CN115524445A - Multi-reaction vessel continuous feeding on-line detection device - Google Patents

Abstract

The invention discloses an online detection device for continuous feeding of multiple reaction vessels, which belongs to the technical field of hydrogen peroxide production equipment and comprises a working box, wherein an output end of a motor A penetrates through the inner wall of a machine box, extends to the inside of the working box and is sleeved with a rotating block, the inside of the working box is annularly and symmetrically clamped with the multiple reaction vessels at equal intervals, a hollow piston is connected in the acid adding pipe in a sliding manner, the middle part of the hollow piston is communicated with an action pipe, one side of the circumferential outer wall of the action pipe is provided with a through hole, and the structures are matched with each other, so that the device can simultaneously carry out acid adding and proportioning on the multiple reaction vessels, and simultaneously, the reaction vessels are switched through the rotation of the rotating block, so that the acid adding and proportioning can be continuously carried out, and the mixing and working efficiency is improved.

Description

Multi-reaction vessel continuous feeding on-line detection device

Technical Field

The invention relates to the technical field of hydrogen peroxide production equipment, in particular to an online detection device for continuous feeding of multiple reaction vessels.

Background

Industrial hydrogen peroxide is controlled in pH value by adding acid in industrial production. The document with the prior art publication number of CN211998817U provides an acid adding device of a hydrogen peroxide production system, which can perform multiple quantitative additions by mixing of a mixing box and automatic addition of an adding box, and can perform the whole detection process circularly by automatic detection of a detector and work of an engineering pump. However, the device is used after being mixed through the mixing box, the multiple reaction vessels cannot be simultaneously carried out, the efficiency of continuous acid adding and mixing is reduced, meanwhile, the device can only detect the pH value of the current mixing box once, the detection efficiency is low, the requirements of production on different hydrogen peroxide pH values are influenced, the hydrogen peroxide pH values cannot be timely detected and mixed, the purpose of controlling the pH value is achieved, and therefore the multi-reaction vessel continuous feeding online detection device is provided.

Disclosure of Invention

1. Technical problem to be solved

The invention aims to provide an online detection device for continuous feeding of multiple reaction vessels, which realizes continuous and automatic acid feeding through the matching of an annular groove B and an acid feeding pipe, and realizes the detection of multiple reaction vessels on a fixing ring through arranging a detection box so as to solve the problems in the background technology.

2. Technical scheme

Many reaction dishes are reinforced on-line measuring device in succession, including the work box, its characterized in that: the utility model discloses a set up sour bottle, including work case, motor A, ring channel A, workstation, acidification pipe, seal block, workstation, set up sour bottle, workstation inside, the work case upside is equipped with the turning block, the turning block is driven its rotation by motor A, ring channel B has been seted up to turning block circumference outer wall, connect fixed solid fixed ring upside card on the turning block and be equipped with a plurality of reaction vessels, work case circumference inner wall one side is equipped with acidification pipe, acidification pipe one end intercommunication has L type pipeline, it is equipped with seal block A to slide in the L type pipeline, L type pipeline one end pass the work case inner wall extend to the outside and with acidification bottle communicates, acidification pipe inside sliding connection has the cavity piston, cavity piston one side is fixed and communicates there is the effect pipe, the through-hole has been seted up to effect pipe circumference outer wall one side, the effect pipe slides and is equipped with seal block B, effect pipe one end passes acidification pipe inner wall and extends to the outside and is connected with the down tube, down tube one end is equipped with the spin, spin and ring channel B roll connection, work case inner wall one side is equipped with the detection case for detect the solution performance parameter in the reaction vessel.

At least one support rod is fixedly arranged in the detection box, a limit rotating block is rotatably connected on a rotating shaft in the middle of the support rod, a limit rod is arranged in the detection box, a limit groove is formed in the middle of the limit rod, the limit rotating block is slidably connected in the limit groove, one end of the limit rod is rotatably connected with a three-connecting rod, one end of the three-connecting rod is rotatably connected with an L-shaped rod, one end of the L-shaped rod is rotatably connected with a swinging rod, one end of the swinging rod is provided with a detector, the other end of the limiting rod is rotatably connected with the middle of the swinging rod, and the rest end of the three-connecting rod is rotatably connected with one end of the supporting rod through a rotating shaft.

Detection case one end is equipped with motor B, motor B output cup joints and is fixed with the double pole, the double pole rotates with the bracing piece to be connected, double pole one end is rotated and is connected with the connecting rod, connecting rod one end is rotated and is connected with the traveller, traveller one end is rotated and is connected with V type pole, V type pole one end is rotated and is connected with the sleeve, the sleeve cover is established and is fixed in three and is connected fixed pivot in three pole one end, makes sleeve and three pole be coaxial synchronous rotation.

And an annular groove A is formed in the bottom surface of the inner part of the working box and is in sliding connection with an annular rail arranged on the bottom surface of the rotating block.

The annular groove B is arranged in a wave-shaped structure, and the slopes of two sides of one wave form of the annular groove B are different along the rotating direction of the rotating block.

One end of the acting pipe penetrates through the inner wall of the acid adding pipe, extends to the outside and is provided with a chute, an inclined rod is arranged on the upper side of the acid adding pipe, and the chute is connected with the inclined rod in a sliding mode.

One end of the inclined rod is rotatably connected with a connecting column, one end of the connecting column is rotatably connected with a rolling ball, and the rolling ball is clamped in the annular groove B.

The L-shaped pipeline is characterized in that a spring A is arranged on one side of the L-shaped pipeline, a sealing block A is arranged at the upper end of the spring A, a spring B is arranged in the acting pipe, and a sealing block B is arranged at one end of the spring B.

Two support rods are symmetrically and fixedly arranged in the detection box, other parts in the detection box are symmetrically arranged by the central axis of the two support rods, and the synchronous motion of the two groups of detectors is realized through one motor B.

One side of the supporting rod is fixedly provided with a limiting sliding barrel through a fixing block, and the limiting sliding barrel is connected with the sliding column in a sliding mode.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) According to the acid adding device, the output end of the motor A penetrates through the inner wall of the case to extend to the interior of the working case and is sleeved with the rotating block, the plurality of reaction vessels are symmetrically clamped in the working case at equal intervals in an annular shape, the interior of the acid adding pipe is connected with the hollow piston in a sliding mode, the middle of the hollow piston is communicated with the acting pipe, one side of the circumferential outer wall of the acting pipe is provided with the through hole, and the structures are matched with each other, so that the acid adding device can be used for simultaneously adding acid to the plurality of reaction vessels and matching the reaction vessels, and meanwhile, the rotating block rotates to switch the reaction vessels, so that the acid adding matching can be continuously carried out, and the mixing and working efficiency is improved.

(2) According to the invention, the detection box is arranged on one side of the upper wall in the working box, the two support rods are symmetrically and fixedly arranged in the detection box, the two limiting rotating blocks are symmetrically and rotatably connected to the rotating shaft on the lower side of the middle part of each support rod, and the output end of the motor B penetrates through the outer wall of the detection box and the inside of each support rod, extends to the outside and is sleeved with the double rods, so that when the motor B rotates below the detection instrument, the motor B can descend through the rotation of the oscillating rod, the detection instrument can extend into the reaction vessel for detection, the detection instrument can rapidly detect, the detection efficiency is improved, and meanwhile, the complexity of manual extension for detection is avoided.

(3) According to the invention, the annular groove B is arranged in a wave-shaped structure, the annular groove B is connected with the rolling ball in a rolling manner, the chute is connected with the inclined rod in a sliding manner, and the annular groove B is arranged in a wave-shaped structure, so that the connecting column moves up and down, the piston is driven by the inclined rod, and the piston can be intermittently and automatically added with acid through the acid conveying pipe, so that one-time acid adding treatment is carried out on a group of reaction vessels for one week until the requirement is met, and the condition of excessive acid adding is avoided.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is an expanded view of the overall structure of the present invention;

FIG. 3 is a cross-sectional view of the inner structure of the work box of the present invention;

FIG. 4 is an expanded view of the internal structure of the detection box of the present invention;

FIG. 5 is a schematic view of the outer side of the supporting rod of the present invention;

FIG. 6 is an enlarged view of the structure at location A of the present invention;

the reference numbers in the figures illustrate: 1. a work box; 101. an annular groove A; 102. a chassis; 103. a motor A; 104. rotating the block; 105. an annular groove B; 106. a reaction vessel; 107. a fixing ring; 2. supporting legs; 3. a window; 4. adding an acid bottle; 5. adding an acid pipe; 501. an L-shaped pipe; 502. a spring A; 503. a sealing block A; 504. a hollow piston; 505. an action tube; 506. a through hole; 507. a spring B; 508. a sealing block B; 509. a chute; 5010. a diagonal bar; 5011. connecting columns; 5012. rolling a ball; 6. a detection box; 601. a support bar; 602. a limiting rotating block; 603. a limiting rod; 604. a limiting groove; 605. a third connecting rod; 606. an L-shaped rod; 607. a swing lever; 608. a detector; 7. a motor B; 701. a double bar; 702. a connecting rod; 703. a traveler; 704. a V-shaped rod; 705. a sleeve; 706. and a limiting sliding cylinder.

Detailed Description

Referring to fig. 1-6, the present invention provides a technical solution:

an online detection device for continuous feeding of multiple reaction vessels comprises a working box 1, wherein the bottom surface of the working box 1 is provided with a plurality of supporting legs 2 at equal intervals in an annular shape, one side of the circumferential outer wall of the working box 1 is symmetrically provided with two windows 3 for observing the internal condition of the working box 1, the upper side of the working box 1 is provided with an acid adding bottle 4, the other side of the circumferential outer wall of the working box 1 is provided with a reading screen which can be used for displaying a detection result on line instead of manual analysis in real time in an online manner, the middle part of the bottom surface of the working box 1 is provided with a machine case 102, the interior of the machine case 102 is provided with a motor A103, the output end of the motor A103 penetrates through the inner wall of the machine case 102 to extend into the working box 1 and is sleeved with a rotating block 104, the circumferential outer wall of the rotating block 104 is provided with an annular groove B105, the upper side of a fixed fixing ring 107 connected with the rotating block 104 is symmetrically provided with a plurality of reaction vessels 106 at equal intervals in an annular shape, one side of the circumferential inner wall of the working box 1 is provided with an acid adding pipe 5, as shown in figure 6, the outer end of the acid adding pipe 5 is communicated with an L-shaped pipe 501, the upper end of the L-shaped pipe 501 penetrates through the inner wall of the working box 1 through a hose to extend to the outside and is communicated with the lower end of the acid adding bottle 4, the middle part of the L-shaped pipe 501 is provided with a spring A502, the upper end of the spring A502 is provided with a sealing block A503, the interior of the acid adding pipe 5 is connected with a hollow piston 504 in a sliding way, one side of the hollow piston 504 is fixed and communicated with an action pipe 505, one side of the circumferential outer wall of the action pipe 505 is provided with a through hole 506, the interior of the action pipe 505 is provided with a spring B507, the inner end of the spring B507 is provided with a sealing block B508, the two sealing blocks are respectively pushed by the two springs to slide in the corresponding pipes, the cylindrical end of the action pipe 505 penetrates through the inner wall of the acid adding pipe 5 to extend to the outside and is provided with a chute 509, the upper side of the acid adding pipe 5 is provided with an inclined rod 5010, the chute 509 is connected with the inclined rod 5010 in a sliding way, one end of the inclined rod 5010 is provided with a ball 5012, one end of the ball 5012, the annular groove B105 is connected with the ball 5012 in a rolling way, by sliding the ball 5012 inside the annular groove B105, the inclined rod 5010 can be caused to slide inside the inclined groove 509, and a displacement component of the inclined rod 5010 in the horizontal direction can push the action pipe 505 to move horizontally.

In this embodiment, the controller drives the output shaft of the motor a103 to rotate, so as to drive the rotating block 104 to rotate, the annular groove B105 of the rotating block 104 drives the rolling ball 5012 and the inclined rod 5010 to slide along the annular groove B105, the moving tracks of the rolling ball 5012 and the inclined rod 5010 are the changing structures of the annular groove B105 in the vertical direction, and the inclined rod 5010 is matched with the inclined groove 509 in a sliding manner, so that the action tube 505 can be pushed to move in the horizontal direction by the movement of the inclined rod 5010 in the vertical direction.

The horizontal movement of the action tube 505 can drive the hollow piston 504 to move, when the action tube 505 and the hollow piston 504 move to the side far away from the L-shaped pipeline 501, the sealing block B508 is tightly pressed in the through hole of the hollow piston 504, the circulation channels at two sides of the hollow piston 504 are closed, and as the space in the acid adding tube 5 near one side of the L-shaped pipeline 501 is gradually enlarged, the pressure in the space is gradually reduced, negative pressure is formed with the outside, so that the sealing block A503 is separated from and extrudes the spring A502, and at the moment, the acid solution can flow into the acid adding tube 5 through the L-shaped pipeline 501;

then, when the acting tube 505 and the hollow piston 504 move to the side close to the L-shaped pipe 501, because the space in the acid adding tube 5 close to the L-shaped pipe 501 gradually decreases, the pressure in the space gradually increases, the spring a502 pushes the sealing block a503 to close the L-shaped pipe 501, at this time, the acid solution does not flow into the acid adding tube 5 any more, and at the same time, the acid solution pushes the sealing block B508 to press the spring B507 to open the two side flow channels of the hollow piston 504, and the acid solution can enter the other side of the acid adding tube 5 through the hollow piston 504, so that the reaction vessel 106 is subjected to acid adding treatment. During the rotation of the rotation block 104, the reaction tubes 505 are moved back and forth repeatedly, so that the plurality of reaction vessels 106 can be treated by adding acid.

In order to sequentially detect a plurality of reaction vessels 106, a detection box 6 is arranged on one side of the upper wall inside a working box 1, two support rods 601 are symmetrically and fixedly arranged inside the detection box 6, two limiting rotation blocks 602 are symmetrically and rotatably connected to a rotation shaft on the lower side of the middle of each support rod 601, two limiting rods 603 are symmetrically arranged inside the detection box 6, a limiting groove 604 is formed in the middle of each limiting rod 603, the limiting rotation blocks 602 are slidably connected with the limiting grooves 604, a three-connection rod 605 is rotatably connected to the front end of each limiting rod 603 through a pin shaft, the rear end of each three-connection rod 605 is rotatably connected with an L-shaped rod 606 through a pin shaft, the upper end of each L-shaped rod 606 is rotatably connected with a swing rod 607 through a pin shaft, a detector 608 is arranged at the lower end of each swing rod 607, the rear end of each limiting rod 603 is rotatably connected with the middle of the swing rod 607 through a pin shaft, and the three-connection rod 605 is rotatably connected with one end of each support rod 601 through a rotation shaft.

In this embodiment, as shown in fig. 5, the limit rod 603, the triple rod 605, the L-shaped rod 606 and the swinging rod 607 can form a closed link rotation mechanism, the motor repeatedly rotates in the forward and reverse directions to drive the triple rod 605 to rotate around the rotation shaft, the rotation of the triple rod 605 inevitably drives the limit rod 603 and the L-shaped rod 606, both ends of which are rotatably connected, to rotate, and under the cooperation of the rotation of the limit rotation block 602 around the rotation shaft connected thereto and the sliding in the limit groove 604, taking fig. 5 as an example, when the triple rod 605 rotates in the counterclockwise direction, the L-shaped rod 606 and the swinging rod 607 rotate downward, and the limit rod 603 rotates upward, so that the included angle between the triple rod 605 and the L-shaped rod 606 and the included angle between the limit rod 603 and the swinging rod 607 gradually decrease, the included angle between the L-shaped rod 606 and the oscillating rod 607 is gradually increased, so that the oscillating rod 607 moves obliquely downward, the detector 608 can extract and detect the solution in the reaction vessel 106, in the whole process of counterclockwise rotation of the three-way rod 605, the limit rotating block 602 slides along the limit groove 604 from the middle part to one side connected with the oscillating rod 607, and then slides to the other side of the limit groove 604, so that the movement of the oscillating rod 607 is divided into two corresponding stages, the horizontal displacement component of the first stage is significantly larger than that of the second stage, and the vertical displacement component of the second stage is also significantly larger than that of the horizontal displacement component; conversely, when the three link lever 605 rotates clockwise, the swing lever 607 moves obliquely upward along the original path, and the detector 608 is retracted.

In the above embodiment, frequent positive and negative rotation of the motor easily causes damage to the motor, and therefore, a motor B7 is disposed at one end of the outer side of the detection box 6, the output end of the motor B7 penetrates through the outer wall of the detection box 6 and the inside of the support rod 601 to extend to the outside and is fixedly sleeved with the double rods 701, the front ends of the double rods 701 are rotatably connected with the connection rod 702 through the pin shaft, the front end of the connection rod 702 is rotatably connected with the sliding column 703 through the hinged support, the front end of the sliding column 703 is rotatably connected with the V-shaped rod 704 through the hinged support, the hinged support at the front end of the V-shaped rod 704 is rotatably connected with the sleeve 705, and the sleeve 705 is fixedly sleeved on the rotating shaft connected to one end of the three-connection rod 605, so that the sleeve 705 and the three-connection rod 605 rotate coaxially and synchronously.

In this embodiment, the controller drives the output shaft of the motor B7 to rotate, so as to drive the dual rod 701 to rotate, further drive the connecting rod 702 to move around the joint of the connecting rod and the dual rod 701 while rotating, further drive the V-shaped rod 704 to rotate and move through the sliding column 703, further drive the sleeve 705 to perform reciprocating rotation, and since the sleeve 705 is connected and fixed with the three-connecting rod 605 through the rotating shaft, the sleeve 705 can drive the three-connecting rod 605 to perform reciprocating rotation.

The cooperation between the structure for the device can add sour ratio to a plurality of reaction wares 106 simultaneously, rotates through turning block 105 simultaneously, carries out reaction ware 106 and switches, thereby makes it can add sour ratio continuously, has improved the efficiency of mixing and work.

Specifically, the bottom surface inside the work box 1 is provided with an annular groove a101, and the annular groove a101 is slidably connected with an annular rail arranged in the middle of the bottom surface of the rotating block 104. So that the turning block 105 can perform only a turning motion.

Further, the annular groove B105 is arranged in a wave-shaped structure, and along the rotation direction of the rotation block 104, the side slopes of two sides of one wave shape of the annular groove B105 are different. The annular groove B105 is provided in a wave-shaped structure, so that the connecting post 5011 moves up and down, and the inclined rod 5010 drives the piston 504, so that the piston can perform acid addition through the acid delivery pipe in a gap. The side slopes on two sides of one waveform are different, so that the acid solution is pumped in and extruded for different time periods.

Furthermore, a limiting sliding barrel 706 is arranged between the two support rods 601 through a fixing block, and the limiting sliding barrel 706 is connected with the sliding column 703 in a sliding manner. The rotation of the double lever 701 brings the connecting rod 702, thereby reciprocating the sliding column 703.

It should be noted that, instead of the sliding connection between the inclined rod 5010 and the inclined groove 509, another connection method may be adopted, for example, a connection column 5011 is rotatably connected to one end of the inclined rod 5010, a ball 5012 is rotatably connected to one end of the connection column 5011, the ball 5012 is clamped in the annular groove B105, the inclined rod 5010 and the action tube 505 are fixedly connected, and the connection angle between the two is not limited.

By means of the balls 5012 sliding in the annular groove B105, the connecting post 5011 is driven into rotation, the horizontal displacement component of which is compensated by the horizontal movement of the actuating tube 505.

When the device for on-line detection and continuous acidification simulation in the industrial hydrogen peroxide production process is needed, firstly, the reaction vessel 106 is placed on the fixed ring 107 to be clamped, at the moment, the output shaft of the motor A103 is driven to rotate by the controller, because the output end of the motor A103 penetrates through the inner wall of the case 102 to extend into the work box 1 and is sleeved with the rotating block 104, the circumferential outer wall of the rotating block 104 is provided with the annular groove B105, the annular groove B105 is arranged in a wave-shaped structure, the annular groove B105 is in rolling connection with the rolling ball 5012, the inclined groove 509 is in sliding connection with the inclined rod 5010, the inclined rod 5010 is arranged in a wave-shaped structure, the piston 504 is driven to reciprocate by the inclined rod 5010, at the moment, as the piston 504 reciprocates, when negative pressure is formed by inward movement, the sealing block A503 is separated, the spring B507 pushes the sealing block B508 to be closed, at the moment, acid flows in, and when the piston moves outwards, the spring A502 pushes the sealing block A503 to close, and the pressure sealing block B508 pushes away, so that the reaction vessel 106 is subjected to acidification treatment, even if the reaction vessel can be subjected to acidification treatment through an acid delivery pipe in a clearance manner, and the like, meanwhile, after the rotating block 104 drives the fixing ring 107 to rotate, when the reaction vessel 106 reaches the lower side of the detection box 6, the output shaft of the motor B7 is driven to rotate through the controller, the output end of the motor B7 penetrates through the outer wall of the detection box 6 and the inside of the supporting rod 601 to extend to the outside and is sleeved with the double rods 701, the connecting rod 702 is driven to rotate through the double rods 701, so that the sliding column 703 slides in a reciprocating manner, the sleeve 705 is driven to rotate in a reciprocating manner through the V-shaped rod 704, the angle of the three-connecting rods 605 is changed, the limiting rod 603 is reversely turned down, and the detector 608 on the swinging rod 607 reaches the reaction vessel 106 to be detected.

Claims (10)

1. Many reaction dishes are reinforced on-line measuring device in succession, including the work box, its characterized in that: an acid adding bottle is arranged at the upper side of the working box,

a rotating block is arranged in the working box and is driven by a motor A to rotate,

the circumferential outer wall of the rotating block is provided with an annular groove B, the upper side of a fixed ring which is fixedly connected with the rotating block is clamped with a plurality of reaction vessels,

an acid adding pipe is arranged on one side of the circumferential inner wall of the working box,

one end of the acid adding pipe is communicated with an L-shaped pipeline, a sealing block A is arranged in the L-shaped pipeline in a sliding mode, one end of the L-shaped pipeline penetrates through the inner wall of the working box to extend to the outside and is communicated with the acid adding bottle,

a hollow piston is connected in the acid adding pipe in a sliding way, one side of the hollow piston is fixedly communicated with an action pipe, a through hole is arranged on one side of the outer wall of the circumference of the action pipe, a sealing block B is arranged in the action pipe in a sliding way,

one end of the action pipe penetrates through the inner wall of the acid adding pipe to extend to the outside and is connected with an inclined rod, one end of the inclined rod is provided with a rolling ball, the rolling ball is in rolling connection with the annular groove B,

and a detection box is arranged on one side of the inner wall of the working box and is used for detecting the performance parameters of the solution in the reaction vessel.

2. The on-line detection device for continuous feeding of multiple reaction vessels according to claim 1, wherein: at least one supporting rod is fixedly arranged in the detection box, a rotating shaft in the middle of the supporting rod is rotatably connected with a limiting rotating block,

a limiting rod is arranged in the detection box, a limiting groove is arranged in the middle of the limiting rod, the limiting rotating block is connected in the limiting groove in a sliding manner,

one end of the limiting rod is rotatably connected with a three-connection rod, one end of the three-connection rod is rotatably connected with an L-shaped rod, one end of the L-shaped rod is rotatably connected with a swinging rod, one end of the swinging rod is provided with a detector,

the other end of the limiting rod is rotatably connected with the middle part of the swinging rod,

and the rest end of the three-connecting rod is rotatably connected with one end of the supporting rod through a rotating shaft.

3. The on-line detection device for continuous feeding of multiple reaction vessels according to claim 2, wherein: one end of the detection box is provided with a motor B, the output end of the motor B is fixedly sleeved with a double rod, the double rod is rotatably connected with a support rod,

one end of the double-rod is rotatably connected with a connecting rod, one end of the connecting rod is rotatably connected with a sliding column, one end of the sliding column is rotatably connected with a V-shaped rod, one end of the V-shaped rod is rotatably connected with a sleeve,

the sleeve is sleeved and fixed on a rotating shaft connected and fixed at one end of the three-connecting rod, so that the sleeve and the three-connecting rod rotate coaxially and synchronously.

4. The on-line detection device for continuous feeding of multiple reaction vessels according to claim 1, wherein: and an annular groove A is formed in the bottom surface of the inner part of the working box and is in sliding connection with an annular rail arranged on the bottom surface of the rotating block.

5. The on-line detection device for continuous feeding of multiple reaction vessels as recited in claim 1, wherein: the annular groove B is arranged in a wave-shaped structure, and the slopes of two sides of one wave of the annular groove B are different along the rotating direction of the rotating block.

6. The on-line detection device for continuous feeding of multiple reaction vessels as recited in claim 1, wherein: one end of the acting pipe penetrates through the inner wall of the acid adding pipe, extends to the outside and is provided with a chute, an inclined rod is arranged on the upper side of the acid adding pipe, and the chute is connected with the inclined rod in a sliding mode.

7. The on-line detection device for continuous feeding of multiple reaction vessels according to claim 1, wherein: one end of the inclined rod is rotatably connected with a connecting column, one end of the connecting column is rotatably connected with a rolling ball, and the rolling ball is clamped in the annular groove B.

8. The on-line detection device for continuous feeding of multiple reaction vessels according to claim 1, wherein: the L-shaped pipeline is characterized in that a spring A is arranged on one side of the L-shaped pipeline, a sealing block A is arranged at the upper end of the spring A, a spring B is arranged in the acting pipe, and a sealing block B is arranged at one end of the spring B.

9. The on-line detection device for continuous feeding of multiple reaction vessels according to claim 1, wherein: two support rods are symmetrically and fixedly arranged in the detection box, other parts in the detection box are symmetrically arranged by the central axis of the two support rods, and the synchronous motion of the two groups of detectors is realized through one motor B.

10. The on-line detection device for continuous feeding of multiple reaction vessels as recited in claim 1, wherein: one side of the supporting rod is fixedly provided with a limiting sliding barrel through a fixing block, and the limiting sliding barrel is connected with the sliding column in a sliding mode.

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