid inlets / outlets 108 and the both ends of the through-flow path 603 are aligned with each other so that fluid flows. It is like that.
- Both end portions of the through channel 603 are a fluid inlet portion and a fluid outlet portion.
- the fluid introduced from one fluid inlet / outlet 108 of the lid plate 103 is discharged from the other fluid inlet / outlet 108 via a passage formed by the through passage 603 and the bottom plate 604.
- the dimension which combined the penetration flow path plate 602 and the bottom face plate 604 can be made equivalent to the flow path plate 104 in the first embodiment.
- the material of the bottom plate 604 is the same material as that of the flow path plate 104, and is a material that suppresses reflection of light and has high thermal conductivity.
- the bottom plate 604 is made of a material that suppresses reflection of light, so that reflected light can be suppressed and the reproducibility of the obtained product can be improved. it can.
- a material having high thermal conductivity is used for the bottom plate 604, temperature controllability can be improved.
- the photoreaction microreactor 601 is combined with the light source module 201 and the temperature control module 202 to form a photoreaction microreactor device. It is possible. Also in the second embodiment, as in the example shown in FIG. 5, a combination of the light reaction microreactor 601 and the light source module 201 and the temperature control module 202 can be arranged in series.
- FIG. 7 is an external view and an exploded perspective view of the photoreaction microreactor according to Example 3 of the present invention.
- a photoreaction microreactor 701 includes a housing upper part 102, a lid plate 702, a flow path plate 104 made of a material that suppresses light reflection and has high thermal conductivity, and a housing lower part 105. .
- the difference between the first embodiment shown in FIG. 1 and the third embodiment shown in FIG. 7 is that, in place of the lid plate 103 in the first embodiment, the reflection of light is suppressed and heat is reduced in the second embodiment.
- a window frame portion 703 made of a highly conductive material and a light transmitting portion 704 made of a material that transmits light are formed.
- the other configurations are the same as in the first and third embodiments.
- the lid plate 702 and the flow path plate 104 are welded to each other to form an integral plate, whereby the two fluid inlet / outlet ports 108 and the both ends of the flow path 109 coincide with each other so that fluid flows.
- the fluid introduced from one fluid inlet / outlet 108 is discharged from the other fluid inlet / outlet 108 via the flow path 109.
- the lid plate 702 includes the window frame portion 703 made of a material having high thermal conductivity and the light transmitting portion 704 made of a material that transmits light. Therefore, only the portion of the flow path 109 of the flow path plate 104 is irradiated with light, and the light to the other portions suppresses the reflection of light on the lid plate 702 and conducts heat. It absorbs in the window frame part 703 which consists of a material with high property.
- the temperature rise due to light absorption can be dispersed by the lid plate 702 and the flow path plate 104, and the temperature controllability can be further improved.
- the photoreaction microreactor 601 can be combined with the light source module 201 and the temperature control module 202 to form a photoreaction microreactor device. Also in the third embodiment, as in the example shown in FIG. 5, a combination of the light reaction microreactor 601 and the light source module 201 and the temperature control module 202 can be arranged in series.
- the material of the window frame portion 703 can be the same as the material of the flow path plate 104.
- the material that suppresses the reflection of light is used for the flow path plate 104, the reflected light can be suppressed and the reproducibility of the obtained product can be improved. Can do. Further, since a material having high thermal conductivity is used for the flow path plate 104, temperature controllability can be improved.
- Heat insulator Case 210 210 Heat transfer plate 211 Circulating fluid circulation section 212 Circulating fluid inlet / outlet 213 Circulating fluid (heat medium) 301 Material (reacted substance) 302 ⁇ -Product, 401 ... Photoreaction microreactor system, 402 ... First raw material (reactant), 403 ... Second raw material (reactant), 404 ... Mixed microreactor, 405 ..Connecting tube, 406... Product, 501... Product, 601... Photoreaction microreactor, 602... Through channel plate, 603. Plate, 701 ... Photoreaction microreactor, 702 ... Lid plate, 703 ... Window frame, 704 ... Light transmission part
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Abstract
Description
、光の反射を抑制し、かつ熱伝導性の高い材質からなる底面プレート604と、ハウジング下部105とを備えている。
Claims (18)
- 被反応物の光反応を進行させるための光反応マイクロリアクタ(101)において、
上記被反応物を通過させるための流路(109)が形成され、熱伝導率が高く、かつ、光の反射を抑制する材質からなる流路プレート(104)を備えることを特徴とする光反応マイクロリアクタ。 - 請求項1に記載の光反応マイクロリアクタにおいて、
上記流路プレート(104)の光反射率は、光の波長が240~2600nmのとき、5.1%~15.3%であることを特徴とする光反応マイクロリアクタ。 - 請求項2に記載の光反応マイクロリアクタにおいて、
上記流路プレート(104)の熱伝導率は、31.2W/(m・K)であることを特徴とする光反応マイクロリアクタ。 - 請求項3に記載の光反応マイクロリアクタにおいて、
上記流路プレート(104)と固着される光透過部材からなるフタプレート(103)を備え、このフタプレート(103)には、上記流路プレート(104)に形成された流路の流体入口と流体出口とのそれぞれ対応する位置に、流体入口(108)と流体出口(108)とが形成されていることを特徴とする光反応マイクロリアクタ。 - 請求項4に記載の光反応マイクロリアクタにおいて、
上記フタプレート(103)及び上記流路プレート(104)を間に挟み込み固定するハウジング上部(102)及びハウジング下部(105)を備え、上記ハウジング上部(102)には、上記フタプレート(103)の上記流体入口と流体出口とそれぞれ対応する位置に、流体入口(107)と流体出口(107)とが形成されていることを特徴とする光反応マイクロリアクタ。 - 請求項5に記載の光反応マイクロリアクタと、
上記光反応マイクロリアクタに光を照射する光源を有する光源モジュール(201)と、
循環液循環部(211)と、上記光反応マイクロリアクタの上記ハウジング上部(102)に形成された流体入口(107)に流体を導入する流体導入口(208)と、上記ハウジング上部(102)に形成された流体出口(107)から流体を導出する流体導出口(208)とを有し、上記光反応マイクロリアクタを収容する温調モジュール(202)と、
を有する光反応マイクロリアクタユニットを備えることを特徴とする光反応マイクロリアクタ装置。 - 請求項6に記載の光反応マイクロリアクタ装置において、
2つの上記光反応マイクロリアクタユニットを互い直列に接続し、一方の光反応マイクロリアクタユニットの流体導入口(208)から導入され、流体導出口(208)から導出された流体が、他方の光反応マイクロリアクタユニットの流体導入口(208)から導入され、流体導出口(208)から導出されることを特徴とする光反応マイクロリアクタ装置。 - 請求項3に記載の光反応マイクロリアクタにおいて、
熱伝導率が高く、かつ、光の反射を抑制する材質からなる窓枠部(703)と、光を透過する材質からなる光透過部(704)とを有し、上記流路プレート(104)と固着されるフタプレート(702)を備え、このフタプレート(702)には、上記流路プレート(104)に形成された流路(109)の流体入口と流体出口とのそれぞれ対応する位置に、流体入口(108)と流体出口(108)とが形成されていることを特徴とする光反応マイクロリアクタ。 - 請求項8に記載の光反応マイクロリアクタにおいて、
上記フタプレート(702)及び上記流路プレート(104)を間に挟み込み固定するハウジング上部(102)及びハウジング下部(105)を備え、上記ハウジング上部(102)には、上記フタプレート(702)の上記流体入口(108)と流体出口(108)とそれぞれ対応する位置に、流体入口(107)と流体出口(107)とが形成されていることを特徴とする光反応マイクロリアクタ。 - 請求項9に記載の光反応マイクロリアクタと、
上記光反応マイクロリアクタに光を照射する光源を有する光源モジュール(201)と、
循環液循環部(211)と、上記光反応マイクロリアクタの上記ハウジング上部(102)に形成された流体入口(107)に流体を導入する流体導入口(208)と、上記ハウジング上部(102)に形成された流体出口(107)から流体を導出する流体導出口(208)とを有し、上記光反応マイクロリアクタを収容する温調モジュールと、
を有する光反応マイクロリアクタユニットを備えることを特徴とする光反応マイクロリアクタ装置。 - 請求項10に記載の光反応マイクロリアクタ装置において、
2つの上記光反応マイクロリアクタユニットを互い直列に接続し、一方の光反応マイクロリアクタユニットの流体導入口(208)から導入され、流体導出口(208)から導出された流体が、他方の光反応マイクロリアクタユニットの流体導入口(208)から導入され、流体導出口(208)から導出されることを特徴とする光反応マイクロリアクタ装置。 - 被反応物の光反応を進行させるための光反応マイクロリアクタ(601)において、
上記被反応物を通過させるための流路(603)が形成され、光を透過させる材質からなる貫通流路プレート(602)と、
上記貫通流路プレート(602)に固着され、熱伝導率が高く、かつ、光の反射を抑制する材質からなる底面プレート(604)と、
を備え、上記流路(603)は、上記貫通流路プレート(602)を貫通して形成されていることを特徴とする光反応マイクロリアクタ。 - 請求項12記載の光反応マイクロリアクタにおいて、
上記底面プレート(604)の光反射率は、光の波長が240~2600nmのとき、5.1%~15.3%であることを特徴とする光反応マイクロリアクタ。 - 請求項13に記載の光反応マイクロリアクタにおいて、
上記底面プレート(604)の熱伝導率は、31.2W/(m・K)であることを特徴とする光反応マイクロリアクタ。 - 請求項14に記載の光反応マイクロリアクタにおいて、
上記貫通流路プレート(602)と固着される光透過部材からなるフタプレート(103)を備え、このフタプレート(103)には、上記貫通流路プレート(602)に形成された流路の流体入口と流体出口とのそれぞれ対応する位置に、流体入口(108)と流体出口(108)とが形成されていることを特徴とする光反応マイクロリアクタ。 - 請求項15に記載の光反応マイクロリアクタにおいて、
上記フタプレート(103)、上記貫通流路プレート(602)、及び上記底面プレート(604)を間に挟み込み固定するハウジング上部(102)及びハウジング下部(105)を備え、上記ハウジング上部(102)には、上記フタプレート(103)の上記流体入口(108)と流体出口(108)とのそれぞれ対応する位置に、流体入口(107)と流体出口(107)とが形成されていることを特徴とする光反応マイクロリアクタ。 - 請求項16に記載の光反応マイクロリアクタと、
上記光反応マイクロリアクタに光を照射する光源を有する光源モジュール(201)と、
循環液循環部(211)と、上記光反応マイクロリアクタの上記ハウジング上部(102)に形成された流体入口(107)に流体を導入する流体導入口(208)と、上記ハウジング上部(102)に形成された流体出口(107)から流体を導出する流体導出口(208)とを有し、上記光反応マイクロリアクタを収容する温調モジュール(202)と、
を有する光反応マイクロリアクタユニットを備えることを特徴とする光反応マイクロリアクタ装置。 - 請求項17に記載の光反応マイクロリアクタ装置において、
2つの上記光反応マイクロリアクタユニットを互い直列に接続し、一方の光反応マイクロリアクタユニットの流体導入口(208)から導入され、流体導出口(208)から導出された流体が、他方の光反応マイクロリアクタユニットの流体導入口(208)から導入され、流体導出口(208)から導出されることを特徴とする光反応マイクロリアクタ装置。
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EP11865894.7A EP2708280B1 (en) | 2011-05-13 | 2011-05-13 | Photoreaction micro reactor |
US14/114,389 US9370760B2 (en) | 2011-05-13 | 2011-05-13 | Microreactor for photoreactions |
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Also Published As
Publication number | Publication date |
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US20160016141A1 (en) | 2016-01-21 |
EP2708280B1 (en) | 2024-02-07 |
CN103517758A (zh) | 2014-01-15 |
EP2708280A1 (en) | 2014-03-19 |
US9821289B2 (en) | 2017-11-21 |
JPWO2012157052A1 (ja) | 2014-07-31 |
EP2708280A4 (en) | 2015-01-14 |
US20140050630A1 (en) | 2014-02-20 |
JP5715244B2 (ja) | 2015-05-07 |
US9370760B2 (en) | 2016-06-21 |
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