CN215540903U - Continuous self-control reaction device - Google Patents

Abstract

A continuous self-control reaction device belongs to the technical field of self-control reaction devices. Feeding line is linked together with 1# reation kettle's feed end, pneumatic pipeline is linked together with feeding line, the pneumatic valve has concatenated on the pneumatic pipeline, install the flowmeter on the pneumatic pipeline between pneumatic valve and the feeding line, the one end of falling material pipeline one is linked together with 1# reation kettle's discharge end, the other end of falling material pipeline one is linked together with 2# reation kettle's feed end, the one end of falling material pipeline two is linked together with 2# reation kettle's discharge end, the other end of falling material pipeline two is linked together with 3# reation kettle's feed end, discharge line is linked together with 3# reation kettle's discharge end, 1# reation kettle, all install the radar level gauge on 2# reation kettle and the 3# reation kettle, 2# reation kettle is less than 1# reation kettle's height, 3# reation kettle is less than 2# reation kettle's height. The utility model has the advantages of increased productivity, automatic control, high automation degree, reduced accident potential and reduced number of operators.

Description

Continuous self-control reaction device

Technical Field

The utility model relates to a continuous automatic control reaction device, belonging to the technical field of automatic control reaction devices.

Background

The traditional batch reaction device has no automatic control and can only feed materials by a single reaction kettle, the labor amount is large, the reaction raw materials can only be manually added when being added, the productivity is low, and the automation degree is low.

Disclosure of Invention

The present invention is to solve the above problems of the prior art, and further to provide a continuous self-control reaction apparatus.

The purpose of the utility model is realized by the following technical scheme:

a continuous self-control reaction device comprises: the device comprises a flowmeter, a radar level gauge, a first material pouring pipeline, a second material pouring pipeline, a No. 1 reaction kettle, a No. 2 reaction kettle, a No. 3 reaction kettle, a feeding pipeline, a pneumatic valve, a discharging pipeline and a pneumatic pipeline, wherein the feeding pipeline is communicated with the feeding end of the No. 1 reaction kettle, the pneumatic pipeline is communicated with the feeding pipeline, the pneumatic valve is connected in series on the pneumatic pipeline, the flowmeter is installed on the pneumatic pipeline between the pneumatic valve and the feeding pipeline, one end of the first material pouring pipeline is communicated with the discharging end of the No. 1 reaction kettle, the other end of the first material pouring pipeline is communicated with the feeding end of the No. 2 reaction kettle, one end of the second material pouring pipeline is communicated with the discharging end of the No. 2 reaction kettle, the other end of the second material pouring pipeline is communicated with the feeding end of the No. 3 reaction kettle, the discharging pipeline is communicated with the discharging end of the No. 3 reaction kettle, the No. 1 reaction kettle, the No. 2 reaction kettle and the No. 3 reaction kettle are both provided with the radar level gauge, the height of the No. 2 reaction kettle is lower than that of the No. 1 reaction kettle, and the height of the No. 3 reaction kettle is lower than that of the No. 2 reaction kettle.

The automatic feeding device controls the flow and the speed of feeding through the pneumatic valve and the flowmeter, realizes automatic feeding, monitors the liquid level of the reaction kettle through the radar liquid level meter, realizes automatic control through the linkage of the radar liquid level meter, the pneumatic valve and the flowmeter, reduces the feeding speed due to high liquid level, and increases the feeding speed due to low liquid level. The three reaction kettles realize continuous feeding through liquid level difference to achieve liquid level balance

The continuous automatic control reaction device realizes the continuity, increases the productivity, realizes the automatic control, has high automation degree, reduces the hidden trouble of accidents and can reduce the number of operators.

Drawings

FIG. 1 is a schematic structural view of a continuous self-control reaction apparatus according to the present invention.

The reference numeral in the figure, 1 is the flowmeter, 2 is the radar level gauge, 3 is the material pouring pipeline one, 4 is the material pouring pipeline two, 5 is 1# reation kettle, 6 is 2# reation kettle, 7 is 3# reation kettle, 8 is the feed line, 9 is the pneumatic valve, 10 is ejection of compact pipeline, 11 is pneumatic line.

Detailed Description

The utility model will be described in further detail below with reference to the accompanying drawings: the present embodiment is implemented on the premise of the technical solution of the present invention, and a detailed implementation is given, but the scope of the present invention is not limited to the following embodiments.

As shown in fig. 1, the continuous self-control reaction apparatus according to the present embodiment includes: the device comprises a flowmeter 1, a radar liquid level meter 2, a material pouring pipeline I3, a material pouring pipeline II 4, a No. 1 reaction kettle 5, a No. 2 reaction kettle 6, a No. 3 reaction kettle 7, a feeding pipeline 8, a pneumatic valve 9, a discharging pipeline 10 and a pneumatic pipeline 11, wherein the feeding pipeline 8 is communicated with the feeding end (upper end) of the No. 1 reaction kettle 5, the pneumatic pipeline 11 is communicated with the feeding pipeline 8, the pneumatic valve 9 is connected in series on the pneumatic pipeline 11, the flowmeter 1 is installed on the pneumatic pipeline 11 between the pneumatic valve 9 and the feeding pipeline 8, one end of the material pouring pipeline I3 is communicated with the discharging end (lower end) of the No. 1 reaction kettle 5, the other end of the material pouring pipeline I3 is communicated with the feeding end of the No. 2 reaction kettle 6, one end of the material pouring pipeline II 4 is communicated with the discharging end of the No. 2 reaction kettle 6, the other end of the material pouring pipeline II 4 is communicated with the feeding end of the No. 3 reaction kettle 7, the discharging pipeline 10 is communicated with the discharging end of the No. 3 reaction kettle 7, all install radar level gauge 2 on 1 # reation kettle 5, 2 # reation kettle 6 and 3# reation kettle 7, 2# reation kettle 6 is less than 1# reation kettle 5's height, and 3# reation kettle 7 is less than 2# reation kettle 6's height.

The feeding speed is controlled through pneumatic valve and flowmeter to the first material of this embodiment, and the big or small decision of pneumatic valve opening increases and reduces the feeding volume, and the liquid level height is low in the radar level gauge detection reation kettle, and pneumatic valve, flowmeter and radar level gauge realize the whole feeding system of chain automated control. Reach the assigned position when 1# reation kettle liquid level and will flow into 2# reation kettle through liquid level balance, reach the assigned position when 2# reation kettle liquid level and will flow into 3# reation kettle through liquid level balance, will get into next process through liquid level balance when 3# reation kettle liquid level reaches the assigned position. The automatic control mode and continuous feeding greatly save the feeding time, and the reaction is directly carried out in the next procedure, thereby greatly improving the yield. For example: the reaction time of 1 reaction kettle is 3 hours, the continuous self-control reaction device of the embodiment can react materials of 2 to 3 reaction kettles within 3 hours, and the productivity is greatly improved.

When the liquid level of the No. 1 reaction kettle reaches a specified position, the liquid flows into the No. 2 reaction kettle through the liquid level balance, and the specified position is determined by the height of a first 3 material pouring pipeline. Similarly, when the liquid level of the No. 2 reaction kettle reaches a designated position, the liquid flows into the No. 3 reaction kettle through the liquid level balance, and the height of the second pouring pipeline 4 determines the liquid level. When the liquid level of the No. 3 reaction kettle reaches a specified position, the next process is carried out through liquid level balance, and the process is determined by the height of the discharge pipeline 10.

The above description is only a preferred embodiment of the present invention, and these embodiments are based on different implementations of the present invention, and the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (2)

1. A continuous automatic control reaction device is characterized by comprising: the device comprises a flowmeter (1), a radar liquid level meter (2), a material pouring pipeline I (3), a material pouring pipeline II (4), a No. 1 reaction kettle (5), a No. 2 reaction kettle (6), a No. 3 reaction kettle (7), a feeding pipeline (8), a pneumatic valve (9), a discharging pipeline (10) and a pneumatic pipeline (11), wherein the feeding pipeline (8) is communicated with the feeding end of the No. 1 reaction kettle (5), the pneumatic pipeline (11) is communicated with the feeding pipeline (8), the pneumatic valve (9) is connected on the pneumatic pipeline (11) in series, the flowmeter (1) is installed on the pneumatic pipeline (11) between the pneumatic valve (9) and the feeding pipeline (8), one end of the material pouring pipeline I (3) is communicated with the discharging end of the No. 1 reaction kettle (5), the other end of the material pouring pipeline I (3) is communicated with the feeding end of the No. 2 reaction kettle (6), one end of the material pouring pipeline II (4) is communicated with the discharging end of the No. 2 reaction kettle (6), the other end of the material pouring pipeline II (4) is communicated with the feeding end of the 3# reaction kettle (7), the discharging pipeline (10) is communicated with the discharging end of the 3# reaction kettle (7), and radar liquid level meters (2) are arranged on the 1# reaction kettle (5), the 2# reaction kettle (6) and the 3# reaction kettle (7).

2. The continuous automatic control reaction device according to claim 1, wherein the 2# reaction kettle (6) is lower than the 1# reaction kettle (5), and the 3# reaction kettle (7) is lower than the 2# reaction kettle (6).

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