Patent Application
20120186972
The present invention relates to a chemical reactor as well as the usage of the chemical reactor in chemical reaction.
Microwave is a kind of electromagnetic wave with wavelength between infrared wavelength and radio wavelength (i.e., within 1 mm-100 cm range).
Microwave has a feature of “volume phase heating” without temperature gradient, which can be used to heat up materials rapidly and uniformly, and has advantages of high thermal efficiency and pollution-free. In addition, microwave has a special “non-heating effect” because it directly acts on the molecules of the reactants. Experiments have shown that microwave have special effects, including: change the process of chemical reaction, decrease the activation energy required for reaction, increase reaction rate, increase equilibrium conversion rate, reduce byproducts, and change stereo-selectivity of the product, etc. Owing to the special promoting effects of microwave to chemical reaction, the usage of microwave in chemical reaction has not only great significance in theoretical research but also great potential in industrial application.
With regard to the above-mentioned features of microwave, in recent years, microwave has been widely researched and applied as an efficient and clean heating means and a chemical reaction means for chemical reaction. However, owing to the short penetration depth of microwave, hotspots may be generated in the material under continuous microwave irradiation and therefore it is difficult to control the reaction temperature; for materials with high viscosity, it is difficult to transfer the material and mix the material homogeneously in the reactor within a microwave cavity. As a result, at present, microwave apparatuses for chemical reaction can't be applied in large-scale industrial applications; instead, the application of microwave apparatuses is only in the stage of laboratory research.
In the Chinese Patent Application No. CN2821468Y, a microwave processor is disclosed. The microwave processor comprises at least a box cavity, wherein, pipe connectors are provided at the center of two opposite side end faces of the box cavity respectively; among the other two opposite side end faces of the box cavity, one side end face is closed, and the other side end face has a flange connector connected to a microwave generating device; a pipe for the fluid to be heated is through set in the box cavity, and the two ends of the pipeline protrudes from the pipe connector. Several of such processors (≦15) can be connected to form a long reactor; while several pipes can be provided in parallel in the cavity. Though this apparatus takes account of the drawback of low penetration depth of microwave, it still doesn't solve the problem of uncontrollable material temperature under continuous microwave irradiation; therefore, it can only be used to heat fluids, but can't be used for chemical reactions that require temperature control under continuous microwave irradiation.
In the Chinese Patent Application No. CN1091394C, an industrial microwave oven for fluid treatment is disclosed, which comprises a microwave resonant cavity with a microwave input port, fluid inlet and outlet and an operating door, as well as sealed screens provided on the fluid inlet and outlet respectively; wherein, a fluid circulator specially designed for allowing the fluid to get physically and chemically reacted completely in a microwave field is provided in the resonant cavity; devices connected to the fluid inlet and outlet for continuous feed and discharge of the fluid as required for the process are mounted on the upper part and lower part of the resonant cavity respectively. Though the apparatus ensures continuous feed and discharge of the material, it can only be used to heat up fluids, but can't be used for chemical reactions that require temperature control under continuous microwave irradiation.
In Chinese Patent Application No. CN2813090Y, a microwave reactor is disclosed; which can be used for continuous organic chemical synthesis; it utilizes the microwave produced by a microwave generator to heat up the organic mixture in a resonant cavity. The resonant cavity has three flanges of connecting port, wherein, the first flange connects a microwave barrier to a microwave generator in a sealed manner, the second flange is connected to a feed pipe, and the third flange is connected to a coil heat exchanger in a sealed manner. The coil heat exchanger transfers excessive reaction heat, to maintain the reaction within predefined temperature range and pressure range. Though the reactor can control the reaction temperature in some degree, the resonant cavity is small, and the duration of microwave irradiation on the material in the resonant cavity is short, and can't ensure the completeness of reaction and the yield rate of product. In addition, the reactor is not applicable to materials with high viscosity.
In Chinese Patent Application No. CN101400195A, a microwave heating apparatus is disclosed, which comprises a microwave irradiating cavity, a material pipe, and a heat exchange pipe. The material pipe is through set in the microwave irradiating cavity, and the heat exchange pipe is provided in the material pipe and is led into and led out of the orifices or wall of the material pipe. The microwave heating apparatus disclosed in the invention can control the material temperature in the material pipe under continuous microwave irradiation, thus achieves controlling temperature in some degree. However, the reaction system is not ideal for chemical reactions of materials having high viscosity, semi-solid phase, and high fouling tendency, and can't be used effectively for heterogeneous catalysis reactions, and have problems related with fouling removal and recondition of the pipe; in addition, when the reaction system is used in chemical reactions that produce gaseous byproducts, it can't exhaust the gasses produced timely, and therefore will influence yield rate of the product.
The object of the present invention is to provide a chemical reactor, which is applicable to chemical reactions of various liquid materials therein, in particular to materials having high viscosity, semi-solid phase, and high fouling tendency; especially, the chemical reactor provided in the present invention is also marvelously applicable to heterogeneous reactions or heterogeneous catalyst reactions.
The chemical reactor provided in the present invention comprises a microwave irradiating apparatus and a chemical reaction apparatus, the microwave irradiating apparatus comprises a microwave generator and a microwave irradiating cavity; wherein, the chemical reaction apparatus comprises a tank and a device for controlling the flow of the material, and at least a part of the tank is located in the microwave irradiating cavity.
The present invention further discloses the use of the chemical reactor provided in the present invention in chemical reactions.
The chemical reactor provided in the present invention can be used for chemical reactions of various liquid materials, especially for chemical reactions of materials having high viscosity, semi-solid phase, and high fouling tendency, and heterogeneous reactions and heterogeneous catalyst reactions. In addition, when the chemical reactor provided in the present invention is used for chemical reactions for producing gaseous byproducts, it can exhaust the gasses timely, decrease the concentration of the resulting byproducts in the tank, and thereby drive the equilibrium of chemical reaction towards the product direction, and improve the conversion rate of the reactants and the yield rate of product.
According to
The microwave irradiating apparatus comprises at least a waveguide tube 4 and a microwave generator 5, the waveguide tube 4 is provided on the wall of the microwave irradiating cavity 3, the microwave generator 5 is outside of the microwave irradiating cavity 3 and is connected to the waveguide tube 4, and emits microwave into the microwave irradiating cavity 3. If a plurality of waveguide tubes 4 are used, preferably the waveguide tubes 4 are evenly distributed on the inner wall of the microwave irradiating cavity 3. The waveguide tubes 4 can be provided on an inner wall of the microwave irradiating cavity or distributed on a plurality of inner walls.
On the microwave irradiating cavity, sealing devices 7 are provided at places where the parts of the chemical reactor penetrate the microwave irradiating cavity, for example, sealing devices are provided at the place where the tank 2 penetrates the microwave irradiating cavity 3. The sealing devices can be devices known to those skilled in the art for protection against microwave leakage, for example, they can be metal screens made of a microwave reflecting material (e.g., a metallic material), or they can be high-temperature microwave screening sealant. The metallic material can be stainless steel, aluminum, aluminum alloy, iron, copper, or silver, or preferably, stainless steel or aluminum alloy.
The microwave irradiating cavity 3 is made of a microwave reflecting material, or the inner wall of the microwave irradiating cavity is coated with a material layer which can reflect the microwave.
In the chemical reactor provided in the present invention, the upper part of the tank 2 is not closed, for example, a chemical reaction channel of which the upper part is open. The tank 2 can be in any shape, as long as the reactants can flow through it easily, for example, it can be in straight shape, spiral shape, or snake shape. Wherein, a straight tank is a tank with a straight axis, a spiral-shaped tank is a tank with a spiral-shaped axis, and a snake-shaped tank is a tank with a snake-shaped axis. The cross sectional shape of the tank should be helpful for guiding the flow of the reactants, for example, it can be U shape, arc shape, semi-circular shape, elliptical shape, or square shape. If the tank 2 is in straight shape or snake shape, it can be fixed horizontally or in an inclined manner, to adapt to the actual flow of the materials.
When the chemical reactor provided in the present invention is used for a vehement chemical reaction with high material splashing tendency, preferably a top cover that covers the tank at least partially can be provided on the top of the tank to protect against material splashing, which is to say, the top cover can cover the top part of the tank partially or entirely. The top cover that covers the top part of the tank partially can be in sieve shape or grating shape.
In the chemical reactor provided in the present invention, the tank 2 can be made of a totally microwave reflecting material or a totally microwave transmitting material; however, a totally microwave reflecting material is preferred. The totally microwave reflecting material can be the material described above, while the totally microwave transmitting material is known to those skilled in the art, such as polyimide or a material modified from polyimide, polyetheretherketone or a material modified from polyetheretherketone, polytetrafluoroethylene or a material modified from polytetrafluoroethylene, polyethylene or a material modified from polyethylene, polypropylene or a material modified from polypropylene, polyvinylbenzene or a material modified from polyvinylbenzene, and quartz or glass, etc. Polytetrafluoroethylene or a material modified from polytetrafluoroethylene, or polyvinylbenzene or a material modified from polyvinylbenzene is preferred. The top cover can be made of a totally microwave transmitting material described above.
In the chemical reactor provided in the present invention, preferably, the device for controlling the flow of the material comprises a device that can drive the material to flow.
The scrapers can be made of a totally microwave transmitting material or a totally microwave reflecting material, as described above. Preferably, the scrapers are made of a totally microwave transmitting material.
As shown in
Preferably, the first protuberances 20 can be plate pieces in any shape, with curved or flat surfaces; preferably the first protuberances 20 are distributed on the entire screw blade 15 at an even interval. Preferably, the one or more first protuberances 20 are vertically arranged on the surfaces of the screw blades 15. The one or more first protuberances 20 can be arranged on a single-screw driving mechanism or a multi-screw driving mechanism.
Preferably, the minimum radial distance from the first protuberances to the screw shaft is ⅕-⅘ of the radial distance from the outer edge of screw blade to the screw shaft, and the length of the first protuberances along the screw shaft is ⅕-⅘ of the screw pitch. Preferably, if a plurality of first protuberances are provided, the first protuberances are arranged at the same minimum radial distance to the screw shaft and are in the same length along the screw shaft; moreover, the first protuberances are arranged at the same interval between them. The interval is defined as the distance between two points on adjacent first protuberances that are the nearest to the screw shaft and at the same radial distance to the screw shaft.
The single-screw driving mechanism or multi-screw driving mechanism can be made of any totally microwave transmitting material or totally microwave reflecting material; the examples of totally microwave transmitting materials and totally microwave reflecting materials have described above. A totally microwave transmitting material is preferred.
In the chemical reactor provided in the present invention, preferably, the device for controlling the flow of the material further comprises a device for altering the flow state of the material; the device for altering the flow state of the material can be arranged separately, or arranged in combination with the first embodiment of the present invention. The device for altering the flow state of the material is a device that alters the material flow state from laminar state to turbulent state or enhances the turbulent state and thereby improves the mixing of the material, for example, the device can be a flow throttling device.
Preferably, the device for altering the flow state of the material can comprise second protuberances arranged in the tank. As shown in
Preferably, the device for altering the flow state of the material comprises a solid particle bed arranged in the tank or a plurality of solid particle beds arranged along the length of the tank, and the material can run through the solid particle bed(s). The one or more solid particle beds can be arranged separately or in combination with the second protuberances.
The solid particle bed(s) can be bed(s) obtained by loading solid particles into the space separated out by two porous barriers that are fixed in the tank and have pore size smaller than the particle size of the solid particles or obtained by fixing bags filled with the solid particles in the tank. The porous barriers or bags are inertial to the chemical reaction. The solid particle bed(s) can be used to improving the mixing of the reactants; the solid particles can be any natural or synthetic inorganic or organic solid particles that don't react with the reactants.
If the chemical reaction in the chemical reactor provided in the present invention is a chemical reaction that requires a catalyst, the solid particles can be solid catalyst particles. In that case, the solid catalyst particles can improve the mixing of the reactants and serve as a catalyst for the chemical reaction.
In the chemical reactor provided in the present invention, preferably, the second protuberances can be made of any totally microwave transmitting material or totally microwave reflecting material; the examples of totally microwave transmitting materials and totally microwave reflecting materials have been described above. Preferably, the second protuberances are made of a totally microwave transmitting material.
Preferably, the chemical reactor provided in the present invention further comprises a heat exchanger and a temperature measuring and controlling device.
The heat exchanger comprises a heat exchanger for material and/or a heat exchanger for microwave irradiating cavity, as shown in
Preferably, as shown in
Preferably, the sandwich layer is made of a totally microwave reflecting material. The heat transfer medium in the sandwich layer and the heat exchanger can be any heat transfer medium known to those skilled in the art, such as compressed gas, kerosene, hexane, benzene, glycerol, or water, etc.
Preferably, the temperature measuring and controlling device comprises a controller, a material temperature measuring device and/or a microwave irradiating cavity temperature measuring device.
The controller receives the signal of material temperature measured by the material temperature measuring device, and controls the flow rate of the heat transfer medium in the sandwich layer according to the temperature of the heat transfer medium and the measured material temperature; and/or receives the signal of temperature in the microwave irradiating cavity measured by the microwave irradiating cavity temperature measuring device, and controls the gas flow rate in the gas exchanger according to the measured microwave irradiating cavity temperature and/or control the flow rate of the heat transfer medium in the heat exchanger according to the temperature of the heat transfer medium in the heat exchanger and the measured microwave irradiating cavity temperature. It is used to attain the purpose of controlling the temperature of reactants and/or the temperature in the microwave irradiating cavity appropriately. As for the selection of heat transfer medium in the sandwich layer and the temperature of the heat transfer medium, and the selection of heat transfer medium in the heat exchanger in the microwave irradiating cavity and the temperature of the heat transfer medium, those skilled in the art can select appropriate heat transfer medium and appropriate temperature of the heat transfer medium to control the temperature of the chemical reaction, according to the actual condition of heat released in the chemical reaction.
The material temperature measuring device and microwave irradiating cavity temperature measuring device can be any temperature measuring devices known to those skilled in the art, for example, the temperature measuring devices can be temperature sensors, such as infrared temperature sensors or thermal couple sensors. A plurality of temperature sensors for measuring the temperature of the material can be used, and arranged along the axial direction of the tank at an appropriate interval, for example, the temperature sensors can be arranged in the length direction of the tank at 100-500 cm interval, to measure the temperature of the material in the entire tank at different positions accurately.
The controller can be a single-chip or a PLC. It is used to control the flow rate of the heat transfer medium in the sandwich layer, according to the temperature measured by the temperature sensors.
If gaseous byproducts are produced in the chemical reaction of the reactants, the gasses can be exhausted timely through the gas exhaust device 6, and therefore the chemical reaction equilibrium can be further driven towards the product side, and the conversion rate of reactants and the yield rate of product can be further improved. If the gasses released from the chemical reaction are toxic or harmful gasses, they should be collected and treated to prevent environmental pollution. Therefore, preferably, the air exchanger further comprises a collecting unit 12 and a processing unit (not shown). In addition, to utilize the heat source rationally, preferably the air exchanger further comprises a heat exchanger to exchange heat with the exhausted gaseous byproducts and reuse the heat recovered from the exhausted gasses.
If the air exchanger is a gas intake device 11, gasses can be taken into the microwave irradiating cavity 3 through the device 11 for heat exchange, and thereby the temperature in the microwave irradiating cavity 3 can be regulated.
With the air exchanger, heat exchanger in the microwave irradiating cavity, and sandwich layer of the tank working together, the temperature of the chemical reaction and the temperature in the microwave irradiating cavity can be controlled more effectively, so that the temperature of the chemical reaction in the tank can be controlled effectively even after long-time continuous operation of the microwave irradiating cavity.
In the chemical reactor provided in the present invention, the microwave irradiating cavity and the tank can be in the plural respectively; and the tanks can be provided in series or in parallel in the microwave irradiating cavities.
If a plurality of tanks are used, the tanks can be arranged in parallel in the microwave irradiating cavity, so that the material can be distributed in the tanks if the material is in a large volume.
If the duration of chemical reaction of the reactants is long or the chemical reaction is a multi-stage reaction and different reactants have to be added in different stages of reaction, a plurality of microwave irradiating cavities can be used, and a plurality of feed inlets can be arranged; in addition, a plurality of tanks can be used and arranged in the microwave irradiating cavities respectively and communicate with each other in sequence. For example, the microwave irradiating cavities and tanks can be 2-10 in quantity. As shown in
The present invention further discloses the use of the chemical reactor provided in the present invention in chemical reactions. The chemical reactor can be used in chemical reactions of various reactants that required heating; especially, the advantages of the chemical reactor provided in the present invention will be more obvious when the chemical reactor is used for reactions in which volatile small-molecule substances (e.g., water, NH3, HCl, etc.) are produced in the process of reaction or materials having high viscosity, semi-solid phase, or high fouling tendency. For example, the chemical reactions can be additive reactions, polymerization reactions, or substitution reactions. Specifically, the substitution reactions can be esterification reactions, ester exchange reactions, etherification reactions, condensation reactions, hydrolytic reactions, and alkylation reactions, etc. In addition, the chemical reactor can also be applied in ring-cleavage reactions and ring-forming reactions, etc. When the chemical reactor provided in the present invention is used, the microwave frequency can be a frequency known to those skilled in the art, for example, 915 MHz and 2,450 MHz.
Hereunder the present invention will be detailed in specific examples; however, the present invention is not limited to these examples.
In this example, the chemical reactor shown in
The microwave irradiating cavity 3 is made of stainless steel, in size of 10 m×1.5 m×2 m; the tank 2 is made of stainless steel, with a square section, in 100 mm width and 300 mm height; the tank 2 is in a straight shape and provided in an inclined manner in the microwave irradiating cavity 3, in approx. 10 m total length; the elevation difference of the tank 2 between the inlet and the outlet in the microwave irradiating cavity 3 is 1 m; the sandwich layer 22 is in thickness of 20 mm and made of stainless steel, with 200 fin-shaped protuberances 23 arranged at 50 mm interval in it; the gas exhaust device 6 is a 200 W exhaust fan, and the opening of the gas exhaust device 6 on the microwave irradiating cavity 3 is a round opening in 500 mm radius. In addition, a single-chip controller and material temperature measuring devices are provided, wherein, the material temperature measuring devices are 4 infrared temperature sensors arranged on the upper part of the tank at the same interval.
The chemical reactor provided in the present invention is used for producing phytosterin acetate through an esterification reaction.
The reaction equation is as follows:
In this example, phytosterin, acetic anhydride, and pyridine (catalyst) are mixed at 1:14:12 in mole ratio, and the mixture is fed at a 5 L/min. flow rate into the chemical reactor; the reaction temperature is controlled with the controller and infrared temperature sensors at 85° C., the reactants are heated up under microwave irradiation at 2,450 MHz microwave frequency, and the reaction duration is 6 min. The product (phytosterin acetate) is collected in the product tank. The yield rate of the product is as high as 97.5%.
Phytosterin acetate is produced with the method described in example 1, with the difference lying in: the reactants are heated up by heating with a heating jacket, the reaction duration is 12 h, and the yield rate of the product is approx. 90%.
It is seen from the example 1 and the comparative example 1: in the process of reaction in example 1, microwave irradiation heating is utilized to increase the reaction rate; in addition, since the upper part of the tank for material flow is open and a gas exhaust device is employed to effectively exhaust the byproduct of reaction (acetic acid), the chemical reaction is driven towards the product side, and therefore the yield rate of product is improved.
In this example, the chemical reactor shown in
The chemical reactor provided in the present invention is used for producing phytosterin stearate through an esterification reaction.
The reaction equation is as follows:
In this example, phytosterin and stearic acid are mixed at 1:1.3 in mole ratio with catalyst (sodium hydrogen sulfate) and water-carrying agent (methyl benzene), the mixture is fed at 3 L/min. flow rate into the chemical reactor, the drive speed of the belt drive unit 9 is 17 mm/s, the mole ratio of sodium hydrogen sulfate to phytosterin is 0.01:1, and the mole ratio of methyl benzene to phytosterin is 1:2; the reaction temperature is controlled at 140° C. with the controller and infrared temperature sensors, the reactants are heated up under microwave irradiation at 2,450 MHz microwave frequency, and the reaction duration is 10 min.; the product (phytosterin stearate) obtained is phytosterin stearate, and the yield rate of the product is 97.5%.
Phytosterin stearate is produced with the method described in example 2, with the difference lying in: the reactants are heated up by heating with a heating jacket, the reaction duration is 10 h, and the yield rate of the product is approx. 90%.
It is seen from the example 2 and the comparative example 2: in the process of reaction in example 2, microwave irradiation heating is utilized to increase the reaction rate; in addition, since the upper part of the tank for material flow is open and a gas exhaust device is employed to effectively evaporate and exhaust the byproduct of reaction (water), the chemical reaction is driven towards the product side, and therefore the yield rate of product is improved.
In this example, the chemical reactor shown in
The above chemical reactor in the present invention is used for hydrolytic reaction of soybean protein.
In this example, soybean protein and water, and papain are mixed at 10:1 weight ratio, and the weight ratio of papain to soybean protein is 1/20; the mixture is fed at 4.4 L/min. flow rate into the chemical reactor. In view of the high concentration and viscosity of the material, a single-screw driving mechanism is used to drive the material to flow through the tank; the speed of the screw is set to 8 rpm. The reaction temperature is controlled at 55° C. with the controller and infrared temperature sensors, the reactants are heated up under microwave irradiation at 2,450 MHz microwave frequency; the reaction duration is 1 h; in the reaction, the soybean protein is hydrolyzed, and the content of amino acid is 0.55 g/L.
The hydrolytic reaction of soybean protein is carried out with the method described in example 3, with the difference lying in: the reactants are heated up by heating with a heating jacket; the reaction duration required to attain the same degree of hydrolysis (i.e., 0.55 g/L amino acid content) is 9 h.
It is seen from the example 3 and comparative example 3: in the process of reaction in example 3, the reaction rate can be increased under microwave heating, and the hydrolytic reaction can complete within a shorter duration. In the comparative example 3, it is difficult to keep the papain active in the long reaction duration; in contrast, the enzyme activity for catalysis can be ensured.
The chemical reactor in example 1 is used, with the difference lying in: the elevation difference of the tank 2 between the inlet and the outlet in the microwave irradiating cavity 3 is 120 mm, and 8 solid catalyst beds are arranged in the tank; the solid catalyst beds are in the same height as the tank, and are arranged at 50 mm interval; the solid catalyst beds are obtained by loading solid catalyst particles into a space separated out by two porous barriers that are arranged with 150 mm distance between them. The porous barriers are in a shape matching the cross section of the tank, and the pores of the porous barriers are in 2 mm size and distributed at 3 pores/cm2 intensity. The solid catalyst particles have 1.5 mm average particle diameter. The solid catalyst particles are active carbon particles charged with phosphotungstic acid at 20 wt. % charge rate.
The above chemical reactor in the present invention is used for condensed hydroformylation reaction catalyzed by heteropoly acids to synthesize pentaerythritol mono-aldehyde ketone.
In this example, N,N-dimethyl formamide is used as the solvent to prepare pentaerythritol solution at 20 wt. %. The pentaerythritol solution is fed at 3 L/min. flow rate into the chemical reactor and driven to flow through solid catalyst beds. Under the action of the catalyst, at 75° C. reaction temperature controlled by the controller and infrared temperature sensors, reduced hydroformylation reaction is carried out under irradiation heating at 2,450 MHz microwave frequency, for approx. 12 min. Pentaerythritol mono-aldehyde ketone is obtained as the product, and the yield rate of the product is approx. 73%.
Pentaerythritol mono-aldehyde ketone is synthesized with the method described in example 4, with the difference lying in: the reduced hydroformylation reaction catalyzed with heteropoly acids is carried out under heating with a heating jacket to synthesize pentaerythritol mono-aldehyde ketone; the duration required for the reaction is 10 h, and the yield of the product is 32%.
It is seen from the example 4 and comparative example 4: in the process of reaction in example 4, the reaction rate can be increased under microwave heating; especially, the strong acceleration effect of microwave heating is obvious in the heterogeneous catalyst reaction.
The chemical reactor in example 1 is used, with the difference lying in: the elevation difference of the tank 2 between the inlet and the outlet in the microwave irradiating cavity 3 is 120 mm.
The chemical reactor in the present invention is used for coupling reaction between 4-fluorobenzonitrile and sodium benzene sulphinate to synthesize cyanophenyl sulfone. The reaction equation is as follows:
In this example, 4-monofluorobenzene nitrile and sodium benzene sulphinate are mixed at 1:2 mole ratio with catalyst (potassium carbonate) and water (as solvent); the mixture is fed at 4 L/min. flow rate into the chemical reactor; the mole ratio of potassium carbonate to 4-monofluorobenzene nitrile is 1:20, and the weight ratio of water to 4-monofluorobenzene nitrile is 1:0.3; the reaction temperature is controlled at 90° C. with the controller and infrared temperature sensors, and the coupling reaction is carried out under irradiation heating at 2450 MHz microwave frequency for 8 min., to obtain the product-cyanophenyl sulfone. The yield rate of the product is 91%.
In contrast, the conventional method for producing cyanophenyl sulfone is: oxidize phenyl thioether with an oxidizer to obtain the product; common oxidizers include hydrogen peroxide, peroxoic acid, periodic acid, and chromium oxide, etc. With such a synthetic method, it is difficult to control the process of reaction, and the raw material aryl thioether itself is a material not available widely; therefore, with that method, the cost of industrial production is very high.
It is seen that the reaction rate of coupling reaction in this example can be increased under microwave heating; in addition, the reaction is easy to implement, and the raw materials required for the reaction are widely available. Therefore, the cost of industrial production is very low.
| Number | Date | Country | Kind |
|---|---|---|---|
| 200910088807.4 | Jul 2009 | CN | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/CN09/75159 | 11/26/2009 | WO | 00 | 4/9/2012 |
