CN215428945U - Chloroethylene production device - Google Patents

Abstract

The present invention provides a vinyl chloride production apparatus, comprising: reaction tower, liquid catalyst circulation pipeline, circulating pump, circulation heat exchanger and security demister. Acetylene, hydrogen chloride mixed gas and liquid catalyst introduced into the upper part of the tower body of the reaction tower are dispersed from top to bottom in the reaction tower and react in the reaction area to generate vinyl chloride; the liquid catalyst circulating pipeline is positioned outside the reaction tower, one end of the liquid catalyst circulating pipeline is connected with a catalyst outlet at the bottom of the reaction tower, and the other end of the liquid catalyst circulating pipeline is connected with a catalyst inlet at the upper part of the reaction tower; the circulating pump is arranged on a pipeline of the liquid catalyst circulating pipeline, so that the liquid catalyst flows along the liquid catalyst circulating pipeline from bottom to top; and the circulating heat exchanger is arranged on the liquid catalyst circulating pipeline and is used for heating or cooling the liquid catalyst. The utility model solves various problems caused by difficult heat transfer and increased side reaction caused by the difficult heat transfer in the process of preparing the chloroethylene by the calcium carbide method.

Description

Chloroethylene production device

Technical Field

The utility model belongs to the technical field of calcium carbide method chloroethylene production, and particularly relates to a chloroethylene production device.

Background

Vinyl Chloride (VCM), also known as Vinyl chloride (Vinyl chloride), is an important monomer used in polymer chemistry, and can be prepared from ethylene or acetylene, and is colorless and easily liquefied gas. Vinyl Chloride Monomer (VCM) is mainly used for producing polyvinyl chloride resin and is widely applied to industries such as buildings, packaging, medical treatment, automobiles and the like. Or copolymerizing with vinyl acetate, butadiene, acrylonitrile, acrylate, vinylidene chloride, etc. to prepare adhesive, paint, food packing material, building material, etc.

Currently, two processes, namely an ethylene process and a calcium carbide process, are mainly used for global VCM production. From the productivity structure, the polyvinyl chloride industry in China mainly adopts the calcium carbide method production technology, and the percentage of the calcium carbide method production technology is 81.3%. The most classical calcium carbide process is the calcium carbide process route, which uses coal and limestone as raw materials to produce calcium carbide (calcium carbide), adds water into the calcium carbide to generate acetylene, and uses activated carbon to load HgCl₂The catalyst is acetylene and hydrogen chloride gas to generate addition reaction to generate VCM. The reaction is a strong exothermic reaction, and the production of chloroethylene by adopting a traditional fixed bed reactor can cause the activated carbon to load HgCl₂The catalyst surface is locally overheated, carbon deposition blocks a pore channel, the contact area of the catalyst and gas is reduced, and the rapid inactivation of the catalyst is causedThe catalytic efficiency of the catalyst is reduced, and in addition, local temperature runaway and side reactions are increased, the types and the quantity of byproducts are increased, so that the subsequent product refining is difficult, and the product quality is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a chloroethylene production device to solve the problems of difficult heat transfer, increased side reactions and the like in the process of preparing chloroethylene by a calcium carbide method.

The utility model is realized by the following steps:

the vinyl chloride production apparatus comprises:

the reaction tower is internally provided with a mixed gas zone, a reaction zone, a gas-liquid separation zone and a catalyst storage zone from top to bottom in sequence; the upper part of the tower body is provided with an acetylene and hydrogen chloride mixed gas inlet and a catalyst inlet, the lower part of the tower body is provided with a reaction product gas outlet, and the bottom of the tower body is provided with a catalyst outlet; leading in acetylene, hydrogen chloride mixed gas and a liquid catalyst in parallel from top to bottom in the reaction tower and reacting in a reaction area to generate vinyl chloride; carrying out gas-liquid separation in a gas-liquid separation zone to obtain reaction product gas containing chloroethylene and a liquid catalyst;

the liquid catalyst circulating pipeline is positioned outside the reaction tower body, one end of the liquid catalyst circulating pipeline is connected with a catalyst outlet, and the other end of the liquid catalyst circulating pipeline is connected with a catalyst inlet;

the circulating pump is arranged on the liquid catalyst circulating pipeline and enables the liquid catalyst to flow along the liquid catalyst circulating pipeline from bottom to top; and

and the circulating heat exchanger is arranged on the liquid catalyst circulating pipeline and is used for heating or cooling the liquid catalyst.

Under the technical scheme, the utility model can be realized as follows:

the device also comprises a safety demister, wherein the lower part of the safety demister is provided with a reaction product gas inlet, the bottom of the safety demister is provided with a bottom outlet, and the upper part of the safety demister is provided with a product gas outlet; a subsequent reaction area, a defoaming area and a product gas area are arranged in the safety demister; the subsequent reaction zone is internally provided with a solid mercury-free catalyst, and the safety demister is used for enabling reaction product gas from the lower part of the reaction tower to continue to react and removing entrained liquid catalyst fog drops to obtain a product chloroethylene gas.

In the chloroethylene production device, in the safety demister, a liquid outlet is arranged on a wall body below the reaction product gas inlet, a catalyst return opening is arranged at the lower part of the reaction tower, and the liquid outlet is connected with the catalyst return opening through a pipeline and is used for returning liquid catalyst at the lower part of the safety demister to the lower part of the reaction tower to continuously participate in reaction under the action of potential difference.

In the vinyl chloride production apparatus, the liquid outlet is provided with a pipe filter for filtering solid impurities in the liquid catalyst during reflux.

The chloroethylene production device also comprises a first catalyst storage tank which is provided with a catalyst inlet, a catalyst feed port and a tank bottom outlet; a control valve is arranged on a pipeline connected with the catalyst outlet, two sides of the control valve are connected with a bypass pipeline, and two ends of the bypass pipeline are respectively connected with a catalyst inlet of the first catalyst storage tank and a tank bottom outlet through the control valve; the first catalyst storage tank is located upstream of the circulation pump.

In the vinyl chloride production device, a catalyst regulating valve for regulating the flow of the catalyst and a flow monitor for metering the flow are arranged on the liquid catalyst circulating pipeline.

In the vinyl chloride production apparatus, a liquid distributor for distributing the liquid catalyst is installed at the upper part of the reaction tower.

In the chloroethylene production device, a catalyst adding port is arranged on the wall body at the middle part of the reaction area and the defoaming area of the safety demister; and the bottom outlet of the second catalyst storage tank is connected with a catalyst adding port in the middle of the security demister through a pipeline provided with a delivery pump.

In the chloroethylene production device, the bottom outlet of the safety demister is connected with a second catalyst storage tank through a pipeline provided with a valve.

The chloroethylene production device also comprises a control system, wherein pressure, temperature and liquid level monitoring systems are arranged on a reaction tower, a first catalyst storage tank, a circulating heat exchanger, a security demister and a condenser of the device and are respectively arranged at a corresponding pressure detection port and a temperature detection port liquid level monitoring port, and a temperature and flow monitoring control system and a monitoring control system of a valve switch are arranged on each connecting pipeline.

According to the utility model, the acetylene and hydrogen chloride mixed gas and the liquid catalyst react in the parallel process from top to bottom in the reaction tower, the reaction is relatively mild, and the generated heat is taken away along with the materials along with the descending of the reaction materials, so that the problem of local temperature runaway is not easy to occur in the reaction zone. In addition, the liquid catalyst taking away the reaction heat is cooled by a heat exchanger arranged outside the reaction tower, and the heat exchange efficiency is high. Meanwhile, the flow of the catalyst circulating outside the reaction tower is easy to control. The technical scheme of the utility model is that on the basis of gas-liquid parallel reaction, the temperature in the reaction zone can be conveniently and effectively controlled by controlling the flow of the catalyst, thereby effectively solving the problems of difficult heat transfer and multiple aspects brought by the heat transfer in the prior art.

Furthermore, the technical scheme of the utility model can realize the online addition and replacement of the catalyst without stopping, thereby realizing the stable, long, full and excellent operation of the vinyl chloride production device.

Drawings

FIG. 1 is a schematic view of an apparatus and a process for producing vinyl chloride by co-current gas-liquid flow according to the present invention;

FIG. 2 is a schematic view of a reaction column of the present invention;

FIG. 3 is a schematic structural diagram of the safety demister of the utility model;

FIG. 4 is a schematic structural diagram of a condenser of the present invention;

fig. 5 is a schematic structural view of a first catalyst storage tank of the present invention.

The various reference numbers in the figures are schematic:

A. hydrogen chloride; B. acetylene; C. crude vinyl chloride gas; D. a liquid catalyst;

1. a reaction tower; 101. a mixed gas inlet; 102. a liquid distributor; 103. a temperature monitoring port; 104. a pressure monitoring port; 105. a reaction product gas outlet; 106. a catalyst return port; 107. a catalyst outlet; 108. a catalyst storage area; 109. a liquid level monitoring port; 110. a gas-liquid separation zone; 111. a reaction zone; 112. a catalyst inlet; 113. a mixed gas zone; 2. a safety demister; 200. a pipeline filter; 201. a liquid outlet; 202. a reaction product gas inlet; 203. a subsequent reaction zone; 204. a defoaming zone; 205. a product gas outlet; 206. a product gas zone; 207. a bottom outlet; 3. a condenser; 301. a product gas inlet; 302. a crude vinyl chloride gas outlet; 303. a catalyst discharge port; 4. a first catalyst storage tank; 401. a catalyst feeding port; 402. a catalyst inlet; 403. a tank bottom outlet; 5. a circulation pump; 6. a circulating heat exchanger; v0, catalyst exhaust valve; v1, first control valve; v2, second control valve; v3, third control valve; v4, fourth control valve; v5, fifth control valve; v6, catalyst regulating valve; v7, gas feed regulating valve; 7. a flow monitor; 8. a second catalyst storage tank.

Detailed Description

The present invention will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Referring to fig. 1, the apparatus for producing vinyl chloride through co-current gas-liquid reaction according to the present invention includes a reaction tower 1, a bubble trap 2, a condenser 3, a first catalyst storage tank 4, a circulation pump 5, a circulation heat exchanger 6, and a second catalyst storage tank 8.

The reaction tower 1 adopts a reaction tower capable of realizing gas-liquid cocurrent flow to realize that the hydrogen chloride A and the acetylene B react under the action of a liquid catalyst to generate a product vinyl chloride gas, and can adopt a known spray tower, a packed tower, a plate tower or other forms for gas-liquid cocurrent flow contact towers. Fig. 2 shows a form of construction. The structure of the reaction tower 1 will be explained with reference to FIG. 2. The reaction tower 1 is provided with a liquid distributor 102 at the upper part, a mixed gas zone 113 at the upper part of the liquid distributor 102, and a reaction zone 111, a gas-liquid separation zone 110 and a catalyst storage zone 108 are arranged below the liquid distributor 102 in sequence from top to bottom. The top of the reaction tower is provided with a mixed gas inlet 101 of acetylene and hydrogen chloride. The tower wall of the reaction tower corresponding to the gas-liquid separation zone is provided with a reaction product gas outlet 105 and a catalyst return port 106, wherein the reaction product gas outlet 105 is positioned above the liquid level of the liquid catalyst in the catalyst storage zone 108, and the catalyst return port 106 is positioned below the reaction product gas outlet 105. The bottom of the reaction tower 1 is provided with a catalyst outlet 107, the tower wall of the reaction tower corresponding to the catalyst storage area 108 is provided with a liquid level monitoring port 109, and the liquid level of the catalyst is monitored when needed. A catalyst inlet 112 is arranged on the tower wall of the upper part of the reaction tower corresponding to the liquid distributor, and a plurality of temperature monitoring ports 103 and pressure monitoring ports 104 are also arranged on the tower wall of the reaction tower according to the requirement;

a jacket is arranged outside the reaction tower 1, a cold and heat source inlet and outlet are arranged on the jacket, and a heat source is introduced to raise the temperature in the reaction tower to be within a preset temperature range at the initial stage of starting the operation of the device; and (3) introducing a cold source as an auxiliary heat exchange means to assist in controlling the temperature in the reaction tower within a preset range in the normal operation stage of the device.

The reaction tower 1 is a one-section or multi-section tower, and can be a single-tower one-stage reaction or a multi-tower series multi-stage reaction.

When the reaction tower 1 adopts a spray tower, the reaction area 111 is empty; when the reaction tower adopts a packed tower, the reaction zone 111 is provided with packing; when the reaction tower adopts a plate tower, the reaction zone is provided with a tower plate. Packing or trays are provided in the reaction zone 111 to provide an interface for gas-liquid contact.

The mixed gas of acetylene and hydrogen chloride is a gas obtained by mixing hydrogen chloride A and acetylene B according to a certain proportion. The mixed gas enters the reaction tower 1 from the mixed gas inlet 101 at the top of the reaction tower 1 through a pipeline provided with a flow monitor 7 and a gas feed regulating valve V7.

The safety demister 2 is used for coupling a gas-solid reaction device and a liquid droplet removing device together, and is used for enabling reaction product gas from the lower part of the reaction tower to continue to react and removing entrained liquid catalyst droplets. Referring to fig. 3, the inside thereof includes a subsequent reaction zone 203, a defoaming zone 204, a product gas zone 206; the bottom of the safety demister 2 is provided with a bottom outlet 207, the lower side is provided with a liquid outlet 201 which is used for leading out liquid catalyst and is in fluid communication with a catalyst return port of the reaction tower 1, the lower side is provided with a reaction product gas inlet 202 which is in fluid communication with a reaction product gas outlet 105 of the reaction tower 1, and the top is provided with a product gas outlet 205, wherein the liquid outlet 201 is positioned at the lower part of the reaction product gas inlet 202. The liquid outlet 201 of the lower side of the safety demister 2 is provided with a pipeline filter 200 to filter the solid impurities in the liquid catalyst during backflow. The outer wall of the safety demister 2 is also provided with a plurality of temperature monitoring ports 103 and pressure monitoring ports 104.

The external of the security demister 2 is provided with a jacket which is provided with a cold and heat source inlet and outlet so as to realize the temperature control of the security demister body.

The reaction product gas outlet 105 on the reaction tower 1 is connected with the reaction product gas inlet 202 on the security demister 2 through a pipeline; the liquid outlet 201 on the lower side of the safety demister 2 is connected with the catalyst return opening 106 on the reaction tower 1 through a pipeline provided with a valve, and the position of the catalyst return opening 106 is lower than that of the liquid outlet 201, so that the connecting pipeline is in a high-low direction (not shown), and the liquid catalyst at the liquid outlet 201 flows into the catalyst return opening 106 under the action of gravity. The bottom outlet 207 at the bottom of the safety demister 2 is connected with the second catalyst storage tank 8 through a pipeline provided with a valve, and the liquid catalyst in the safety demister which does not accord with the reflux use requirement any more is led out and recycled when necessary. A catalyst adding port is arranged on the wall body at the middle part of the reaction area and the defoaming area of the safety defoaming device; the bottom outlet of the second catalyst storage tank is connected with a catalyst adding port in the middle of the security demister through a pipeline provided with a delivery pump so as to deliver the catalyst in the second catalyst storage tank to a subsequent reaction zone of the security demister.

The subsequent reaction area 203 of the safety demister 2 is internally provided with a gas-solid contact mechanism and is also provided with a mercury-free solid catalyst, and the defoaming area 204 is provided with a wire mesh-filled demister or a spray catcher.

The reaction product gas from the reaction tower 1 enters the safety demister 2 through a reaction product gas inlet 202, wherein unreacted raw material gas further reacts in a subsequent reaction zone 203 to generate vinyl chloride gas so as to improve the conversion rate of the raw material, entrained liquid catalyst droplets are removed through a defoaming zone 204 after the reaction, the product gas is obtained at the top of the safety demister 2, the liquid catalyst condensed into large droplets is intercepted by the demister or a mist catcher in the defoaming zone 204, and the liquid catalyst returns to a catalyst return port 106 of the reaction tower 1 through a liquid outlet 201 on the side surface of the lower part of the safety demister 2 and enters the reaction tower 1 for recycling.

The condenser 3 is used for reducing the temperature of the product gas from the safety demister 2 and secondarily recovering trace liquid catalyst fog drops carried in the product gas.

Referring to fig. 4, the condenser 3 is provided with a product gas inlet 301, a crude vinyl chloride gas outlet 302, a catalyst discharge port 303, and a cold and heat source inlet and outlet;

the product gas outlet 205 at the top of the guard demister 2 is connected to the product gas inlet 301 at the upper part of the condenser 3 through a pipe.

The first catalyst storage tank 4 can be used for storing liquid catalyst which is not circulated into the system for standby; meanwhile, the liquid catalyst in the system can be returned to the first catalyst storage tank 4 when the liquid catalyst needs to be withdrawn; the liquid catalyst is a liquid mercury-free catalyst.

Referring to fig. 5, the first catalyst storage tank 4 is provided with a catalyst feed port 401, a catalyst inlet port 402, and a temperature monitoring port 103 at the top, and a tank bottom outlet port 403 at the bottom. The first catalyst storage tank 4 is provided with a jacket or other heating means for heating the catalyst in the first catalyst storage tank 4.

Referring to fig. 1, a third control valve V3 is provided on a pipeline connected to the catalyst outlet 107 of the reaction column 1, a bypass pipeline is connected to both sides of the third control valve V3, one end of the bypass pipeline is connected to the catalyst inlet 402 of the first catalyst storage tank through a fifth control valve V5, and the other end of the bypass pipeline is connected to the tank bottom outlet 403 through a second control valve V2. The first catalyst storage tank 4 is located upstream of the circulation pump 5. For safety in the production process, a first control valve V1 and a fourth control valve V4 can be optionally installed as shown in FIG. 1. In view of the discharge lead-out of the catalyst in the first catalyst storage tank 4, a discharge pipe equipped with a catalyst discharge valve V0 is provided on the pipe between the first control valve V1 and the second control valve V2.

Referring to fig. 1, the circulation heat exchanger 6 is provided with a catalyst inlet and a catalyst outlet, and is further provided with a cold and heat source inlet and outlet for cooling the liquid catalyst and by-producing steam or hot water. It adopts a heat exchanger which is resistant to temperature, pressure and corrosion. Which can heat the liquid mercury-free catalyst in the initial phase of the initial operation of the plant in order to reach the reaction temperature as quickly as possible. When the device normally operates, the tube side of the heat exchanger carries the high-temperature liquid catalyst away, the shell side carries the pressure cooling water away, and the hot water or steam is produced as a byproduct, thereby achieving the purpose of energy conservation.

In fig. 1, a catalyst outlet 107 at the bottom of a reaction tower 1, a circulating pump 5, a circulating heat exchanger 6, a catalyst inlet 112 at the upper part of the reaction tower 1, a liquid catalyst circulating pipeline, a third control valve V3 mounted thereon, a flow monitor 7, and a catalyst regulating valve V6 form a catalyst circulating system capable of regulating temperature and flow, and are used for realizing self-circulation utilization of the catalyst in the reaction tower when the device normally operates.

The top of the second catalyst storage tank 8 is provided with an inlet and a charging port, the bottom of the second catalyst storage tank is provided with an outlet, the outer wall of the second catalyst storage tank is also provided with a liquid level monitoring port and a temperature monitoring port, the outer part of the second catalyst storage tank is provided with a jacket, and the jacket is provided with a cold and heat source inlet and outlet.

Referring to the embodiment shown in fig. 1, a reaction tower 1 is used for gas-liquid phase contact and reaction, a liquid catalyst enters from a catalyst inlet 112, then enters a reaction zone 111 after being distributed by a liquid distributor 102, a raw material mixed gas enters the reaction tower 1 from a mixed gas inlet 101 at the top of the reaction tower 1 and enters the reaction zone 111 with the liquid catalyst downwards in parallel, the gas and the liquid phases in the reaction zone 111 are fully contacted, the mixed gas reacts in the presence of the catalyst, and the temperature of the liquid catalyst and the temperature of reaction product gas are raised by the heat generated by the reaction. The heated liquid catalyst is cooled outside the tower and then returned to the upper part of the reaction tower for recycling, so that the reaction heat of the reaction system is removed.

The working process of the utility model is as follows:

(1) adding catalyst to the system

Before production is started, when liquid catalyst needs to be added into the reaction system, the standby catalyst is added into a first catalyst storage tank, valves of a first control valve V1, a third control valve V3, a fourth control valve V4 and a fifth control valve V5 are closed, a jacket (or other heating facilities) of the first catalyst storage tank is introduced with a heat source to heat the catalyst in the storage tank, when the catalyst in the first catalyst storage tank reaches a set temperature (110-170 ℃), valves of the first control valve V1 and a second control valve V2 and a valve of a catalyst regulating valve V6 are opened, a circulating pump 5 is started, and the liquid catalyst in a first catalyst storage tank 4 is added into the reaction tower through a circulating heat exchanger 6, a catalyst inlet 112 of the reaction tower 1 and a liquid distributor 102. When the liquid level of the liquid catalyst at the bottom in the reaction tower meets the process requirement, the valves of the fourth control valve V4 and the third control valve V3 are opened, the valve of the fifth control valve V5 is kept in a closed state, and the valves of the first control valve V1 and the second control valve V2 are closed at the same time, so that the liquid catalyst forms circulation in the reaction tower 1 through the circulating heat exchanger 6, and normal production can be started.

(2) Addition of the gas mixture

Raw materials of hydrogen chloride A and acetylene B are mixed according to the molar ratio of the hydrogen chloride to the acetylene (1.0-1.2): 1 to form mixed gas, and the mixed gas enters a mixed gas area 113 of the reaction tower from the top of the reaction tower at a certain flow rate regulated by a gas feed regulating valve V7, and the flow rate is monitored by a flow rate monitor 7.

(3) Formation of vinyl chloride gas

In the reaction tower, the mixed gas moves downwards from the mixed gas zone 113 at the top, the liquid catalyst is distributed by the liquid distributor 102 and then flows downwards along the tower internal parts in parallel with the mixed gas, the liquid catalyst and the mixed gas are in gas-liquid contact in the reaction zone 111 in the reaction tower, hydrogen chloride and acetylene react under the action of the liquid catalyst to generate vinyl chloride gas, a mixture of reaction product gas and the liquid catalyst is obtained, the reaction is an exothermic reaction, and the mixture can take away reaction heat in the falling process; the temperature in the reaction tower is controlled at 110-170 ℃.

(4) Gas-liquid separation

The mixture obtained in the step (3) is separated by a gas-liquid separation zone 110 at the lower part of the reaction tower, the liquid catalyst falls back to a catalyst storage zone 108 at the bottom of the reaction tower under the action of self gravity, and the reaction product gas carrying the liquid catalyst is sent to a safety demister 2 through a reaction product gas outlet 105 and a communication pipeline;

(5) removal of heat of reaction

The liquid catalyst at the bottom of the reaction tower is cooled by a circulating heat exchanger on an external circulating pipeline and then is conveyed into the reaction tower for recycling.

(6) Subsequent reaction

The unreacted raw gas in the reaction product gas carrying the liquid catalyst obtained in the step (4) continuously reacts in the subsequent reaction zone 203 of the safety demister 2 to generate vinyl chloride gas, and the carried liquid catalyst is removed through the defoaming zone 204 to obtain product gas; the temperature in the safety demister is controlled at 110-170 ℃; after the secondary reaction of the acetylene by the safety demister, the conversion rate of the acetylene can reach 99 percent;

when the content of solid impurities in the liquid catalyst at the bottom of the safety demister exceeds the process requirement, the solid impurities can be discharged to the second catalyst storage tank 8 and do not flow back to the reaction tower any more.

(7) Product gas condensation

Condensing the product gas obtained in the step (6) by a condenser 3 to further remove entrained trace liquid catalyst fog drops to obtain crude chloroethylene gas, obtaining a qualified product by a subsequent refining process, and condensing the obtained liquid catalyst at the bottom of the condenser for recycling;

when a proper amount of catalyst needs to be supplemented in the production process, the valves of the fourth control valve V4 and the third control valve V3 are kept in an open state, and the valves of the fifth control valve V5 and the catalyst discharge valve V0 are kept in a closed state, the valves of the first control valve V1 and the second control valve V2 are opened, so that the liquid catalyst in the first catalyst storage tank is supplemented, and therefore the catalyst is supplemented without stopping.

When the liquid catalyst in the reaction system needs to be withdrawn, the liquid catalyst in the reaction system can be led out to the first catalyst storage tank 4 by opening the valves of the fourth control valve V4 and the fifth control valve V5 and closing the valves of the third control valve V3 and the first control valve V1.

In the utility model, the circulation flow of the liquid catalyst is controlled by the catalyst regulating valve V6 arranged on the pipeline between the circulation heat exchanger and the catalyst inlet of the reaction tower, so that the heat exchange quantity of the liquid catalyst in the circulation heat exchanger is regulated and controlled, and the internal temperature of the reaction tower is further controlled.

The device is also provided with a control system, pressure, temperature, flow and liquid level monitoring systems can be selectively arranged on the reaction tower, the catalyst circulation pipeline, the first catalyst storage tank, the circulation heat exchanger, the security demister, the condenser and other components of the device according to the process requirements and are respectively arranged at the corresponding pressure detection port, the temperature detection port, the circulation pipeline, the liquid level monitoring port and other positions, and the monitoring control systems of the temperature and flow monitoring control system and the valve switch are arranged on the corresponding pipelines, so that through full-automatic control, each parameter in the real-time monitoring and adjusting device is within the range of the process preset requirement.

Compared with a fixed bed reaction process, the method has the following advantages:

(1) the liquid catalyst is adopted, so that the catalytic active ingredients are uniformly distributed, the temperature distribution is uniform, the heat transfer speed is high, no local temperature runaway exists, the service life of the catalyst is long, and the utilization rate of the catalyst is high;

(2) the mixed gas and the liquid catalyst are in gas-liquid direct contact, so that the reaction efficiency can be improved; the productivity of a single set of device is high;

(3) the liquid catalyst adopts external circulation liquid-liquid heat exchange, the heat exchanger has small area, high heat exchange efficiency and low equipment investment, and can generate by-product steam to achieve the aim of saving energy;

(4) the device and the process combining the reaction tower and the safety demister can ensure that the conversion rate of acetylene reaches 99 percent, reduce the acetylene content in the chloroethylene product gas and improve the safety and the economical efficiency of production;

(5) the tower reaction has high mass transfer efficiency, the temperature is effectively controlled by adjusting the flow of the liquid catalyst, and the production safety is high;

(6) the catalyst can be added and replaced on line without stopping, and the stable, long, full and excellent operation of a vinyl chloride production device can be realized;

(7) the catalyst is a mercury-free catalyst, and the problem of mercury pollution in the existing vinyl chloride production is solved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A vinyl chloride production apparatus, comprising:

the reaction tower is internally provided with a mixed gas zone, a reaction zone, a gas-liquid separation zone and a catalyst storage zone from top to bottom in sequence; the upper part of the tower body is provided with an acetylene and hydrogen chloride mixed gas inlet and a catalyst inlet, the lower part of the tower body is provided with a reaction product gas outlet, and the bottom of the tower body is provided with a catalyst outlet; the gas-liquid separation zone is used for carrying out gas-liquid separation to obtain reaction product gas containing chloroethylene and a liquid catalyst;

the liquid catalyst circulating pipeline is positioned outside the reaction tower body, one end of the liquid catalyst circulating pipeline is connected with a catalyst outlet, and the other end of the liquid catalyst circulating pipeline is connected with a catalyst inlet;

the circulating pump is arranged on the liquid catalyst circulating pipeline and enables the liquid catalyst to flow along the liquid catalyst circulating pipeline from bottom to top; and

and the circulating heat exchanger is arranged on the liquid catalyst circulating pipeline and is used for heating or cooling the liquid catalyst.

2. The device of claim 1, further comprising a safety demister, wherein a reaction product gas inlet is arranged at the lower part of the safety demister, a bottom outlet is arranged at the bottom part of the safety demister, and a product gas outlet is arranged at the upper part of the safety demister; a subsequent reaction area, a defoaming area and a product gas area are arranged in the safety demister; the subsequent reaction zone is internally provided with a solid mercury-free catalyst, and the safety demister is used for enabling reaction product gas from the lower part of the reaction tower to continue to react and removing entrained liquid catalyst fog drops to obtain a product chloroethylene gas.

3. The device as claimed in claim 2, wherein the safety demister is provided with a liquid outlet on a wall body below the reaction product gas inlet, and a catalyst return port is provided at the lower part of the reaction tower, and the liquid outlet is connected with the catalyst return port through a pipeline for returning the liquid catalyst at the lower part of the safety demister to the lower part of the reaction tower to continue to participate in the reaction under the action of the head difference.

4. The apparatus of claim 3, wherein the liquid outlet is provided with a pipe filter to filter solid impurities in the liquid catalyst during reflux.

5. The apparatus of claim 1, further comprising a first catalyst storage tank having a catalyst inlet, a catalyst feed port, and a tank bottom outlet; a control valve is arranged on a pipeline connected with the catalyst outlet, two sides of the control valve are connected with a bypass pipeline, and two ends of the bypass pipeline are respectively connected with a catalyst inlet of the first catalyst storage tank and a tank bottom outlet through the control valve; the first catalyst storage tank is located upstream of the circulation pump.

6. The apparatus of claim 1, wherein a catalyst regulating valve for catalyst flow regulation and a flow monitor for flow metering are installed on the liquid catalyst circulation line.

7. The apparatus according to claim 1, wherein a liquid distributor for distributing the liquid catalyst is installed at an upper portion of the reaction tower.

8. The apparatus as claimed in claim 2, wherein the bottom outlet of the safety demister is connected to the second catalyst storage tank through a pipe provided with a valve.

9. The device according to claim 8, wherein a catalyst addition port is provided on a wall body at a middle portion between the reaction zone and the defoaming zone of the safety demister; and the bottom outlet of the second catalyst storage tank is connected with a catalyst adding port in the middle of the security demister through a pipeline provided with a delivery pump.

10. The apparatus as claimed in claim 1, further comprising a control system, wherein pressure, temperature and liquid level monitoring systems are arranged on the reaction tower, the first catalyst storage tank, the circulating heat exchanger, the security demister and the condenser of the apparatus and are respectively mounted on the corresponding pressure detection port and the temperature detection port, and a monitoring control system for monitoring and controlling the temperature and flow and a monitoring control system for opening and closing a valve are arranged on each connecting pipeline.

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