CN212790922U - Methyl benzoic acid's continuous nitration system - Google Patents

Abstract

The utility model provides a continuous nitration system of methyl benzoic acid, which utilizes a continuous reaction system to realize the continuous nitration reaction of methyl benzoic acid, on one hand, the energy utilization rate is higher because the reaction volume is reduced and the heat exchange efficiency is improved; on the other hand, the dilute phase liquid separated by the reaction liquid thickener is added into the continuous nitration reactor, so that the cold energy of the dilute phase liquid is fully utilized while the nitric acid is fully utilized, the working load of a refrigerant system is greatly reduced, and the energy waste is reduced while the consumption of the nitric acid is reduced.

Description

Methyl benzoic acid's continuous nitration system

Technical Field

The utility model belongs to the technical field of the chemical industry, especially, relate to a methyl benzoic acid's continuous nitration reaction system.

Background

The methyl benzoic acid has three isomers, namely m-methyl benzoic acid, o-methyl benzoic acid and p-methyl benzoic acid. The nitrated product obtained by the m-toluic acid after the nitration reaction has three isomers which are 2-nitro-3-toluic acid, 3-methyl-4-nitrobenzoic acid and 2-nitro-5-toluic acid respectively, and the three isomeric products are important intermediates in the field of medical and agricultural chemicals, wherein the 2-nitro-3-toluic acid is a key intermediate for synthesizing chlorantraniliprole, cyantraniliprole and other high-efficiency low-toxicity pesticides, the 3-methyl-4-nitrobenzoic acid is an important intermediate for synthesizing telmisartan and other medicines, and the 2-nitro-5-toluic acid is a core starting material for synthesizing pyrimidine anticancer drugs such as raltitrexed and other medicines.

The nitrated product of the nitrated p-methyl benzoic acid is 3-nitro-4-methyl benzoic acid, and downstream products taking the 3-nitro-4-methyl benzoic acid as a raw material comprise an anti-tumor drug nilotinib, a leukemia treatment drug pratinib and the like.

The nitrated product obtained after the nitration of the o-methylbenzoic acid has two isomers, namely 2-methyl-3-nitrobenzoic acid and 2-methyl-5-nitrobenzoic acid, wherein the 2-methyl-3-nitrobenzoic acid is an important intermediate of pesticide methoxyfenozide, and the 2-methyl-5-nitrobenzoic acid is an important intermediate of a drug for treating diabetes, namely canagliflozin.

The prior nitrated product of methyl benzoic acid is produced by adopting an intermittent kettle. According to the reaction mechanism of the methyl benzoic acid nitration, under the condition that the reaction temperature and the concentration of acid are both high, the reaction rate is relatively high, the heat released by the reaction is relatively large, if the heat generated in the reaction process cannot be removed in time, the reaction temperature can be further increased, so that the nitration reaction rate is further accelerated, more reaction heat is released, a vicious circle is formed, and finally, a polynitrogen compound with extremely high explosion risk is generated, even serious safety accidents are caused. Therefore, in the initial stage of the reaction, if the concentration of the acid is higher, the lower reaction temperature needs to be controlled, the requirements on the heat exchange area of the reaction equipment and the flow rate of the refrigerant in a refrigerant system are higher, otherwise, the reaction is easy to lose control, materials are scrapped if the reaction is light, and safety accidents occur if the reaction is heavy. In order to solve the problem, nitric acid adopts a dropwise adding mode or a slow charging mode is adopted for methylbenzoic acid in the intermittent kettle type production process, and the reaction kettle can increase the heat exchange area by additionally arranging a heat exchange structure so as to ensure that the heat generated by the nitration reaction of the methylbenzoic acid can be removed in time under the condition of large refrigerant flow, and the effect of benign control is achieved, so that the intermittent kettle type process is complex in operation, high in energy consumption and low in production efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a methyl benzoic acid's continuous nitration reaction system, the utility model provides a system is simple, energy-conserving high-efficient, and production efficiency is high.

The utility model provides a continuous nitration system of methyl benzoic acid, which comprises a continuous nitration reactor,

the outlet of the solid continuous feeding system is communicated with the solid feeding hole of the continuous nitration reactor;

the outlet of the liquid continuous feeding system is communicated with the inlet of a liquid raw material cooler, and the outlet of the liquid raw material cooler is communicated with the liquid feeding hole of the continuous nitration reactor;

the material inlet of the reaction liquid thickener is communicated with the discharge hole of the continuous nitration reactor, the clear liquid outlet of the reaction liquid thickener is communicated with the inlet of a circulating liquid condenser, the outlet of the circulating liquid condenser is communicated with a circulating liquid feed inlet of the continuous nitration reactor, and the circulating liquid feed inlet is arranged at one end of the continuous nitration reactor, which is far away from the discharge hole;

and a refrigerant outlet of the refrigerant system is communicated with a refrigerant inlet of the continuous nitration reactor, and a refrigerant return port of the refrigerant system is communicated with a refrigerant outlet of the continuous nitration reactor.

Preferably, the continuous nitration reactor is a tubular reactor, a continuous kettle type reactor or a tubular reactor and a continuous kettle type reactor which are connected in series.

Preferably, when the continuous nitration reactor is a tubular reactor, the solid feed inlet is arranged at the inlet end of the tubular reactor, the liquid feed inlet is arranged at the inlet end and/or the middle of the tubular reactor, and the circulating liquid feed inlet is arranged at the inlet end of the tubular reactor.

Preferably, when the continuous nitration reactor is a continuous kettle type reactor, the solid feed inlet is arranged at the top of the continuous kettle type reactor, the liquid feed inlet is arranged at the top of the continuous kettle type reactor, and the circulating liquid feed inlet is arranged at the top or the bottom of the continuous kettle type reactor.

Preferably, when the continuous nitration reactor is a continuous kettle type reactor and a tubular reactor which are sequentially connected in series, the solid feed inlet is arranged at the top of the continuous kettle type reactor, the liquid feed inlet is arranged at the inlet end of the tubular reactor, and the circulating liquid feed inlet is arranged at the top of the continuous kettle type reactor.

Preferably, the inlet end of the tubular reactor is one tenth of the area of the inlet end of the tubular reactor.

Preferably, the middle of the tubular reactor is one third to two thirds of the area of the tubular reactor.

Preferably, a stirring and mixing device and/or an insert structure are/is arranged in the continuous nitration reactor.

Preferably, the continuous nitration reactor is provided with a built-in heat removal structure and/or heat removal by means of a device jacket.

Preferably, when the continuous nitration reactor comprises a continuous kettle type reactor, the position of a material outlet of the continuous kettle type reactor is an overflow port, and the height of the overflow port is 1/2-4/5 away from the bottom of the reactor.

The utility model provides a continuous nitration system of methyl benzoic acid, which comprises a continuous nitration reactor and a solid continuous feeding system, wherein the outlet of the solid continuous feeding system is communicated with a solid feeding hole of the continuous nitration reactor; the outlet of the liquid continuous feeding system is communicated with the inlet of a liquid raw material cooler, and the outlet of the liquid raw material cooler is communicated with the liquid feeding hole of the continuous nitration reactor; a material inlet of the reaction liquid thickener is communicated with a discharge hole of the continuous nitration reactor, a clear liquid outlet of the reaction liquid thickener is communicated with an inlet of a circulating liquid condenser, and an outlet of the circulating liquid condenser is communicated with a circulating liquid feed hole of the continuous nitration reactor; and a refrigerant outlet of the refrigerant system is communicated with a refrigerant inlet of the continuous nitration reactor, and a refrigerant return port of the refrigerant system is communicated with a refrigerant outlet of the continuous nitration reactor. The utility model realizes the continuous nitration reaction of methyl benzoic acid by using the continuous reaction system, on one hand, the reaction volume is reduced, the heat exchange efficiency is improved, and the energy utilization rate is higher; on the other hand, the dilute phase liquid separated by the reaction liquid thickener is added into the continuous nitration reactor, so that the cold energy of the dilute phase liquid is fully utilized while the nitric acid is fully utilized, the working load of a refrigerant system is greatly reduced, and the energy waste is reduced while the consumption of the nitric acid is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

FIG. 1 is a schematic structural diagram of the continuous nitration system of methyl benzoic acid of the present invention;

wherein, 1 is a continuous nitration reactor, 2 is a solid continuous feeding system, 3 is a liquid continuous feeding system, 4 is a liquid raw material cooler, 5 is a reaction liquid thickener, 6 is a circulating liquid condenser, and 7 is a refrigerant system.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a continuous nitration system of methyl benzoic acid, which comprises a continuous nitration reactor,

the outlet of the solid continuous feeding system is communicated with the solid feeding hole of the continuous nitration reactor;

the outlet of the liquid continuous feeding system is communicated with the inlet of a liquid raw material cooler, and the outlet of the liquid raw material cooler is communicated with the liquid feeding hole of the continuous nitration reactor;

a material inlet of the reaction liquid thickener is communicated with a discharge hole of the continuous nitration reactor, a clear liquid outlet of the reaction liquid thickener is communicated with an inlet of a circulating liquid condenser, and an outlet of the circulating liquid condenser is communicated with a circulating liquid feed hole of the continuous nitration reactor;

a refrigerant outlet of the refrigerant system is communicated with a refrigerant inlet of the continuous nitration reactor, and a refrigerant return port of the refrigerant system is communicated with a refrigerant outlet of the continuous nitration reactor;

the continuous nitration reactor is a tubular reactor, a continuous kettle type reactor or a tubular reactor and a continuous kettle type reactor which are connected in series; and a stirring and mixing device is arranged in the continuous nitration reactor.

As shown in figure 1, the utility model provides a methyl benzoic acid's continuous nitration system includes continuous nitration reactor 1, solid continuous feed system 2, liquid continuous feed system 3, liquid raw material cooler 4, reaction liquid thickener 5, circulating liquid condenser 6 and refrigerant system 7 constitution.

The continuous nitration reactor is provided with at least one solid feed inlet for continuous input solid raw material methylbenzoic acid, still is provided with at least one liquid feed inlet, preferably 2 liquid feed inlets for continuous input liquid raw material nitric acid, still is provided with at least one circulating liquid feed inlet for in the reaction mixed liquid in the continuous nitration reactor is added to the dilute phase liquid that will nitrify the reaction liquid separation, still is provided with the discharge gate, is used for continuous output nitration liquid.

The outlet of the solid continuous feeding system 2 is communicated with the solid feeding hole of the continuous nitration reactor 1, the outlet of the liquid continuous feeding system 3 is connected with the material inlet of the liquid cooler 4, the material outlet of the liquid cooler 4 is communicated with the liquid feeding hole of the continuous nitration reactor 1, the discharge hole of the continuous nitration reactor 1 is connected with the inlet of the reaction liquid thickener 5, the clear liquid outlet of the reaction liquid thickener 5 is connected with the material inlet of the circulating liquid condenser 6, the material outlet of the circulating liquid condenser 6 is communicated with the circulating liquid feeding hole of the continuous nitration reactor 1, the refrigerant outlet of the refrigerant system 7 is connected with the refrigerant inlet of the continuous nitration reactor 1, and the refrigerant return opening of the refrigerant system 7 is connected with the refrigerant outlet of the continuous nitration reactor 1.

The utility model discloses in, among the continuous nitration reaction system of methyl benzoic acid continuous nitration reactor, the continuous charging system of solid, the continuous charging system of liquid, liquid raw material cooler, reaction liquid thickener, circulating liquid condenser and refrigerant system all are connected with automatic control system, adopt automatic operation.

The utility model discloses in, the continuous charging system of solid comprises feed bin, baiting valve, counter, material propeller, and automatic control system is all connected with the baiting valve to the counter, and automatic control system is fed back to the numerical value of counter, and automatic control system regulates and control the quality of the solid that gets into continuous nitration ware through the counter through the aperture of regulation and control baiting valve.

The present invention relates to a combined reactor, and more particularly, to a combined reactor, which is preferably a tubular reactor, a continuous tank reactor or a tubular reactor and a continuous tank reactor, and is formed by connecting in series, and in an embodiment of the present invention, the combined reactor may be a tubular reactor, two continuous tank reactors connected in series, a tubular reactor and a continuous tank reactor connected in series, or a continuous tank reactor and a tubular reactor connected in series. On this basis, it is also within the scope of the invention to use more complex series or parallel combinations.

In the utility model, the continuous nitration reactor is provided with a built-in heat transfer structure and/or transfers heat through an equipment jacket.

In the present invention, the volume of the continuous nitrification reactor is preferably 15 to 200L, more preferably 30 to 180L, most preferably 50 to 150L, most preferably 100L.

In the present invention, the inside of the continuous nitrification reactor is provided with a stirring and mixing device for mixing the raw materials, the stirring and mixing device comprises a stirring device and/or an insert structure, and may be other material mixing structures known to those skilled in the art, such as a fixed mixing unit or some turbulent flow structures. The stirring device is preferably a spiral stirring structure with a pushing effect, a rod-shaped stirring structure, a stirring sheet matched heat exchange tube stirring structure or an inserting sheet mixing structure, and more preferably is a spiral stirring structure with a pushing effect. The stirring speed is preferably 100-500 r/min, more preferably 200-400 r/min, most preferably 300-350 r/min, and specifically, in the embodiment of the present invention, the stirring speed may be 300r/min, 350r/min, or 500 r/min. The present invention is not limited to the specific structure of the insert structure, and may be an insert commonly used by those skilled in the art.

When the continuous nitration reactor is a tubular reactor, the solid feed inlet is arranged at the inlet end of the tubular reactor, the liquid feed inlet is arranged at the inlet end and/or the middle of the tubular reactor, and the circulating liquid feed inlet is arranged at the inlet end of the tubular reactor;

when the continuous nitration reactor is a continuous kettle type reactor, the solid feed port, the liquid feed port and the circulating liquid feed port can be arranged at any position of the continuous kettle type reactor, preferably, the solid feed port is arranged at the top of the continuous kettle type reactor, the liquid feed port is arranged at the top of the continuous kettle type reactor, and the circulating liquid feed port is arranged at the top or the bottom of the continuous kettle type reactor; preferably, when the continuous nitration reactor is two continuous kettle type reactors connected in series, the liquid feed inlet, the solid feed inlet and the circulating liquid feed inlet are correspondingly arranged at corresponding positions of the first continuous kettle type reactor, and the bottom of the second continuous kettle type reactor is communicated with the reaction liquid thickener.

When the continuous nitration reactor is the continuous kettle type reactor and the tubular reactor which are connected in series in sequence, the inlet (such as a solid feed inlet, a liquid feed inlet or a circulating liquid feed inlet) arranged on the continuous kettle type reactor can be arranged at any position of the continuous kettle type reactor, preferably, the solid feed inlet is arranged at the top of the continuous kettle type reactor, the liquid feed inlet is arranged at the inlet end of the tubular reactor, and the circulating liquid feed inlet is arranged at the top of the continuous kettle type reactor.

When the continuous nitration reactor is a tubular reactor and a continuous kettle type reactor which are sequentially connected in series, the solid feed inlet, the liquid feed inlet and the circulating liquid feed inlet can be arranged at the inlet end of the tubular reactor.

In the present invention, the first continuous tank reactor, the second continuous tank reactor and the successive reactors are distinguished according to the direction of the material flow, the material is firstly called as "first", and then enters as "second", and so on. For example, "a continuous tank reactor and a tubular reactor connected in series" means that the raw material enters the continuous tank reactor first and then enters the tubular reactor.

In the utility model, the raw material enters from one end of the tubular reactor, the other end is the end provided with the discharge port for outputting, the end where the raw material enters can be called as the front section, the end of the discharge port is called as the rear end, and the inlet end of the tubular reactor refers to the area one tenth of the front end where the raw material enters; the middle of the tubular reactor refers to one-third to two-thirds of the area of the tubular reactor.

The utility model discloses in, work as when continuous nitration reactor includes continuous kettle type reactor, when two continuous kettle type reactors establish ties, tubular reactor and continuous kettle type reactor use in series, the material exit position can be for the optional position that is not higher than liquid level in the reactor, and more preferred material exit position is the overflow mouth, and the overflow mouth height is for locating apart from reactor bottom 1/2 ~ 4/5.

It is generally considered by those skilled in the art that when nitric acid is used as a nitrating reagent for the nitration of methyl benzoic acid, the higher the concentration of nitric acid, the more beneficial it is to obtaining a mono-nitrated product by the nitration of methyl benzoic acid, and the concentration of nitric acid in the dilute phase liquid separated from the nitration liquid becomes smaller due to the generation of water during the nitration of methyl benzoic acid, so that those skilled in the art cannot easily think of recycling the separated dilute phase liquid, and the cold energy of the dilute phase liquid is wasted. The utility model discloses a set up the thickener in methyl benzoic acid's continuous nitration reaction system, will nitrify the dilute phase liquid separation in the reaction liquid ingeniously, the principal ingredients of dilute phase liquid is the nitric acid, this part dilute phase liquid temperature itself is lower, get into continuous nitration reactor after the precooling, can make full use of nitrify the cold volume of the dilute phase liquid that the reaction liquid separates out, great range reduces refrigerant system's work load, it is extravagant to reduce the energy when reducing the nitric acid quantity.

Further, the utility model discloses well reaction liquid thickener separates out the dilute phase liquid after, through automatic control system regulation, make dilute phase liquid and raw materials methyl benzoic acid contact reaction earlier, be about the circulation liquid feed inlet sets up the one end of keeping away from the discharge gate at continuous nitration reactor, because the concentration of nitric acid is lower in the dilute phase liquid, reaction rate slows down, avoid local overheat's phenomenon, because along with the emergence of nitration, generate water in the reaction process, make the concentration of nitric acid reduce in the dilute phase liquid, be not enough to maintain and last quick reaction, consequently through being different from front end (being the entry end) position at continuous nitration reactor, like the higher nitric acid of the import of a department or many import addition concentration of intermediate position, reach the effect that the nitration reaction of making methyl benzoic acid lasts and go on fast. Therefore, the continuous nitration reaction system of the methyl benzoic acid and the nitration method thereof not only can reduce the workload of a refrigerant system and reduce the energy consumption, but also ensure that the nitration reaction of the methyl benzoic acid is continuously and rapidly carried out and improve the production efficiency by adjusting different feeding positions of liquid materials and the flow rate of each strand of material.

The utility model discloses in, liquid continuous feeding system 3, liquid raw material cooler 4, reaction liquid thickener 5, circulating liquid condenser 6 and refrigerant system 7 are cooling device, feeding device and reaction liquid thickener commonly used in the field, the utility model discloses do not specially limit to its model specification etc..

The utility model also provides a methyl benzoic acid's continuous nitration technology, use the above continuous nitration system, including following step:

A) continuously conveying methyl benzoic acid into a continuous nitration reactor through a solid continuous feeding system, and continuously precooling nitric acid by a liquid raw material cooler through a liquid continuous feeding system and then adding the nitric acid into the continuous nitration reactor;

B) the methyl benzoic acid and nitric acid are contacted in the continuous nitration reactor to carry out continuous nitration reaction, and the obtained nitration reaction liquid is conveyed to the reaction liquid thickener from a discharge hole;

C) and the dilute phase liquid separated by the reaction liquid thickener is cooled by a circulating liquid condenser and then is conveyed into a continuous nitration reactor, and the thick phase slurry enters a subsequent treatment unit for separation to obtain a nitration product of the methyl benzoic acid.

The target product of the nitration reaction of the methyl benzoic acid is the methyl benzoic acid product which only contains one nitro on the benzene ring.

The nitration product obtained by the nitration reaction of m-toluic acid has three isomers which are respectively 2-nitro-3-toluic acid, 3-methyl-4-nitrobenzoic acid and 2-nitro-5-toluic acid;

the nitrated product of the nitrated p-toluic acid is 3-nitro-4-toluic acid;

the nitrated product obtained after the nitration of the o-methylbenzoic acid has two isomers, namely 2-methyl-3-nitrobenzoic acid and 2-methyl-5-nitrobenzoic acid.

The device that the continuous nitrification process used in the utility model is the above continuous nitrification system to the commodity circulation trend of raw materials is as the benchmark, and concrete process flow is as follows:

continuously conveying methyl benzoic acid into a continuous nitration reactor through a solid continuous feeding system, conveying nitric acid from the liquid continuous feeding system to continuously flow through a liquid raw material cooler for precooling, and then adding the nitric acid into the continuous nitration reactor, wherein the methyl benzoic acid and the nitric acid are subjected to a continuous nitration reaction in the continuous nitration reactor, a certain reaction temperature is controlled, and a nitration reaction liquid is obtained after a certain retention time; after the nitration reaction liquid is thickened by the reaction liquid thickener, dilute phase liquid is output from a dilute phase liquid outlet of the reaction liquid thickener, cooled by a circulating liquid condenser and then added into the continuous nitration reactor, and thick phase slurry enters a subsequent processing unit to obtain a nitration product. The continuous nitration reaction system of the methyl benzoic acid removes heat generated in the nitration reaction process of the methyl benzoic acid and nitric acid in time through a refrigerant system, and an automatic control system controls the temperature of a reaction liquid by controlling the temperature of the refrigerant and the temperature of a flow.

The methyl benzoic acid continuous nitration reaction system can experience a short regulation period from start-up to continuous stable production, the whole regulation period is regulated and controlled by an automatic control system, a flow meter and a continuous feedback regulating valve are connected at a circulating liquid feed inlet of the continuous nitration reactor, when the automatic control system receives a signal that dilute phase liquid flowing through a circulating liquid condenser enters the continuous nitration reactor, the feeding position of liquid raw material nitric acid and the feeding amount of each feeding position can be regulated and controlled, and the amount of the dilute phase liquid separated by a reaction liquid thickener, the feeding position of the dilute phase liquid and the feeding amount of each feeding position can be regulated and controlled, and a stable state is achieved.

In the present invention, the methyl benzoic acid is preferably m-methyl benzoic acid, o-methyl benzoic acid or p-methyl benzoic acid; the mass ratio of the nitric acid to the methylbenzoic acid is preferably (2-5): 1, more preferably (2.5 to 4.5): 1, most preferably (3-4): 1, specifically, in the embodiment of the present invention, may be 2: 1. 3: 1. 5: 1. 3.5:1 or 4: 1. in the present invention, the concentration of the nitric acid is preferably equal to or greater than 80%, more preferably equal to or greater than 85%, most preferably equal to or greater than 90%, and specifically, in the embodiments of the present invention, may be 92%, 95%, 96% or 98%.

In the utility model discloses in, methyl benzoic acid's feed rate is preferably 109 ~ 333kg/h, more preferably 140 ~ 300kg/h, and is specific, in the embodiment of the utility model, can be 150kg/h, 160kg/h, 140kg/h, 171kg/h, 115.6kg/h, 144kg/h or 134.4 kg/h.

In the present invention, the temperature of the continuous nitration reaction is preferably-25 to 0 ℃, more preferably-20 to-5 ℃, and most preferably-15 to-10 ℃, and specifically, in the embodiment of the present invention, may be-15 ℃, -12 ℃, -10 ℃, -25 ℃, -20 ℃, or-5 ℃. In the present invention, the time of the continuous nitration reaction is preferably 1-30 min, more preferably 5-25 min, more preferably 10-20 min, and specifically, in the embodiment of the present invention, may be 3min, 4min, 5min, 5.5min, 6min, 6.5min, 7.5min, 8min, 8.5min, 9min, 10min, 11min, 12min, 13min, 15min, 19min, 7min, 30min, 20min or 25 min.

In the present invention, the temperature of the nitric acid pre-cooling is preferably lower than the temperature of the continuous nitration by 5 to 30 ℃, more preferably lower than 8 to 25 ℃, most preferably lower than 10 to 20 ℃, specifically, in the embodiment of the present invention, the reaction temperature may be-15 ℃, and the nitric acid pre-cooling may be lower than the reaction temperature by 10 ℃, that is, -25 ℃; the reaction temperature is-12 ℃, and the nitric acid is pre-cooled to 18 ℃ lower than the reaction temperature, namely-30 ℃; the reaction temperature is-10 ℃, and the nitric acid is pre-cooled to 20 ℃ lower than the reaction temperature, namely-30 ℃; the reaction temperature is-25 ℃, and the nitric acid is pre-cooled to 5 ℃ lower than the reaction temperature, namely-30 ℃; the reaction temperature is-10 ℃, and the nitric acid is pre-cooled to be 15 ℃ lower than the reaction temperature, namely-25 ℃.

In the present invention, the temperature of the dilute phase liquid is 5 to 30 ℃ lower than the temperature of the continuous nitration, more preferably 8 to 25 ℃ lower, most preferably 10 to 20 ℃ lower, and specifically, in the embodiment of the present invention, the reaction temperature may be-15 ℃, and the dilute phase liquid is cooled to 10 ℃ lower than the reaction temperature, i.e., -25 ℃; the reaction temperature is-12 ℃, and the dilute phase liquid is cooled to be 10 ℃ lower than the reaction temperature, namely-22 ℃; the reaction temperature is-10 ℃, and the dilute phase liquid is cooled to 10 ℃ lower than the reaction temperature, namely-20 ℃; the reaction temperature is-15 ℃, and the dilute phase liquid is cooled to be 5 ℃ lower than the reaction temperature, namely-20 ℃; the reaction temperature is-25 ℃, and the dilute phase liquid is cooled to be 5 ℃ lower than the reaction temperature, namely-30 ℃.

In the present invention, the dilute phase liquid accounts for 20-70% of the mass of the reaction mixture in the continuous nitrification reactor, more preferably 30-60%, most preferably 40-50%, and specifically, in the embodiment of the present invention, it can be 20%, 30%, 35%, 40%, 50%, 60% or 70%.

In the utility model discloses in, continuous nitration carries out under the condition of stirring, the speed of stirring is preferably 100 ~ 500r/min, more preferably 200 ~ 400r/min, most preferably 300 ~ 350r/min, and is specific, in the embodiment of the utility model, can be 300r/min, 350r/min, 500 r/min.

According to the reaction mechanism of the methyl benzoic acid nitration, the nitration reaction rate is accelerated under the conditions of increasing the reaction temperature and increasing the concentration or dosage of the acid, but the multi-nitration reaction is easy to occur at higher temperature and higher concentration and dosage of the acid, and the faster the nitration reaction rate is, the more difficult the reaction is to control.

Taking m-toluic acid as an example, the proportion of three isomers of m-toluic acid mononitration product can change along with the change of process conditions, and is most obvious along with the change of reaction temperature, the utility model discloses an adjust process conditions, obtain the product of different proportions. For example, the lower the reaction temperature, the higher the ratio of 2-nitro-3-methylbenzoic acid, the higher the reaction temperature, and the higher the ratio of 3-methyl-4-nitrobenzoic acid to 2-nitro-5-methylbenzoic acid. Therefore, when more 2-nitro-3-methylbenzoic acid is obtained from the three isomer products, the temperature can be reduced, and meanwhile, the higher concentration and proportion of acid are adopted, so that the higher reaction rate is ensured; when 3-methyl-4-nitrobenzoic acid and 2-nitro-5-methylbenzoic acid are obtained in more of three isomer products, the temperature can be raised, and meanwhile, the higher reaction rate is ensured and the safety and controllability of production are ensured by adopting lower acid concentration and proportion.

The utility model discloses the people discovers through a large amount of researches that the technological condition is: the concentration of nitric acid is not lower than 80%, the mass ratio of nitric acid to methylbenzoic acid is 2-5: 1, the reaction temperature is-25-0 ℃, a liquid raw material nitric acid is precooled to a liquid state which is 5-30 ℃ lower than the reaction temperature before being added into a continuous nitration reactor, a dilute phase liquid is precooled to a liquid state which is 5-30 ℃ lower than the reaction temperature before being added into the continuous nitration reactor, the dilute phase liquid entering the continuous nitration reactor accounts for 20-70% of the mass fraction of the nitration reaction liquid, and the retention time of the raw material methylbenzoic acid in the continuous nitration reactor is 1-30 min.

Through the research, utility model people discover that the concentration of acid is low on the one hand, and the methyl benzoic acid is slower with the reaction of nitric acid, and production efficiency is low, the utility model discloses an acid concentration be not less than 80%.

Through research, the utility model people find that the mass ratio of the nitric acid to the methyl benzoic acid is larger, the methyl benzoic acid and the nitric acid are easy to generate polynitro compounds after reaction, the waste of the nitric acid is caused, and the after-treatment burden is increased; the mass ratio of nitric acid to methyl benzoic acid is smaller, the reaction of methyl benzoic acid and nitric acid is slower, the production efficiency is low, and the mass ratio of nitric acid to methyl benzoic acid is 2-5: 1.

Through research, the utility model people find that the reaction temperature is higher, the methyl benzoic acid reacts with nitric acid faster, the reaction releases heat quickly, and the phenomenon of untimely heat transfer is easy to occur, and meanwhile, the methyl benzoic acid reacts with the nitric acid to generate polynitro compounds; the reaction temperature is low, the content of the polynitro compound can be effectively controlled, but the lower the temperature of the reaction liquid is, the longer the reaction time is, the higher the total energy consumption is, and the overall economy is poor. The utility model adopts a reaction temperature of-25 to 0 ℃.

Through research, the utility model discloses the people find that the dilute phase liquid that the reaction liquid thickener separates adds to the continuous nitration reactor, make full use of dilute phase liquid cold volume, improve the utilization ratio of nitric acid, also guarantee to react controllable simultaneously, dilute phase liquid accounts for the weight fraction of nitration liquid and is on the low side, the too much cold volume that saves simultaneously of nitric acid quantity is limited, also can increase the load of refrigerant system, reduce the controllability of reaction; the dilute phase liquid accounts for a higher mass fraction of the nitration reaction liquid, and the workload and the separation difficulty of the thickener can be increased. The utility model adopts the dilute phase liquid to account for 20 to 70 percent of the mass fraction of the nitration liquid.

The residence time mentioned in the utility model is defined as the time difference between the methyl benzoic acid and the nitric acid entering the continuous nitration reactor and the nitration liquid flowing out of the continuous nitration reactor, and through research, the utility model finds that the residence time of the raw material methyl benzoic acid in the continuous nitration reactor is too long, the phenomenon that the nitration products of the methyl benzoic acid and the nitric acid continue to generate side reaction with excessive nitric acid is easy to occur, and the production efficiency is low at the same time; the retention time of the raw material methyl benzoic acid in the continuous nitration reactor is too short, and two conditions are easy to occur, wherein one condition is that the reaction of the raw material methyl benzoic acid and nitric acid is too fast, heat transfer is not timely, the reaction is not easy to control, and the other condition is that the reaction of the raw material methyl benzoic acid and nitric acid is insufficient. The residence time of the raw material methyl benzoic acid in the continuous nitration reactor is 1-30 min.

The intermittent reaction process is usually to add nitric acid or methyl benzoic acid into a reactor in advance, then slowly add a second raw material, the reaction of methyl benzoic acid and nitric acid is a rapid reaction, the more the materials participating in the reaction in a certain time, the more the heat released by the reaction, the less the reaction is easy to control, therefore, the feeding speed is strictly controlled in the reaction process and is not suitable to be too fast, if the feeding speed is too fast, the more the heat released by the reaction is, the phenomenon of reaction temperature rise occurs in a non-timely manner, once the reaction temperature rises, the feeding is suspended or the feeding speed is slowed down, so that the phenomenon that the more the materials are fed under the same reaction conditions and the longer the feeding time is, therefore, the small test process has a more obvious amplification effect when carrying out industrial amplification, when carrying out industrial production, because the heat exchange efficiency of a reaction kettle is limited, the feeding speed is not suitable to be too fast, resulting in a prolonged reaction time. Therefore, in a kilogram-level pilot scale process of reaction materials, the reaction time is 10-120 min, and higher conversion rate and yield (such as the scheme disclosed by CN 108129322A) can be realized, but the time for single-batch production is 12h when industrial scale-up production is carried out, wherein the reaction time is not less than 4h (such as the scheme disclosed by the environmental impact report of the Jiangtai methylbenzoic acid series project in Anhui)

Through the research, the utility model discloses the people discovers that liquid raw material nitric acid and dilute phase liquid precool before adding continuous nitration ware and can reduce refrigerant system's work load, if precooling or precooling degree are lower, the methyl benzoic acid takes place the heat of reaction release in the twinkling of an eye and can not in time be removed, under the condition of guaranteeing the reaction liquid temperature, need control lower refrigerant temperature and bigger refrigerant flow in the refrigerant system, the utility model discloses a liquid state that precooling is 5 ~ 30 ℃ lower than reaction temperature before liquid raw material nitric acid adds continuous nitration ware, and the liquid state that precooling is 5 ~ 30 ℃ lower than reaction temperature before the dilute phase liquid adds continuous nitration ware.

The utility model provides an energy-conservation embodies following two aspects in the methyl benzoic acid continuous nitration reaction system:

on one hand, the reaction volume is reduced, the heat exchange efficiency is improved, and the energy utilization rate is higher;

on the other hand, the dilute phase liquid separated by the reaction liquid thickener is added into the continuous nitration reactor, so that the cold energy of the dilute phase liquid is fully utilized while the nitric acid is fully utilized, and the contribution of the cold energy of the dilute phase liquid to energy conservation is particularly explained in the utility model. The cold energy of the dilute-phase liquid is defined as the energy required by raising the temperature of the same amount of dilute-phase liquid from the separated temperature to room temperature (25 ℃), the contribution of the cold energy of the dilute-phase liquid to the energy conservation is expressed as the percentage of the cold energy of the dilute-phase liquid to the theoretical total cold energy, and the theoretical total cold energy is numerically the same as the total heat release in the nitration reaction process of the methylbenzoic acid.

A ring assessment document disclosed in 2018 of Jiangtai in Anhui mentions that 4000 tons of 2-nitro-3-methylbenzoic acid are planned to be produced annually in two stages, the disclosed process is an intermittent kettle type production process, a reaction device adopted is a 10-cubic reaction kettle, 4 sets of production devices are planned, the capacity of one set of production device is 1000 tons, each set of equipment produces two batches every day, and the annual production batch is 2400 batches. The utility model discloses use one set of continuous nitration reactor volume to carry out methyl benzoic acid's nitration between for example for the continuous nitration reaction system of 50L methyl benzoic acid, methyl nitrobenzoic acid's annual output can reach 1900 tons, and this set of methyl benzoic acid's continuous nitration reaction system compares one set of 10 cubic reation kettle's production efficiency and improves 90%, and the reactor volume reduces to 1/200, and production efficiency is showing and is improving, because the reactor reduces and rare-phase liquid's recycle, and energy-conserving effect is showing.

The improvement of the production efficiency is shown in the percentage of the annual yield improvement of the methyl benzoic acid continuous nitration reaction system compared with the reaction kettle batch production system, and the annual yield (1000 tons) of a batch production system with 10 cubic reaction kettles is used as a comparison in the following examples, which is mentioned in a critique document published in 2018 in Anhui Jiangtai.

The annual throughput in the following examples is defined as the total mass of the starting material methylbenzoic acid, the starting material liquid nitric acid and the dilute phase liquid in the continuous nitration reaction system of methylbenzoic acid.

The annual yield in the following examples is defined as the total mass of the nitrated product of methylbenzoic acid produced by nitrating methylbenzoic acid.

In the embodiments 1 to 13 of the present invention, the conversion rate of the raw material is equal to or more than 99.5%, and the yield is equal to or more than 95%.

Example 1:

an outlet of the solid continuous feeding system (2) is connected with a first material inlet of the continuous nitration reactor (1), an outlet of the liquid continuous feeding system (3) is connected with a material inlet of the liquid cooler (4), a material outlet of the liquid cooler (4) is connected with a second material inlet of the continuous nitration reactor (1), a material outlet of the continuous nitration reactor (1) is connected with an inlet of the reaction liquid thickener (5), a clear liquid outlet of the reaction liquid thickener (5) is connected with a material inlet of the circulating liquid condenser (6), a material outlet of the circulating liquid condenser (6) is connected with a third material inlet of the continuous nitration reactor (1), a refrigerant outlet of the refrigerant system (7) is connected with a refrigerant inlet of the continuous nitration reactor (1), and a return port of the refrigerant system (7) is connected with a refrigerant outlet of the continuous nitration reactor (1).

The continuous nitration reactor (1) adopts a spiral stirring structure tubular reactor with the volume of 100L and the pushing function, and the inlet positions of a first material inlet, a second material inlet and a third material inlet are all positioned at the front end of the continuous nitration reactor (1).

The continuous nitration reaction of m-toluic acid is carried out by using a continuous nitration reaction system of toluic acid:

m-toluic acid is continuously conveyed at the flow rate of 160kg/h through a solid continuous feeding system (2), enters a continuous nitration reactor (1) from a first material inlet, and simultaneously nitric acid with the concentration of 98% is conveyed by a liquid continuous feeding system (3) to continuously flow through a liquid raw material cooler (4) to be precooled to 10 ℃ lower than the reaction temperature, namely minus 25 ℃, and then enters the continuous nitration reactor (1) from a second material inlet, the mass ratio of the added nitric acid to the m-toluic acid is 5:1, the m-toluic acid and the nitric acid are subjected to continuous nitration reaction in the continuous nitration reactor (1), the reaction temperature is controlled to be minus 15 ℃, the stirring speed is 300r/min, the reaction time is 7.5min, a nitration reaction liquid is obtained, a dilute phase liquid with the mass fraction of 40% of the nitration liquid is separated after the nitration liquid is thickened by a reaction liquid thickener (5), and is cooled to 10 ℃ lower than the reaction temperature by a circulating liquid condenser (6) After the liquid state at the temperature of minus 25 ℃ is obtained, the liquid enters the continuous nitration reactor (1) from a third material inlet, and the thick-phase slurry enters a subsequent processing unit to obtain three nitration isomer products.

The continuous nitration reaction system of the methyl benzoic acid can achieve 11520 tons of m-methyl benzoic acid continuous nitration reaction annual treatment capacity, the output of three isomers nitration products of the m-methyl benzoic acid is 1490 tons, the production efficiency is improved by 49 percent, and the energy can be saved by 26.5 percent by utilizing the cold energy of dilute phase liquid.

Example 2:

example 2 differs from example 1 in that the continuous nitrification reactor (1) used was a tubular reactor having a rod-like stirring structure and a volume of 100L, and the connection manner of the apparatus and the material inlet position were the same as those of example 1.

The continuous nitration reaction of o-methylbenzoic acid is carried out by using a continuous nitration reaction system of methylbenzoic acid:

continuously conveying o-methylbenzoic acid at the flow rate of 150kg/h through a solid continuous feeding system (2), feeding the o-methylbenzoic acid into a continuous nitration reactor (1) from a first material inlet, conveying 98% nitric acid continuously flowing through a liquid raw material cooler (4) from a liquid continuous feeding system (3) to be precooled to 18 ℃ lower than the reaction temperature, namely minus 30 ℃, then feeding the nitric acid into the continuous nitration reactor (1) from a second material inlet, controlling the mass ratio of the added nitric acid to the o-methylbenzoic acid to be 5:1, carrying out continuous nitration reaction on the o-methylbenzoic acid and the nitric acid in the continuous nitration reactor (1), controlling the reaction temperature to be minus 12 ℃, stirring speed to be 350r/min, obtaining nitration reaction liquid after the reaction time is 8min, separating dilute phase liquid accounting for 40% of the mass fraction of the nitration liquid after the nitration liquid is thickened by a reaction liquid thickener (5), and cooling the dilute phase liquid accounting for 10% lower than the reaction temperature by a circulating liquid condenser (6) After the liquid state at the temperature of minus 22 ℃ enters the continuous nitration reactor (1) from a third material inlet, the thick phase slurry enters a subsequent processing unit to obtain two nitration isomer products.

The annual treatment capacity of the o-methylbenzoic acid continuous nitration reaction carried out by using the methyl benzoic acid continuous nitration reaction system reaches 10800 tons, the output of two isomers nitration products of the o-methylbenzoic acid is 1380 tons, the production efficiency is improved by 38 percent, and the energy can be saved by 24.2 percent by utilizing the cold energy of dilute phase liquid.

Example 3:

example 3 differs from example 1 in that the continuous nitrification reactor (1) is selected as a tubular reactor with a plug-in mixing structure and a volume of 100L, and the connection mode of the equipment and the position of the material inlet are the same as those of example 1.

The continuous nitration reaction of the methyl benzoic acid is carried out by using a continuous nitration reaction system of the methyl benzoic acid:

p-benzoic acid is continuously conveyed through a solid continuous feeding system (2) at the flow rate of 140kg/h, enters a continuous nitration reactor (1) from a first material inlet, and simultaneously nitric acid with the concentration of 98% is conveyed through a liquid continuous feeding system (3) to continuously flow through a liquid raw material cooler (4) to be precooled to 20 ℃ lower than the reaction temperature, namely minus 30 ℃, and then enters the continuous nitration reactor (1) from a second material inlet, the mass ratio of the added nitric acid to the p-toluic acid is 5:1, the p-toluic acid and the nitric acid are subjected to continuous nitration reaction in the continuous nitration reactor (1), the reaction temperature is controlled to be minus 10 ℃, the reaction time is 10min, so as to obtain a nitration reaction liquid, the nitration reaction liquid is thickened by a reaction liquid thickener (5), a dilute phase liquid with the mass fraction of 30% of the nitration liquid is separated, and is cooled to a liquid state with the temperature lower than the reaction temperature by 10 ℃, namely minus 20 ℃ by a circulating liquid condenser (6) Then the slurry enters the continuous nitration reactor (1) through a third material inlet, and the thick-phase slurry enters a subsequent treatment unit to obtain a nitration product.

The annual treatment capacity of the continuous nitration reaction system of the methyl benzoic acid for carrying out the continuous nitration reaction of the methyl benzoic acid reaches 8640 tons, the output of the nitration product of the methyl benzoic acid is 1290 tons, the production efficiency is improved by 29 percent, and the energy can be saved by 14.6 percent by utilizing the cold energy of dilute phase liquid.

Example 4:

example 4 the continuous nitrification reactor (1) and the continuous nitrification reactor system selected in example 1 were connected in the same manner except for the material inlet position.

The continuous nitration reactor (1) adopts a spiral stirring structure tubular reactor with the volume of 100L and the pushing function, the inlet positions of a first material inlet and a third material inlet are positioned at the front end of the continuous nitration reactor (1), and one inlet of a second material inlet is positioned at the middle position of the continuous nitration reactor (1).

The continuous nitration reaction of m-toluic acid is carried out by using a continuous nitration reaction system of toluic acid:

continuously conveying m-toluic acid at the flow rate of 171kg/h through a solid continuous feeding system (2), feeding the m-toluic acid into a continuous nitration reactor (1) from a first material inlet, conveying 98% nitric acid continuously flowing through a liquid raw material cooler (4) from a liquid continuous feeding system (3) to be precooled to the temperature lower than the reaction temperature by 10 ℃ below zero or minus 25 ℃, then feeding the nitric acid into the continuous nitration reactor (1) from a second material inlet, controlling the reaction temperature to be minus 15 ℃, stirring at the speed of 300r/min and reacting for 7min to obtain a nitration reaction liquid, thickening the nitration reaction liquid by a reaction liquid thickener (5), separating a dilute phase liquid accounting for 40% of the mass fraction of the nitration reaction liquid, and cooling the dilute phase liquid to the temperature lower than the reaction temperature by 10 ℃ by a circulating liquid condenser (6) After the liquid state at the temperature of minus 25 ℃ is obtained, the liquid enters the continuous nitration reactor (1) from a third material inlet, and the thick-phase slurry enters a subsequent processing unit to obtain three nitration isomer products.

The annual treatment capacity of the continuous nitration reaction system of the methyl benzoic acid for carrying out the continuous nitration reaction of the m-methyl benzoic acid reaches 12300 tons, the yield of three isomers of the m-methyl benzoic acid is 1590 tons, the production efficiency is improved by 59 percent, and the energy can be saved by 26.5 percent by utilizing the cold energy of dilute phase liquid.

Example 5:

example 5 the continuous nitrification reactor (1) and the continuous nitrification reactor system selected in example 1 were connected in the same manner except for the material inlet position.

The continuous nitration reactor (1) adopts a spiral stirring structure tubular reactor with the volume of 100L and the pushing function, the inlet positions of a first material inlet and a third material inlet are positioned at the front end of the continuous nitration reactor (1), one inlet of a second material inlet is positioned at the front end of the continuous nitration reactor (1), and one inlet position is positioned at the middle position of the continuous nitration reactor (1).

The continuous nitration reaction of m-toluic acid is carried out by using a continuous nitration reaction system of toluic acid:

the method comprises the steps of continuously conveying m-toluic acid through a solid continuous feeding system (2) at the flow rate of 171kg/h, feeding the m-toluic acid into a continuous nitration reactor (1) through a first material inlet, conveying nitric acid with the concentration of 98% through a liquid continuous feeding system (3), continuously flowing through a liquid raw material cooler (4), precooling to the temperature lower than the reaction temperature by 10 ℃ or minus 25 ℃, and dividing the nitric acid into two streams, wherein the flow ratio of the two streams is 1:2, the stream with the ratio of 1 enters the continuous nitration reactor (1) through a second material inlet positioned at the front end of the continuous nitration reactor (1), the stream with the ratio of 2 enters the continuous nitration reactor (1) through a second material inlet positioned at the middle position of the continuous nitration reactor (1), the mass ratio of the added nitric acid to the m-toluic acid is 5:1, and the m-toluic acid and the nitric acid are subjected to continuous nitration reaction in the continuous nitration reactor (1), controlling the reaction temperature at-15 ℃, stirring at 300r/min, reacting for 7min to obtain nitration reaction liquid, thickening the nitration reaction liquid by a reaction liquid thickener (5), separating out dilute phase liquid accounting for 40% of the mass fraction of the nitration reaction liquid, cooling the dilute phase liquid to a liquid state lower than the reaction temperature by 5 ℃, namely-20 ℃ by a circulating liquid condenser (6), then feeding the dilute phase liquid into a continuous nitration reactor (1) from a third material inlet, and feeding the thick phase slurry into a subsequent processing unit to obtain three nitration isomer products.

The annual treatment capacity of the continuous nitration reaction system of the methyl benzoic acid for carrying out the continuous nitration reaction of the m-methyl benzoic acid reaches 12300 tons, the yield of three isomers nitration products of the m-methyl benzoic acid is 1600 tons, the production efficiency is improved by 60 percent, and the energy can be saved by 26.5 percent by utilizing the cold energy of dilute phase liquid.

Example 6:

the difference between the embodiment 6 and the embodiment 1 lies in the inlet positions of the continuous nitrification reactor and the materials, the selected continuous nitrification reactor (1) is two continuous tank reactors which are connected in series and have a stirring and mixing structure and the volume of 150L, the inlet positions of a first material inlet and a second material inlet are both positioned at the top of a first continuous tank reactor, the inlet position of a third material inlet is positioned at the bottom of the first continuous tank reactor, a material outlet of the first continuous tank reactor is connected with a material inlet positioned at the bottom of a second continuous tank reactor, and a material outlet of the second continuous tank reactor is connected with an inlet of a reaction liquid thickener (5).

The continuous nitration process of m-toluic acid by using the continuous nitration reaction system of the toluic acid comprises the following steps:

m-toluic acid is continuously conveyed at the flow rate of 115.6kg/h through a solid continuous feeding system (2), enters a continuous nitration reactor (1) from a first material inlet, and simultaneously nitric acid with the concentration of 96% is conveyed by a liquid continuous feeding system (3) to continuously flow through a liquid raw material cooler (4) to be precooled to the temperature which is lower than the reaction temperature by 5 ℃ below zero, namely-30 ℃, and then enters the continuous nitration reactor (1) from a second material inlet, the mass ratio of the added nitric acid to the m-toluic acid is 3.5:1, the m-toluic acid and the nitric acid are subjected to continuous nitration reaction in the continuous nitration reactor (1), the reaction temperature is controlled to be-25 ℃, the stirring speed is 500r/min, the reaction time is 30min, a nitration reaction liquid is obtained, the nitration liquid is thickened by a reaction liquid thickener (5), a dilute phase liquid with the mass fraction of 35% of the nitration liquid is separated, and is cooled to the temperature which is lower than the reaction temperature by 5% by a circulating liquid condenser (6) After the liquid state at the temperature of minus 30 ℃ enters the continuous nitration reactor (1) from a third material inlet, the thick phase slurry enters a subsequent processing unit to obtain three nitration isomer products.

The annual treatment capacity of the continuous nitration reaction system of the methyl benzoic acid for carrying out the continuous nitration reaction of the m-methyl benzoic acid reaches 5760 tons, the output of three isomers nitration products of the m-methyl benzoic acid is 1060 tons, the production efficiency is improved by 6 percent, and the energy can be saved by 20.6 percent by utilizing the cold energy of dilute phase liquid.

Example 7:

example 7 differs from example 1 in the inlet position of the continuous nitrification reactor and the feed.

The selected continuous nitration reactor (1) is a continuous nitration reactor which is formed by connecting a spiral stirring structure tubular reactor with the volume of 100L and a stirring mixing structure continuous kettle type reactor with the volume of 100L in series in a mode that the tubular reactor is arranged in front of the continuous kettle type reactor and the continuous kettle type reactor is arranged behind the continuous nitration reactor, and the inlet positions of the first material inlet, the second material inlet and the third material inlet are positioned at the front end of the tubular reactor in the continuous nitration reactor (1).

The continuous nitration process of m-toluic acid by using the continuous nitration reaction system of the toluic acid comprises the following steps:

the m-toluic acid is continuously conveyed by a solid continuous feeding system (2) at the flow rate of 144kg/h, enters a continuous nitration reactor (1) from a first material inlet, simultaneously nitric acid with the concentration of 95% is conveyed by a liquid continuous feeding system (3) to continuously flow through a liquid raw material cooler (4) and precool to the temperature which is 10 ℃ below the reaction temperature, namely minus 25 ℃, and then enters the continuous nitration reactor (1) from a second material inlet, the mass ratio of the added nitric acid to the m-toluic acid is 4:1, the m-toluic acid and the nitric acid carry out continuous nitration reaction in the continuous nitration reactor (1), the reaction temperature is controlled to be minus 15 ℃, the stirring speed of a tubular reactor and the continuous kettle type reactor is 300r/min, the nitration reaction liquid is obtained after the reaction time is 20min, the nitration reaction liquid is thickened by a reaction liquid thickener (5), the separated dilute phase liquid accounting for 40 percent of the mass fraction of the nitration reaction liquid is cooled to a liquid state lower than the reaction temperature by 10 ℃ or minus 25 ℃ by a circulating liquid condenser (6), and then enters a continuous nitration reactor (1) through a third material inlet, and the thick phase slurry enters a subsequent processing unit to obtain three nitration isomer products.

The annual treatment capacity of the continuous nitration reaction system of the methyl benzoic acid for carrying out the continuous nitration reaction of the m-methyl benzoic acid reaches 8640 tons, the output of three isomers nitration products of the m-methyl benzoic acid is 1330 tons, the production efficiency is improved by 33 percent, and the energy can be saved by 22.7 percent by utilizing the cold energy of dilute phase liquid.

Example 8:

example 8 differs from example 1 in the inlet position of the continuous nitrification reactor and the feed.

The selected continuous nitration reactor (1) is a continuous nitration reactor which is formed by connecting a continuous kettle type reactor with a stirring and mixing structure and a spiral stirring structure tubular reactor with a volume of 100L and a pushing function in series in a mode that the continuous kettle type reactor is arranged in front of the tubular reactor, the inlet positions of a first material inlet and a third material inlet are positioned at the top of the continuous kettle type reactor in the continuous nitration reactor (1), and the inlet position of a second material inlet is positioned at the front end of the tubular reactor in the continuous nitration reactor (1).

The continuous nitration process of m-toluic acid by using the continuous nitration reaction system of the toluic acid comprises the following steps:

the m-toluic acid is continuously conveyed by a solid continuous feeding system (2) at the flow rate of 134.4kg/h, enters a continuous nitration reactor (1) from a first material inlet, and simultaneously nitric acid with the concentration of 92% is conveyed by a liquid continuous feeding system (3) to continuously flow through a liquid raw material cooler (4) and precool to the temperature which is 15 ℃ below the reaction temperature, namely minus 25 ℃, and then enters the continuous nitration reactor (1) from a second material inlet, the mass ratio of the added nitric acid to the m-toluic acid is 4:1, the m-toluic acid and the nitric acid carry out continuous nitration reaction in the continuous nitration reactor (1), the reaction temperature is controlled at minus 10 ℃, the stirring speed of a tubular reactor and the continuous kettle type reactor is 300r/min, the reaction time is 25min, then nitration reaction liquid is obtained, the nitration liquid is thickened by a reaction liquid thickener (5), the separated dilute phase liquid accounting for 30 percent of the mass fraction of the nitration reaction liquid is cooled to a liquid state lower than the reaction temperature by 10 ℃ or minus 20 ℃ by a circulating liquid condenser (6), and then enters a continuous nitration reactor (1) through a third material inlet, and the thick phase slurry enters a subsequent processing unit to obtain three nitration isomer products.

The annual treatment capacity of the continuous nitration reaction system of the methyl benzoic acid for carrying out the continuous nitration reaction of the m-methyl benzoic acid reaches 6912 tons, the yield of three isomers nitration products of the m-methyl benzoic acid is 1230 tons, the production efficiency is improved by 23 percent, and the energy can be saved by 12.2 percent by utilizing the cold energy of dilute phase liquid.

Example 9:

the connection of each unit in the continuous nitration reaction system of methylbenzoic acid and the operation procedure of the continuous nitration reaction of m-methylbenzoic acid using the continuous nitration reaction system of methylbenzoic acid in example 9 were the same as in example 4, and the stirring speed of the tubular reactor, the process conditions and the advantageous effects were changed as shown in table 1:

TABLE 1 results of nitration reactions at different stirring speeds

Example 10:

the connection of each unit in the continuous nitration reaction system of methylbenzoic acid and the operation steps of the continuous nitration reaction of m-methylbenzoic acid using the continuous nitration reaction system of methylbenzoic acid in example 10 are the same as those in example 4, the mass fraction of dilute phase liquid in the nitration reaction liquid in the process conditions is changed, and the process conditions and the beneficial effects are shown in table 2:

TABLE 2 nitration results with different amounts of dilute phase liquid added

Example 11:

the connection of each unit in the continuous nitration reaction system of methylbenzoic acid and the operation steps of the continuous nitration reaction of m-methylbenzoic acid using the continuous nitration reaction system of methylbenzoic acid in example 11 were the same as in example 4, the reaction temperature in the process conditions was changed, and the mass fraction of the dilute phase liquid in the nitration reaction liquid and the mass ratio of nitric acid to m-methylbenzoic acid were adjusted, and the process conditions and advantageous effects were as shown in table 3:

TABLE 3 nitration results at different reaction temperatures

Example 12

The connection of each unit in the continuous nitration reaction system of methylbenzoic acid and the operation procedure of the continuous nitration reaction of m-methylbenzoic acid using the continuous nitration reaction system of methylbenzoic acid in example 12 were the same as in example 4, the mass ratio of nitric acid to m-methylbenzoic acid in the process conditions was changed, and the process conditions and advantageous effects are as shown in table 4:

TABLE 4 results of continuous nitration reactions with different amounts of starting materials

Example 13

The connection of the units in the continuous nitration reaction system of methylbenzoic acid and the operation of the continuous nitration reaction of m-methylbenzoic acid using the continuous nitration reaction system of methylbenzoic acid in example 13 were the same as in example 4, the concentration of nitric acid in the process conditions was changed, and the reaction temperature and the cooling temperature of nitric acid and dilute phase liquid, the mass ratio of nitric acid and m-methylbenzoic acid were adjusted accordingly, and the process conditions and advantageous effects are as shown in table 5:

TABLE 5 continuous nitration results at different nitric acid concentrations

Claims (10)

1. A continuous nitration system of methyl benzoic acid is characterized by comprising a continuous nitration reactor,

the outlet of the solid continuous feeding system is communicated with the solid feeding hole of the continuous nitration reactor;

the outlet of the liquid continuous feeding system is communicated with the inlet of a liquid raw material cooler, and the outlet of the liquid raw material cooler is communicated with the liquid feeding hole of the continuous nitration reactor;

the material inlet of the reaction liquid thickener is communicated with the discharge hole of the continuous nitration reactor, the clear liquid outlet of the reaction liquid thickener is communicated with the inlet of a circulating liquid condenser, the outlet of the circulating liquid condenser is communicated with a circulating liquid feed inlet of the continuous nitration reactor, and the circulating liquid feed inlet is arranged at one end of the continuous nitration reactor, which is far away from the discharge hole;

and a refrigerant outlet of the refrigerant system is communicated with a refrigerant inlet of the continuous nitration reactor, and a refrigerant return port of the refrigerant system is communicated with a refrigerant outlet of the continuous nitration reactor.

2. The continuous nitrification system of claim 1, wherein the continuous nitrification reactor is a tubular reactor, a continuous tank reactor, or a tubular reactor and a continuous tank reactor connected in series.

3. The continuous nitrification system according to claim 2, wherein when the continuous nitrification reactor is a tubular reactor, the solid feed port is arranged at the inlet end of the tubular reactor, the liquid feed port is arranged at the inlet end and/or the middle of the tubular reactor, and the circulating liquid feed port is arranged at the inlet end of the tubular reactor.

4. The continuous nitrification system according to claim 2, wherein when the continuous nitrification reactor is a continuous tank reactor, the solid feed port is disposed at the top of the continuous tank reactor, the liquid feed port is disposed at the top of the continuous tank reactor, and the circulating liquid feed port is disposed at the top or bottom of the continuous tank reactor.

5. The continuous nitrification system of claim 2, wherein when the continuous nitrification reactor is a continuous tank reactor and a tubular reactor which are connected in series in sequence, the solid feed inlet is arranged at the top of the continuous tank reactor, the liquid feed inlet is arranged at the inlet end of the tubular reactor, and the circulating liquid feed inlet is arranged at the top of the continuous tank reactor.

6. The continuous nitrification system of any one of claims 3 to 5, wherein the inlet end of the tubular reactor is one tenth of the area of the inlet end of the tubular reactor.

7. The continuous nitrification system according to any one of claims 3 to 5, wherein the middle of the tubular reactor is one-third to two-thirds of the area of the tubular reactor.

8. The continuous nitrification system of claim 1, wherein an agitated mixing device and/or an insert structure is provided within the continuous nitrification reactor.

9. The continuous nitrification system of claim 1, wherein the continuous nitrification reactor is provided with built-in heat removal structures and/or heat removal by equipment jackets.

10. The continuous nitrification system according to any one of claims 2 to 5, wherein when the continuous nitrification reactor comprises a continuous tank reactor, the material outlet of the continuous tank reactor is located at an overflow port, and the height of the overflow port is 1/2 to 4/5 from the bottom of the reactor.

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