Patent Description:
Helicobacter pylori (H. pylori), as a spiral-shaped bacterium with numerous unipolar flagella, was discovered in <NUM> by Barry J. Marshall and J. Robin Warren. pylori has been proved to be associated with gastritis, chronic gastroenteritis, gastric ulcer, duodenal ulcer, non-ulcer dyspepsia and some gastric cancers, and thus has attracted a lot of medical attention. Extensive researches have been conducted to investigate the relationship between H. pylori infection and gastrointestinal diseases over the past <NUM> years.

pylori is detected and identified mainly by rapid urease test, H. pylori antibody test, <NUM>C-urea (or <NUM>C-urea) breath test, pathological tissue section method, and culture, where the <NUM>C-urea (or <NUM>C-urea) breath test high the highest precision (<NUM>-<NUM>% or more). <NUM>C-urea is an essential raw material for the production of the <NUM>C-urea breath test kit, but it is still difficult to achieve the industrial preparation of <NUM>C-urea.

Generally, the urea is synthesized through the high-temperature and high-pressure reaction between carbon dioxide (CO<NUM>) and ammonia (NH<NUM>). Whereas, this synthesis route is not suitable for the <NUM>C-urea preparation due to the poor CO<NUM> conversion.

Chinese Patent Publication Application <CIT> discloses a <NUM>C-urea synthesis method. The reactor cooled through liquid nitrogen is filled with weighed methanol and sulfur, followed by liquefied <NUM>CO and NH<NUM>. The reaction vessel is closed and the temperature of the reaction vessel is set to <NUM>-<NUM>. The reactor is purged by helium to empty the air in the reactor.

Chinese Patent Publication Application <CIT> discloses a <NUM>C-urea synthesis method. The reaction kettle is purged with helium, and is charged with gas at ultralow temperature into the reaction kettle connected to the feed gas cylinder. The gas filing process can be operated continuously and automatically through a pressure difference between the reaction kettle and the fed gas cylinder. The liquid <NUM>CO and NH<NUM> together with sulfur reacts in the reaction kettle.

In view of the defects in the prior art, the present disclosure provides a highly-efficient and safe continuous-flow synthesis method of <NUM>C-urea. In this continuous-flow synthesis method route, <NUM>CO, sulphur (S) and NH<NUM> are reacted in methanol in a continuous-flow reactor under heating and pressurizing conditions to continuously prepare <NUM>C-urea, with <NUM>-<NUM>% <NUM>CO conversion rate, <NUM>-<NUM>%<NUM>C-urea yield and <NUM>% <NUM>C-urea purity. Therefore, the synthesis method provided herein has excellent product quality and high yield.

Technical solutions of the present disclosure are described as follows.

This application provides a continuous-flow synthesis method of <NUM>C-urea, comprising:.

In some embodiments, a molar ratio of the sulphur to NH<NUM> to <NUM>CO is (<NUM>-<NUM>):(<NUM>-<NUM>):<NUM>.

In some embodiments, the continuous-flow reactor is controlled to <NUM>-<NUM> MPa and <NUM>-<NUM>.

In some embodiments, in step (S2), a flow rate of the slurry is <NUM>-<NUM>/min; and a flow rate of the <NUM>CO is <NUM>-<NUM>/min.

In some embodiments, a residence time of the three-phase mixture in the continuous-flow reactor is <NUM>-<NUM>.

In some embodiments, in step (S4), the purification is performed through steps of:.

In some embodiments, a purity of the <NUM>C-urea after purification is <NUM>%.

In some embodiments, a <NUM>CO conversion rate is <NUM>-<NUM>%; and a <NUM>C-urea yield is <NUM>-<NUM>%.

In some embodiments, a heat exchange medium of the continuous-flow reactor is heat-conducting oil or a water-based heat-conducting medium; and the water-based heat-conducting medium is water, a <NUM>,<NUM>-ethanediol binary aqueous solution or a <NUM>,<NUM>-propanediol binary aqueous solution.

In some embodiments, the slurry is fed by a feed pump into the mixing unit; the <NUM>CO passes through a pressure reducing valve to enter the mixing unit, wherein a flow of the <NUM>CO is controlled by a flow controller; and the reaction product flowing out from the continuous-flow reactor enters the gas-liquid separator through a back pressure valve.

Compared to the prior art, this application has the following beneficial effects.

The drawings needed in the description of the embodiments of the disclosure or the prior art will be briefly described below to explain technical solutions of the embodiments of the present disclosure or the prior art more clearly. Obviously, presented in the accompany drawings are merely some embodiments of the present disclosure, and other drawings can be obtained by those skilled in the art based on the drawings provided herein without paying creative effort.

This figure is a flow chart of a continuous-flow synthesis method of <NUM>C-urea according to an embodiment of the present disclosure.

Implementation, features and advantages will be further illustrated below with reference to the accompany drawing and embodiments.

Technical solutions of the present disclosure will be clearly and completely described below with reference to the embodiments and accompanying drawings. Obviously, described below are merely some embodiments of this disclosure, and are not intended to limit the disclosure. Other embodiments obtained by those skilled in the art based on the embodiments provided herein without paying any creative effort should fall within the scope of the present disclosure.

Unless otherwise specified, the materials and reagents in the following embodiments are available commercially, and the experiments are performed by conventional methods. For the quantitative analysis, three replicates are performed, and the results are expressed as mean or mean ± standard deviation.

As used herein, the "and/or" includes three solutions, for example, "A and/or B" includes A, B and a combination thereof. Additionally, technical solutions of various embodiments can be combined on the premise that the combined technical solution can be implemented by those skilled in the art. When the combination of technical solutions is contradictory or cannot be implemented, such a combination does not exist, and does not fall within the scope of the present disclosure.

Described herein was a continuous-flow synthesis method of <NUM>C-urea, including steps of:.

By replacing a kettle reactor with the continuous-flow reactor, a reaction time of continuous-flow synthesis is reduced from hours to minutes, significantly developing the reaction rate. In addition, the raw materials react in the continuous-flow reactor, contributing to a full contact therebetween. Particularly, the continuous-flow synthesis method using the continuous-flow reactor does not require gas compression into the reactor as opposed to the traditional kettle reactor reaction, shorting a process time, and improving a reaction efficiency.

Since a gas-phase raw material in the continuous-flow synthesis method is <NUM>CO, the pressure in the continuous-flow reactor keeps constant during reaction and will not affect the reaction. To the contrary, regarding the reaction in the kettle reactor, <NUM>CO therein will be consumed constantly, therefore, it is difficult to maintain the initial pressure in the reactor at the later stage of the reaction, resulting in reaction rate decreases and affecting the reaction efficiency.

In an embodiment, a molar ratio of the sulphur to NH<NUM> to <NUM>CO is (<NUM>-<NUM>):(<NUM>-<NUM>):<NUM>.

In an embodiment, the continuous-flow reactor is controlled to <NUM>-<NUM> MPa and <NUM>-<NUM>.

In an embodiment, in step (S2), a flow rate of the slurry is <NUM>-<NUM>/min; and a flow rate of the <NUM>CO is <NUM>-<NUM>/min.

In an embodiment, a residence time of the three-phase mixture in the continuous-flow reactor is <NUM>-<NUM>.

By using the above-mentioned technology solutions, the reaction time will be greatly reduced compared with traditional kettle-reactor reaction.

In an embodiment, in step (S4), the purification is performed through the following steps.

The liquid phase is subjected to rotary evaporation in a rotary evaporator, dissolving with an alcohol or water, and vacuum filtration to collect a filtrate. Then the filtrate is dried to obtain the <NUM>C-urea.

In an embodiment, a purity of the <NUM>C-urea after purification is <NUM>%.

By using the above-mentioned technology solutions, the product yield is high.

In an embodiment, a <NUM>CO conversion rate is <NUM>-<NUM>%; and a <NUM>C-urea yield is <NUM>-<NUM>%.

In an embodiment, a heat exchange medium of the continuous-flow reactor is heat-conducting oil or a water-based heat-conducting medium; and the water-based heat-conducting medium is water, a <NUM>,<NUM>-ethanediol binary aqueous solution or a <NUM>,<NUM>-propanediol binary aqueous solution.

In an embodiment, the slurry is fed by a feed pump into the mixing unit; the <NUM>CO passes through a pressure reducing valve to enter the mixing unit, wherein a flow of the <NUM>CO is controlled by a flow controller; and the reaction product flowing out from the continuous-flow reactor enters the gas-liquid separator through a back pressure valve.

By using the above-mentioned technology solutions, the flow of the slurry and that of <NUM>CO can be precisely controlled, thereby precisely controlling a reaction process.

In an embodiment, the continuous-flow synthesis method further includes a step of gas leak detection. The <NUM>C-urea is synthesized in an operating room, which is kept in negative pressure by using an evacuating device. The evacuating device is communicated with an evacuating pipe. The operating room and the evacuating pipe are respectively provided with an ammonia sensing probe, a carbon monoxide sensing probe, and a hydrogen sulfide sensing probe. When levels of ammonia and/or carbon monoxide and/or hydrogen sulfide exceed a preset value, it indicates a possible gas leak. Since ammonia, carbon monoxide and hydrogen sulfide are hazardous to the health of operators, the system will give an alarm or a corresponding valve is immediately closed. The operators need to monitor and repair the pipe before continuing with the urea synthesis process.

The above-mentioned technology solutions can protect the operator from being damaged ammonia, carbon monoxide and hydrogen sulfide.

In summary, by means of the continuous-flow reactor, the continuous-flow synthesis method provided herein has novelty, simple operation, high product quality and yield, thereby leading to low cost and less pollution. By means of the continuous-flow reactor, the cost is greatly reduced. This application has simple operation, relatively mild reaction conditions, and relatively low pollution. The continuous-flow synthesis method provided herein effectively overcomes the defects of existing reactions that cannot be produced on a larger scale, facilitating large-scale production and improving quality and yield of the <NUM>C-urea.

(S1) <NUM> of sulphur, <NUM> of a methanol solution containing <NUM> mol/L of NH<NUM> and <NUM> of methanol were fed into a feed kettle, and then mixed to obtain a slurry.

(S2) The slurry was fed by a feed pump into a mixing unit, to which <NUM>CO was fed after passing through a pressure reducing valve, so as to obtain a three-phase mixture, where a flow rate of the <NUM>CO was controlled at <NUM>/min by a flow controller, and a flow rate of the slurry was <NUM>/min.

(S3) The three-phase mixture was mixed evenly in the mixing unit, fed into a continuous-flow reactor, and reacted at <NUM> and <NUM> MPa for <NUM> to obtain a reaction product.

(S4) The reaction product was cooled by a cooling coil in an ice-water bath, and then flowed out of the continuous-flow reactor as a brown liquid to enter a gas-liquid separator for separation. A liquid phase was collected as a crude product solution, and subjected to rotary evaporation in a rotary evaporator, dissolving with water and vacuum filtration to collect a filtrate. The filtrate was dried to obtain <NUM>C-urea. The gas phase generated from the gas-liquid separation was discharged and absorbed with a NaOH solution.

Examples <NUM>-<NUM> were performed according to the steps of Example <NUM>. The amounts of raw materials and the reaction parameters of Examples <NUM>-<NUM> were shown in Table <NUM>.

Comparative Examples <NUM>-<NUM> were performed basically according to the steps of Example <NUM>.

Regarding Comparative Example <NUM>, a slurry obtained in step (S1) and <NUM>CO were directly fed into the continuous-flow reactor for reaction.

Regarding Comparative Example <NUM>, it was free from addition of <NUM> of methanol in step (S1).

<NUM>C-urea yields and <NUM>CO conversion rates of Comparative Examples <NUM>-<NUM> are shown in Table <NUM>.

Technical solutions of various embodiments can be combined on the premise that the combined technical solution can be implemented by those skilled in the art. When the combination of technical solutions is contradictory or cannot be implemented, such a combination does not exist, and does not fall within the scope of the present disclosure.

Claim 1:
A continuous-flow synthesis method of <NUM>C-urea, comprising:
(S1) mixing sulphur and a methanol solution containing NH<NUM> in a feed kettle to obtain a slurry; or mixing ammonia gas (NH<NUM>), sulphur and methanol in a feed kettle to obtain a slurry;
(S2) feeding the slurry into a mixing unit; and feeding <NUM>CO into the mixing unit to obtain a three-phase mixture;
(S3) mixing the three-phase mixture in the mixing unit evenly; and feeding the three-phase mixture into a continuous-flow reactor for reaction to obtain a reaction product; and
(S4) feeding the reaction product into a gas-liquid separator for gas-liquid separation, and collecting a liquid phase; subjecting the liquid phase to purification to obtain the <NUM>C-urea.