CN215087050U - Chlorine dioxide disinfection equipment inner chamber reaction system - Google Patents

Abstract

A chlorine dioxide disinfection equipment inner chamber reaction system relates to the technical field of disinfection equipment and comprises a reactor, a reaction chamber, an air guide funnel, a stirrer, a first motor, a liquid guide pipe, a liquid outlet pipe, a blocking plug, a screw rod, a second motor, a control panel and a chlorine dioxide sensor; the reaction chamber is arranged in the reactor; the large opening end of the air guide funnel is arranged on the reaction chamber, the small opening end of the air guide funnel penetrates through the upper surface of the reactor, and the air guide funnel is communicated with the reaction chamber; a sodium chlorate supply assembly and a hydrochloric acid supply assembly are respectively arranged on the two transverse sides of the reactor, and both the sodium chlorate supply assembly and the hydrochloric acid supply assembly penetrate through the reactor and are communicated with the reaction chamber; the stirrer is rotatably arranged in the reaction chamber; the first motor is arranged at the bottom of the reactor and is in driving connection with the stirrer. The utility model discloses can make the raw materials reaction more abundant during the use to judge the time of the abundant reaction of raw materials and discharge reaction product from the reacting chamber automatically by the machine is automatic, the flexibility is high during the use, and the practicality is strong.

Description

Chlorine dioxide disinfection equipment inner chamber reaction system

Technical Field

The utility model relates to a disinfecting equipment technical field especially relates to chlorine dioxide disinfecting equipment inner chamber reaction system.

Background

Chlorine dioxide is a gas from yellow green to orange yellow, and is mainly used for bleaching paper pulp, fibers, wheat flour and starch, and refining and bleaching oil, beeswax and the like. The disinfection and sterilization treatment of the drinking water is a safe and nontoxic green disinfectant which is internationally recognized.

Chlorine dioxide disinfectants produced in the prior art generally adopt chlorine dioxide disinfection equipment, and the chlorine dioxide and chlorine compound disinfectants can be generated by adding sodium chlorate and concentrated hydrochloric acid into the equipment, and simultaneously water and sodium chloride are generated. In the actual use process of the chlorine dioxide disinfection equipment, because the operator cannot grasp the reaction time well and the reaction of the raw materials is insufficient, a large amount of waste of the raw materials is caused, and the production cost of the disinfectant is greatly increased. Based on the existing problems, an inner chamber reaction system of chlorine dioxide disinfection equipment is provided.

SUMMERY OF THE UTILITY MODEL

Objects of the invention

In order to solve the technical problems existing in the background technology, the utility model provides an inner cabin reaction system of chlorine dioxide disinfection equipment, which can solve the problem of raw material waste caused by insufficient reaction of sodium chlorate and concentrated hydrochloric acid in the prior art by arranging a stirrer; through setting up chlorine dioxide sensor, can solve among the prior art problem that operating personnel do not master well to reaction time.

(II) technical scheme

The utility model provides an inner cabin reaction system of chlorine dioxide disinfection equipment, which comprises a reactor, a reaction chamber, an air guide funnel, a stirrer, a first motor, a liquid guide pipe, a liquid outlet pipe, a blocking plug, a screw rod, a second motor, a control panel and a chlorine dioxide sensor;

the reaction chamber is arranged in the reactor; the large opening end of the air guide funnel is arranged on the reaction chamber, the small opening end of the air guide funnel penetrates through the upper surface of the reactor, and the air guide funnel is communicated with the reaction chamber; a sodium chlorate supply assembly and a hydrochloric acid supply assembly are respectively arranged on the two transverse sides of the reactor, and both the sodium chlorate supply assembly and the hydrochloric acid supply assembly penetrate through the reactor and are communicated with the reaction chamber; the stirrer is rotatably arranged in the reaction chamber; the first motor is arranged at the bottom of the reactor and is in driving connection with the stirrer;

the liquid guide pipe penetrates through the reactor and is arranged on the reaction chamber, the liquid guide pipe is communicated with the reaction chamber, and the lower end of the liquid guide pipe is a closed end; the liquid outlet pipe is arranged on one lateral side of the liquid guide pipe and communicated with the liquid guide pipe; the blocking plug is arranged on the inner wall of the liquid guide pipe in a sliding manner; the screw rod is rotationally arranged on the inner wall of the bottom of the liquid guide pipe and is in threaded connection with the blocking plug; the second motor is arranged at the bottom of the liquid guide pipe and is in driving connection with the screw rod; the control panel is arranged on the reactor, a processor is arranged on the control panel, and the processor is in control connection with the sodium chlorate supply assembly, the hydrochloric acid supply assembly, the first motor and the second motor; the chlorine dioxide sensor is arranged on the inner wall of the air guide funnel and is in communication connection with the processor.

Preferably, the reactor also comprises supporting legs, wherein the supporting legs are arranged at the bottom of the reactor, and anti-slip pads are arranged at the bottoms of the supporting legs and are square pads or cylindrical pads.

Preferably, a sliding groove is formed in the inner wall of the liquid guide pipe; a sliding block is arranged on one transverse side of the blocking plug and is in sliding connection with the liquid guide pipe, and the sliding block is positioned in the sliding groove; the sliding block and the sliding groove are both of T-shaped structures.

Preferably, the sodium chlorate supply assembly comprises a first liquid storage tank, a first material blocking plug, a first liquid pump and a first connecting pipe; the first liquid storage tank is arranged on one lateral side of the reactor, and a first charging hole is formed in the first liquid storage tank; the first material blocking plug is arranged in the first material inlet; the first liquid pump is arranged in the first liquid storage tank, and the processor is connected with the first liquid pump in a control mode; two ends of the first connecting pipe are respectively communicated with the first liquid pump and the reaction chamber.

Preferably, a first pull ring is arranged on the first material blocking plug, the first pull ring is of a square annular structure or a circular annular structure, and an anti-skid sleeve is arranged on the first pull ring.

Preferably, the hydrochloric acid supply assembly comprises a second liquid storage tank, a second material blocking plug, a second liquid pump and a second connecting pipe; the second liquid storage tank is arranged on the other side of the reactor in the transverse direction, and a second charging hole is formed in the second liquid storage tank; the second material blocking plug is arranged in the second material inlet; the second liquid pump is arranged in the second liquid storage tank, and the processor is in control connection with the second liquid pump; and two ends of the second connecting pipe are respectively communicated with the second liquid pump and the reaction chamber.

Preferably, the second stopper is provided with a second pull ring, the second pull ring is of a square annular structure or a circular annular structure, and the second pull ring is provided with an anti-slip sleeve.

Compared with the prior art, the above technical scheme of the utility model following profitable technological effect has:

1. the utility model discloses before the use, add sodium chlorate solution from first charge door in the first liquid reserve tank, then add high concentration hydrochloric acid solution from the second charge door, again with the air guide funnel osculum end with gas collection device be connected can, simple to operate is simple.

2. The utility model discloses during the use, first drawing liquid pump and second drawing liquid pump are started in treater control, and first drawing liquid pump and second drawing liquid pump draw sodium chlorate solution in the first liquid reserve tank respectively and hydrochloric acid solution in the second liquid reserve tank get into the reacting chamber and carry out the mixing reaction, and when solution in the reacting chamber adds to a certain amount, close first drawing liquid pump and second drawing liquid pump, and the while treater starts first motor, and first motor drive agitator rotates, stirs mixed solution, reaction with higher speed.

3. The utility model discloses after using a period, chlorine dioxide sensor detects chlorine dioxide's concentration is lower, sodium chlorate reacts almost completely with hydrochloric acid this moment, be the aqueous solution of sodium chloride in the remaining solution, only contain a small amount of sodium chlorate and hydrochloric acid, chlorine dioxide sensor gives the treater with signal feedback, the start-up of treater control second motor, second motor drive lead screw rotates, the lead screw drives and blocks the downstream, block when blocking and remove to the drain pipe below, the sodium chloride solution flows from the drain pipe, can let more abundant of raw materials reaction, the waste of raw materials has been reduced, the manufacturing cost of disinfectant has been reduced.

Drawings

Fig. 1 is a schematic structural diagram of a reaction system of an inner chamber of chlorine dioxide disinfection equipment provided by the utility model.

Fig. 2 is a partial sectional view of the inner chamber reaction system of the chlorine dioxide disinfection equipment provided by the utility model.

Fig. 3 is a partially enlarged view of a portion a in fig. 2.

Fig. 4 is a block diagram of the working principle of the control system in the inner chamber reaction system of the chlorine dioxide disinfection equipment provided by the utility model.

Reference numerals: 1. a reactor; 2. supporting legs; 201. a non-slip mat; 3. a reaction chamber; 4. an air guide funnel; 5. a first liquid storage tank; 501. a first feed inlet; 6. a first stop plug; 601. a first pull ring; 7. a second liquid storage tank; 701. a second feed inlet; 8. a second material blocking plug; 801. a second tab; 9. a first liquid pump; 10. a first connecting pipe; 11. a second liquid pump; 12. a second connecting pipe; 13. a stirrer; 14. a first motor; 15. a catheter; 1501. a chute; 16. a liquid outlet pipe; 17. blocking the plug; 1701. a slider; 18. a screw rod; 19. a second motor; 20. a control panel; 21. a chlorine dioxide sensor; 22. a processor.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

As shown in fig. 1-4, the inner chamber reaction system of chlorine dioxide disinfection equipment provided by the present invention comprises a reactor 1, a reaction chamber 3, an air guide funnel 4, a stirrer 13, a first motor 14, a liquid guide tube 15, a liquid outlet tube 16, a blocking plug 17, a screw rod 18, a second motor 19, a control panel 20 and a chlorine dioxide sensor 21;

the reaction chamber 3 is arranged in the reactor 1; the large-opening end of the gas guide funnel 4 is arranged on the reaction chamber 3, the small-opening end of the gas guide funnel 4 penetrates through the upper surface of the reactor 1, and the gas guide funnel 4 is communicated with the reaction chamber 3; a sodium chlorate supply assembly and a hydrochloric acid supply assembly are respectively arranged at two transverse sides of the reactor 1, and both the sodium chlorate supply assembly and the hydrochloric acid supply assembly penetrate through the reactor 1 and are communicated with the reaction chamber 3; the stirrer 13 is rotatably arranged in the reaction chamber 3; the first motor 14 is arranged at the bottom of the reactor 1, and the first motor 14 is in driving connection with the stirrer 13;

the liquid guide pipe 15 penetrates through the reactor 1 and is arranged on the reaction chamber 3, the liquid guide pipe 15 is communicated with the reaction chamber 3, and the lower end of the liquid guide pipe 15 is a closed end; the liquid outlet pipe 16 is arranged at one lateral side of the liquid guide pipe 15, and the liquid outlet pipe 16 is communicated with the liquid guide pipe 15; the blocking plug 17 is arranged on the inner wall of the liquid guide pipe 15 in a sliding way; the screw rod 18 is rotationally arranged on the inner wall of the bottom of the liquid guide tube 15, and the screw rod 18 is in threaded connection with the blocking plug 17; the second motor 19 is arranged at the bottom of the liquid guide tube 15, and the second motor 19 is in driving connection with the screw rod 18; the control panel 20 is arranged on the reactor 1, the processor 22 is arranged on the control panel 20, and the processor 22 is in control connection with the sodium chlorate supply component, the hydrochloric acid supply component, the first motor 14 and the second motor 19; the chlorine dioxide sensor 21 is arranged on the inner wall of the air guide funnel 4, and the chlorine dioxide sensor 21 is in communication connection with the processor 22.

In an optional embodiment, still include supporting leg 2, supporting leg 2 sets up in reactor 1 bottom, and supporting leg 2 bottom is provided with slipmat 201, and slipmat 201 is square pad or cylindrical pad, through setting up supporting leg 2 and slipmat 201, can guarantee the utility model discloses stability when using.

In an alternative embodiment, a sliding groove 1501 is formed on the inner wall of the catheter 15; a slide block 1701 is arranged on one transverse side of the blocking plug 17, the slide block 1701 is in sliding connection with the liquid guide pipe 15, and the slide block 1701 is positioned in the sliding groove 1501; the slider 1701 and the runner 1501 are both T-shaped structures, and by arranging the slider 1701 and the runner 1501, the stability of the stopper 17 sliding in the catheter 15 can be ensured.

In an alternative embodiment, the sodium chlorate supply assembly comprises a first liquid storage tank 5, a first stopper 6, a first liquid pump 9 and a first connecting pipe 10; the first liquid storage tank 5 is arranged on one lateral side of the reactor 1, and a first charging hole 501 is arranged on the first liquid storage tank 5; the first stop plug 6 is arranged in the first charging hole 501; the first liquid pump 9 is arranged in the first liquid storage tank 5, and the processor 22 is in control connection with the first liquid pump 9; both ends of the first connection pipe 10 are respectively communicated with the first liquid pump 9 and the reaction chamber 3.

In an optional embodiment, a first pull ring 601 is arranged on the first stopper 6, the first pull ring 601 is a square ring structure or a circular ring structure, and an anti-slip sleeve is arranged on the first pull ring 601, so that the first stopper 6 can be conveniently taken down from the first liquid storage tank 5.

In an alternative embodiment, the hydrochloric acid supply assembly comprises a second liquid storage tank 7, a second stopper 8, a second liquid pump 11 and a second connecting pipe 12; the second liquid storage tank 7 is arranged at the other side of the reactor 1, and a second charging hole 701 is formed in the second liquid storage tank 7; the second material blocking plug 8 is arranged in the second feeding hole 701; the second liquid pump 11 is arranged in the second liquid storage tank 7, and the processor 22 is in control connection with the second liquid pump 11; both ends of the second connection pipe 12 are respectively communicated with the second drawing pump 11 and the reaction chamber 3.

In an optional embodiment, a second pull ring 801 is arranged on the second stopper plug 8, the second pull ring 801 is a square ring structure or a circular ring structure, and an anti-slip sleeve is arranged on the second pull ring 801, so that the second stopper plug 8 can be conveniently taken down from the second liquid storage tank 7.

The utility model discloses before the use, add sodium chlorate solution from first charge door 501 in first liquid reserve tank 5, then add high concentration hydrochloric acid solution from second charge door 701, again with the gas guide funnel 4 osculum end with the gas collection device be connected can, during the use, treater 22 control starts first drawing liquid pump 9 and second drawing liquid pump 11, first drawing liquid pump 9 and second drawing liquid pump 11 draw sodium chlorate solution in first liquid reserve tank 5 and hydrochloric acid solution in second liquid reserve tank 7 respectively and get into reaction chamber 3 and carry out the mixing reaction, when the solution in reaction chamber 3 adds to a certain amount, close first drawing liquid pump 9 and second drawing liquid pump 11, treater 22 starts first motor 14 simultaneously, first motor 14 drives agitator 13 and rotates, stir the mixed solution, the accelerated reaction; after a period of time, the chlorine dioxide sensor 21 detects that the concentration of chlorine dioxide is low, at the moment, the sodium chlorate and hydrochloric acid almost completely react, the remaining solution is a sodium chloride aqueous solution and only contains a small amount of sodium chlorate and hydrochloric acid, the chlorine dioxide sensor 21 feeds back a signal to the processor 22, the processor 22 controls the second motor 19 to start, the second motor 19 drives the screw rod 18 to rotate, the screw rod 18 drives the blocking plug 17 to move downwards, when the blocking plug 17 moves to the lower part of the liquid outlet pipe 16, the sodium chloride solution flows out of the liquid outlet pipe 16, so that the raw materials can be reacted more fully, the waste of the raw materials is reduced, and the production cost of the disinfectant is reduced.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (7)

1. The inner chamber reaction system of the chlorine dioxide disinfection equipment is characterized by comprising a reactor (1), a reaction chamber (3), an air guide funnel (4), a stirrer (13), a first motor (14), a liquid guide pipe (15), a liquid outlet pipe (16), a blocking plug (17), a screw rod (18), a second motor (19), a control panel (20) and a chlorine dioxide sensor (21);

the reaction chamber (3) is arranged in the reactor (1); the large opening end of the air guide funnel (4) is arranged on the reaction chamber (3), the small opening end of the air guide funnel (4) penetrates through the upper surface of the reactor (1), and the air guide funnel (4) is communicated with the reaction chamber (3); a sodium chlorate supply component and a hydrochloric acid supply component are respectively arranged on the two transverse sides of the reactor (1), and both the sodium chlorate supply component and the hydrochloric acid supply component penetrate through the reactor (1) and are communicated with the reaction chamber (3); the stirrer (13) is rotatably arranged in the reaction chamber (3); the first motor (14) is arranged at the bottom of the reactor (1), and the first motor (14) is in driving connection with the stirrer (13);

the liquid guide pipe (15) penetrates through the reactor (1) and is arranged on the reaction chamber (3), the liquid guide pipe (15) is communicated with the reaction chamber (3), and the lower end of the liquid guide pipe (15) is a closed end; the liquid outlet pipe (16) is arranged at one lateral side of the liquid guide pipe (15), and the liquid outlet pipe (16) is communicated with the liquid guide pipe (15); the blocking plug (17) is arranged on the inner wall of the liquid guide pipe (15) in a sliding way; the screw rod (18) is rotationally arranged on the inner wall of the bottom of the liquid guide pipe (15), and the screw rod (18) is in threaded connection with the blocking plug (17); the second motor (19) is arranged at the bottom of the liquid guide pipe (15), and the second motor (19) is in driving connection with the screw rod (18); the control panel (20) is arranged on the reactor (1), the control panel (20) is provided with a processor (22), and the processor (22) is in control connection with the sodium chlorate supply assembly, the hydrochloric acid supply assembly, the first motor (14) and the second motor (19); the chlorine dioxide sensor (21) is arranged on the inner wall of the air guide funnel (4), and the chlorine dioxide sensor (21) is in communication connection with the processor (22).

2. The chlorine dioxide disinfection equipment inner chamber reaction system of claim 1, further comprising a support leg (2), wherein the support leg (2) is arranged at the bottom of the reactor (1), the bottom of the support leg (2) is provided with a non-slip mat (201), and the non-slip mat (201) is a square mat or a cylindrical mat.

3. The inner chamber reaction system of chlorine dioxide disinfection equipment as claimed in claim 1, wherein the inner wall of the liquid guide tube (15) is provided with a chute (1501); a sliding block (1701) is arranged on one transverse side of the blocking plug (17), the sliding block (1701) is in sliding connection with the liquid guide pipe (15), and the sliding block (1701) is positioned in the sliding groove (1501); the slide block (1701) and the sliding groove (1501) are both of T-shaped structures.

4. A chlorine dioxide disinfection apparatus inner chamber reaction system as claimed in claim 1, wherein the sodium chlorate supply assembly comprises a first liquid storage tank (5), a first stopper (6), a first liquid pump (9) and a first connecting pipe (10); the first liquid storage tank (5) is arranged on one lateral side of the reactor (1), and a first charging opening (501) is arranged on the first liquid storage tank (5); the first material blocking plug (6) is arranged in the first feeding hole (501); the first liquid pump (9) is arranged in the first liquid storage tank (5), and the processor (22) is in control connection with the first liquid pump (9); two ends of the first connecting pipe (10) are respectively communicated with the first liquid pump (9) and the reaction chamber (3).

5. The inner chamber reaction system of chlorine dioxide disinfection equipment according to claim 4, wherein the first stopper plug (6) is provided with a first pull ring (601), the first pull ring (601) is a square ring structure or a circular ring structure, and the first pull ring (601) is provided with an anti-slip sleeve.

6. A chlorine dioxide disinfection apparatus interior compartment reaction system as claimed in claim 1, wherein the hydrochloric acid supply assembly comprises a second liquid storage tank (7), a second stopper (8), a second liquid pump (11) and a second connecting pipe (12); the second liquid storage tank (7) is arranged on the other side of the reactor (1) in the transverse direction, and a second charging hole (701) is formed in the second liquid storage tank (7); the second material blocking plug (8) is arranged in the second feeding hole (701); the second liquid pump (11) is arranged in the second liquid storage tank (7), and the processor (22) is in control connection with the second liquid pump (11); two ends of the second connecting pipe (12) are respectively communicated with the second liquid pump (11) and the reaction chamber (3).

7. The inner chamber reaction system of chlorine dioxide disinfection equipment according to claim 6, wherein the second stopper plug (8) is provided with a second pull ring (801), the second pull ring (801) is a square ring structure or a circular ring structure, and the second pull ring (801) is provided with an anti-slip sleeve.

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