CN108686612A - Tubular type countercurrent flow reactor - Google Patents

Abstract

The invention discloses a kind of tubular type countercurrent flow reactors, including heater, feed heat exchanger tube and discharging heat exchanger tube, it further include center heat pipe, center heat pipe is twist looped around outside heater, charging heat exchanger tube and discharging heat exchanger tube are twist looped around outside the heat pipe of center, charging heat exchanger tube is with the heat exchanger tube that discharges along central hot caliber to being arranged alternately, the charging heat exchanger tube of adjacent two layers joins end to end and forms feeding pipe successively, the discharging heat exchanger tube of adjacent two layers joins end to end and forms discharging pipeline successively, outermost charging heat exchanger tube is provided with feed inlet, outermost discharging heat exchanger tube is provided with discharge port, the charging heat exchanger tube of innermost layer is connected with one end of center heat pipe, the discharging heat exchanger tube of innermost layer is connected with the other end of center heat pipe, make feeding pipe and discharging pipeline connection and forms complete material flow passage.This reactor can improve reaction rate and reactivity, and reduce energy consumption, save production cost.

Description

Tubular type countercurrent flow reactor

Technical field

The present invention relates to reactor fields, and in particular to a kind of tubular type countercurrent flow reactor.

Background technology

During various chemical substances and bronsted lowry acids and bases bronsted lowry (such as schreyerite Leaching Vanadium and iron), acidleach at present or the dipped journey of alkali Using reaction kettle, i.e., mineral aggregate to be treated is added in reaction kettle and is reacted, influence material reaction rate because Element includes:The grain size (specific surface area) of material, the acid-base value of medium, reaction temperature, reaction pressure, reaction time etc., therefore need Ensure higher reaction temperature in reaction kettle.It is handled using reaction kettle, it can only be in the mineral aggregate processing that reaction kettle will be added After the material in reaction kettle could be taken out, add next batch mineral aggregate and handled, and at each batch mineral aggregate It needs that the reduction of its temperature, next batch mineral aggregate is waited for reheat after reason, causes entire technological process that cannot continuously implement And energy waste is big, it is of high cost to examine.

Reactor is widely used in the fields such as chemical industry, chemistry, provides reacting environment for the reaction of material, while material being added Heat is to suitable temperature, to ensure reaction efficiency.Therefore it is handled using heat transfer reactor, can realize wanting for continuous processing Ask, but current tubular reactor structure be usually in the reactor between having heaters is installed, heat exchanger tube is more in a manner of coil pipe Layer winding is arranged in outside heater, and material is gradually flowed to heater direction from outside feed pipe by coil pipe, temperature by Edge up height, and finally temperature also reaches the requirement that reaction temperature meets reaction treatment when inside coil outside heater, finally again Pass through discharge nozzle output-response device.Such as application No. is 201220350956.0 utility model patent, disclosed pipe reactions Device includes that there are one reactors, and the coil pipe being located in reactor tank body is to be coiled at least two layers along concentric axis by a pipe One end of the above coil pipe, coil pipe connects feed inlet, and the other end connects discharge port, hanger is evenly equipped on the circumferential inner wall of tank body, A hook mutually hooked with outer layer coil pipe corresponding position is respectively equipped on each hanger.In use, material is passed through from feed inlet, from Discharge port is discharged, and the heater in reactor tank body heats material.

Using existing tubular reactor, the material being discharged from discharge nozzle causes thermal energy to waste since temperature is higher, together When processing before material when entering feed pipe temperature it is relatively low, to be heated to reaction temperature, and need a large amount of thermal energy, therefore energy consumption It is very high, improve production cost.

Invention content

Technical problem to be solved by the invention is to provide a kind of waste heats for the high-temperature material completed using reaction to newly adding The low-temperature material entered is heated, and is made full use of thermal energy to realize, is reduced the tubular type countercurrent flow reactor of energy consumption.

The present invention solves the used tubular type countercurrent flow reactor of its technical problem, includes the heating in shell Device, charging heat exchanger tube and discharging heat exchanger tube,

Further include center heat pipe, the center heat pipe is twist looped around outside heater, the charging heat exchanger tube and is gone out Material heat exchanger tube is twist looped around outside the heat pipe of center, and charging heat exchanger tube and discharging heat exchanger tube are in central hot pipe radial direction On be set as multilayer, and feed heat exchanger tube with the heat exchanger tube that discharges along central hot caliber to being arranged alternately, the charging of adjacent two layers is changed Heat pipe joins end to end and forms feeding pipe successively, and the discharging heat exchanger tube of adjacent two layers joins end to end and forms discharge nozzle successively Road, outermost charging heat exchanger tube are provided with feed inlet, and outermost discharging heat exchanger tube is provided with discharge port, the charging of innermost layer Heat exchanger tube is connected with one end of center heat pipe, and the discharging heat exchanger tube of innermost layer is connected with the other end of center heat pipe, makes feed pipe Road and discharging pipeline connection simultaneously form complete material flow passage.

Further, center heat pipe, multilayer charging heat exchanger tube and multilayer discharging heat exchanger tube are an integrally formed pipeline.

Further, the inner wall of the shell is provided with thermal insulation layer.

Further, heat conduction protective case is provided in the shell, the heater is set to the inside of heat conduction protective case, Center heat pipe, charging heat exchanger tube and discharging heat exchanger tube are arranged except heat conduction protective case.

Compared with prior art, the beneficial effects of the invention are as follows:Heater is by surrounding space heating to suitable material Material to be reacted is passed through charging heat exchanger tube by the high temperature of reaction from feed inlet, material from outermost charging heat exchanger tube successively Heat exchanger tube is fed by each layer, finally reaches the charging heat exchanger tube of innermost layer, in this process, the distance of material to heater It is gradually reduced, temperature gradually rises, and subsequently into center heat pipe, fill process finishes.Material is most interior from center heat pipe entrance again The discharging heat exchanger tube of layer, then in turn through outermost discharge nozzle is reached after multilayer discharging heat exchanger tube, discharging process finishes, During discharging, material exchanges heat with the new material into charging heat exchanger tube, to make the material moved along feeding pipe Temperature gradually rises, and is continuously decreased along the temperature of charge that discharging pipeline moves, due to charging heat exchanger tube and discharging heat exchanger tube It is arranged alternately twist and successively, the discharging material-heat-exchanging area in the feed material in feeding pipe and discharging pipeline is non- Normal is big, can ensure fully to exchange heat between feed material and discharging material, in this way, material is in several layers of chargings close to heater After heat exchanger tube, center heat pipe and discharging heat exchange tube reaction, during being successively discharged from discharging heat exchanger tube, the heat of carrying is big Part can be transferred to the new reaction mass for entering charging heat exchanger tube, and the temperature of discharging material is greatly lowered.In general, from The material of discharge port discharge is can be controlled in the material temperature difference entered from feed inlet within 10 degrees Celsius, and most of heat rests on It is recycled in reactor, to reduce the energy consumption of heater, saves production cost, and pyroreaction field can be provided for material Institute solves the problems, such as that prior art high energy consumption, reactivity are low.

Description of the drawings

Fig. 1 is the main view schematic cross-sectional view of the present invention.

Fig. 2 to Fig. 5 is the bending and molding schematic diagram of present invention charging heat exchanger tube and the heat exchanger tube that discharges.

Reference numeral:2-heaters;3-charging heat exchanger tubes;31-feed inlets;32-feed zones;33-the second connection Section;4-discharging heat exchanger tubes;41-discharge ports;42-discharging sections;43-the first linkage section;5-thermally insulating housings;6-heat conduction are protected Set;7-center heat pipes.

Specific implementation mode

Present invention will be further explained below with reference to the attached drawings and examples.

Include that heater 2 in shell, charging are changed as shown in Figure 1, the tubular type countercurrent flow reactor of the present invention Heat pipe 3 and discharging heat exchanger tube 4,

Further include center heat pipe 7, the center heat pipe 7 is twist looped around outside heater 2, the charging heat exchanger tube 3 It is twist looped around outside center heat pipe 7 with discharging heat exchanger tube 4, charging heat exchanger tube 3 and discharging heat exchanger tube 4 are in center heat pipe 7 are set as multilayer in the radial direction, and feed heat exchanger tube 3 and be arranged along 7 radially alternating of center heat pipe with discharging heat exchanger tube 4, adjacent Two layers of charging heat exchanger tube 3 joins end to end and forms feeding pipe successively, and the discharging heat exchanger tube 4 of adjacent two layers joins end to end successively And discharging pipeline is formed, outermost charging heat exchanger tube 3 is provided with feed inlet 31, and outermost discharging heat exchanger tube 4 is provided with out The charging heat exchanger tube 3 of material mouth 41, innermost layer is connected with one end of center heat pipe 7, discharging heat exchanger tube 4 and the center heat pipe of innermost layer 7 other end is connected, and makes feeding pipe and discharging pipeline connection and forms complete material flow passage.

Specifically, as shown in Figure 1, heater 2 is located at the bosom of housing cavity, center heat pipe 7 be looped around heater 2 it Outside, charging heat exchanger tube 3 is set as multilayer along center heat pipe 7 is radial, and by being followed successively by 3a, 3b, 3c except interior ..., discharge heat exchanger tube 4 are set as multilayer along center heat pipe 7 is radial, by being followed successively by 4a, 4b, 4c except interior ..., charging heat exchanger tube 3 and discharging heat exchanger tube 4 along 7 radially alternating of center heat pipe be arranged, then center heat pipe 7, charging heat exchanger tube 3 and discharge heat exchanger tube 4 form pipeline from it is interior to It is followed successively by center heat pipe 7 outside, charging heat exchanger tube 3a, discharging heat exchanger tube 4a, charging heat exchanger tube 3b, discharging heat exchanger tube 4b, feeds and changes Heat pipe 3c, discharging heat exchanger tube 4c ....In addition, adjacent with center heat pipe 7 can also be discharging heat exchanger tube 4.

Heater 2 is arranged in the center of reaction chamber, for material to be heated to suitable high temperature, improves the anti-of material Rate is answered, existing arbitrary heating device specifically can be used in heater 2, such as electric heating equipment, flue gas or steam-heating apparatus, combustion Burn heating device etc..Center heat pipe 7, charging heat exchanger tube 3 and the heat exchanger tube 4 that discharges are protected using the high material of existing thermal coefficient Demonstrate,prove good heat exchange rate.Caliber, the number of plies, length and the screw pitch of center heat pipe 7, charging heat exchanger tube 3 and the heat exchanger tube 4 that discharges Etc. parameters can there are many, the reactor of multiple specifications can be designed, be manufactured into, according to specific reaction mass type, grain Diameter, reaction time etc. are determined.Feed inlet 31 is used to material to be reacted being passed through charging heat exchanger tube 3, and feed inlet 31 can be with Material delivery pipe is connected, using pump as the power of Flow of Goods and Materials.

Adjacent two layers feed between heat exchanger tube 3, between adjacent two layers discharging heat exchanger tube 4, the charging heat exchanger tube 3 of innermost layer with The pipe fitting phase of bending may be used between center heat pipe 7 and between discharging heat exchanger tube 4 and the center heat pipe 7 of innermost layer Even, it is preferred that center heat pipe 7, multilayer charging heat exchanger tube 3 and multilayer discharging heat exchanger tube 4 are an integrally formed pipeline, sealing Property is more preferable.Specifically, charging heat exchanger tube 3 uses a pipeline bending and molding with discharging heat exchanger tube 4, as shown in Fig. 2, in pipeline Pipeline is divided into feed zone 32 and discharging section 42 by point a, and since at a of midpoint, feed zone 32 is bent into the spiral of certain length Shape obtains center heat pipe 7, specifically as shown in figure 3, outward bending then by discharging section 42 from a of midpoint, is bent First linkage section 43, then again by 42 bending of discharging section twist, obtain the discharging heat exchanger tube 4 of innermost layer, discharging heat exchange Pipe 4 is looped around except center heat pipe 7, and discharging heat exchanger tube 4 can be in direct contact with center heat pipe 7 to ensure heat exchange efficiency, also may be used With with spacing appropriate, the pipeline after bending is as shown in Figure 4.Then bending feed zone 32, second be bent connect again Section 33 is connect, specifically as shown in figure 5, then proceeding to bending feed zone 32, obtains the charging heat exchanger tube 3 of innermost layer, charging heat exchange Pipe 3 is looped around except the discharging heat exchanger tube 4 of innermost layer, then bending discharging section 42 again.By repeatedly, alternately bending feed Section 32 and discharging section 42, it will be able to obtain integrally formed center heat pipe 7, multilayer charging heat exchanger tube 3 and multilayer discharging heat exchanger tube 4。

The inner wall of the shell is provided with thermal insulation layer 5, and thermal insulation layer 5 uses existing conventional heat preservation material, plays reduction heat The effect of loss improves heat utilization efficiency, while playing the role of protection charging heat exchanger tube 3 and discharging heat exchanger tube 4.The feed inlet 31 extend to discharge port 41 except thermally insulating housing 5, the material being conveniently passed through after the material and discharge reaction that react.

Heat conduction protective case 6 is provided in the shell, the heater 2 is set to the inside of heat conduction protective case 6, central hot Pipe 7, charging heat exchanger tube 3 and discharging heat exchanger tube 4 are arranged except heat conduction protective case 6.Heat conduction protective case 6 is high using thermal coefficient Material, heat conduction protective case 6 separate heater 2 and charging heat exchanger tube 3 and discharging heat exchanger tube 4, can avoid maintenance, replace heater Charging heat exchanger tube 3 and discharging heat exchanger tube 4 are impacted when 2.

The course of work of this reactor is:Using heater 2 by center heat pipe 7 and closest to several layers of chargings of heater 2 Heat exchanger tube 3 and discharging heat exchanger tube 4 are heated to suitable high temperature, which determines according to specific material, it is ensured that material can be fast Speed reaction.Material to be reacted is inputted into outermost charging heat exchanger tube 3 by the actuating units such as pumping, material is from outside to inside successively Heat exchanger tube 3 is fed by each layer, then enters center heat pipe 7 from the charging heat exchanger tube 3 of innermost layer, after center heat pipe 7 again Into the discharging heat exchanger tube 4 of innermost layer, then changed successively by the discharging of each layer from the inside to the outside since the discharging heat exchanger tube 4 of innermost layer After heat pipe 4, it is discharged from the discharge port 41 of outermost discharging heat exchanger tube 4.

In above process, material is gradually reduced when being moved in feeding heat exchanger tube 3 at a distance from heater 2, temperature by Edge up height, and material gradually starts to react, and when material enters center heat pipe 7, temperature reaches highest, realizes fast reaction, then into Enter to discharge heat exchanger tube 4, and temperature continuously decreases, and is finally discharged.

After by the high-temperature area reaction near heater 2, the material of high temperature is discharged material from discharging heat exchanger tube 4, by It is arranged alternately in charging heat exchanger tube 3 and discharging heat exchanger tube 4, when by each layer of discharging heat exchanger tube 4, in the heat exchanger tube 4 that discharges Material can all exchange heat with the material in adjacent charging heat exchanger tube 3, after repeatedly exchanging heat, the object in the heat exchanger tube 4 that discharges Material temperature degree continuously decreases, and the temperature of charge fed in heat exchanger tube 3 gradually rises, and the material in the heat exchanger tube 4 that discharges carries big Partial heat energy can all be transferred to charging heat exchanger tube 3 in reaction mass, in this way from discharge port 41 be discharged temperature of charge with from Feed inlet 31 is passed through the temperature of charge difference very little of charging heat exchanger tube 3, can control within 10 degrees Celsius, the material after reaction The heat accounting very little taken away, most heats all rest on inside reactor and are recycled, greatly improved Heat utilization efficiency.By taking certain reaction as an example, reaction temperature is controlled at 90 to 100 degrees Celsius, when using traditional reactor, is needed object Material is heated to 90 to 100 degrees Celsius from the room temperature of 20 degrees centigrades, is expelled directly out after the completion of material reaction, the material temperature of discharge Degree at 90 to 100 degrees Celsius, and the temperature of charge being newly added be room temperature, need using heating device by the material being newly added again 90 to 100 degrees Celsius are heated to, energy consumption is very high.And after using the application, 2 needs of heater add the material being passed through at first Heat is discharged after material reaction to 90 to 100 degrees Celsius, and the temperature of charge being discharged from discharge port 41 is at 25 to 35 degrees Celsius, big portion Point heat transfer is to the material being newly added, and the heat taken away is considerably less, and heater 2, which only requires supplementation with a small amount of thermal energy, to be made The high-temperature area of reactor keeps high temperature that can reduce by 85% to 90% energy consumption compared with prior art, greatly reduce life Produce cost.

Claims (4)

1. tubular type countercurrent flow reactor includes heater (2), charging heat exchanger tube (3) and discharging heat exchange in shell It manages (4), which is characterized in that

Further include center heat pipe (7), the center heat pipe (7) is twist looped around heater (2) outside, the charging heat exchanger tube (3) and discharging heat exchanger tube (4) is twist looped around center heat pipe (7) outside, charging heat exchanger tube (3) and discharging heat exchanger tube (4) It is set as multilayer in the radial direction in center heat pipe (7), and feeds heat exchanger tube (3) with discharging heat exchanger tube (4) along center heat pipe (7) radially alternating is arranged, and the charging heat exchanger tube (3) of adjacent two layers joins end to end and forms feeding pipe successively, adjacent two layers Discharging heat exchanger tube (4) joins end to end and forms discharging pipeline successively, and outermost charging heat exchanger tube (3) is provided with feed inlet (31), outermost discharging heat exchanger tube (4) is provided with discharge port (41), charging heat exchanger tube (3) and the center heat pipe (7) of innermost layer One end be connected, the discharging heat exchanger tube (4) of innermost layer is connected with the other end of center heat pipe (7), makes feeding pipe and discharge nozzle Road is connected to and forms complete material flow passage.

2. tubular type countercurrent flow reactor according to claim 1, which is characterized in that center heat pipe (7), multilayer charging are changed Heat pipe (3) and multilayer discharging heat exchanger tube (4) are an integrally formed pipeline.

3. tubular type countercurrent flow reactor according to claim 1, which is characterized in that the inner wall of the shell be provided with every Thermosphere (5).

4. tubular type countercurrent flow reactor according to claim 3, which is characterized in that be provided with heat conduction guarantor in the shell Sheath (6), the heater (2) are set to the inside of heat conduction protective case (6), and center heat pipe (7) feeds heat exchanger tube (3) and goes out Expect that heat exchanger tube (4) is arranged except heat conduction protective case (6).