CN115962996A - Benzalkonium chloride suction filtration detection device and use method thereof - Google Patents

Abstract

The invention belongs to the technical field of benzalkonium chloride suction filtration detection, and particularly relates to a benzalkonium chloride suction filtration detection device and a using method thereof, wherein the benzalkonium chloride suction filtration detection device comprises primary filtration equipment, mixing equipment and detection equipment; the primary filtering equipment is used for filtering impurities in the solution to be detected; the mixing equipment is used for mixing the filtered solution to be detected with the additive; the detection device is used for detecting the solution to be detected mixed with the additive. The application can filter the solution to be detected and can mix the solution with various additives step by step and at regular time before detection, thereby completing pretreatment. The influence of solution disturbance brought by pipeline conveying on the detection result can be avoided, bubbles in the solution to be detected can be eliminated, and the detection precision is prevented from being influenced by the bubbles. This application can carry check out test set again after filtering the unqualified solution of first detection.

Description

Benzalkonium chloride suction filtration detection device and use method thereof

Technical Field

The invention belongs to the technical field of benzalkonium chloride suction filtration detection, and particularly relates to a benzalkonium chloride suction filtration detection device and a using method thereof.

Background

Benzalkonium chloride is a quaternary ammonium cationic surfactant and is a heterogeneous mixture of alkyl benzyl chlorides with various even-numbered alkyl chains. When the benzalkonium chloride is produced, suction filtration detection equipment is needed to detect the benzalkonium chloride.

As publication number CN213842826U discloses a suction filtration device for chemical industry detection, including the gravel jar, the left side of gravel jar is fixed with the trachea, tracheal right-hand member is fixed with the air pump, the upper end of gravel jar support is close to the right side and is fixed with the gravel jar, the upper end of gravel jar is fixed with the rose box, the right side of rose box is close to the lower position and has been seted up the delivery port, the upper end of rose box has the filter case lid through the bolt fastening, the left side upper surface of filter case lid is connected with the aqueduct, the lower extreme fixed connection of aqueduct is in centrifugal filter's upper end, centrifugal filter's lower extreme fixed connection is in the left side of gravel jar, centrifugal filter's left side is connected with the aqueduct, the lower extreme of aqueduct is close to one meter fixedly connected with the water pump, the water tank has been placed to the below of aqueduct.

When the solution to be detected is mixed with the additive, and the solution is conveyed in a pipeline, more bubbles are easy to exist in the solution. The suction filtration detection equipment in the prior art can not remove bubbles in a solution to be detected, and the bubbles in the solution can influence the detection precision of the detection device.

Disclosure of Invention

In view of the above disadvantages, the present invention aims to provide a benzalkonium chloride suction filtration detection device and a use method thereof.

The invention provides the following technical scheme:

a benzalkonium chloride suction filtration detection device comprises primary filtration equipment, mixing equipment and detection equipment; the primary filtering equipment is used for filtering impurities in the solution to be detected; the mixing equipment is used for mixing the filtered solution to be detected with the additive; the detection equipment is used for detecting the solution to be detected mixed with the additive;

the detection equipment comprises a detection tank body, wherein a mounting seat is arranged in the detection tank body, and an inner cavity is arranged in a seat body of the mounting seat; the inner cavity is communicated with the outside of the mounting seat body through an inlet, and the inlet is provided with a first electromagnetic valve;

an ultrasonic vibrating rod is arranged in the inner cavity;

the mounting seat body is internally provided with a detection cavity communicated with the inner cavity, the detection cavity is internally provided with a detector, the detection cavity is communicated with the outside of the mounting seat body through an outlet, and the outlet is provided with a second electromagnetic valve.

The primary filtering equipment comprises a primary filtering tank body, wherein a fourth conveying pipe is installed at the input port of the primary filtering tank body, and a fourth conveying pump is installed on the fourth conveying pipe;

a first filter layer is arranged in the primary filter tank body; the bottom of the primary filter tank body is provided with a first discharge port.

The mixing device is used for gradually mixing the filtered solution to be detected with a plurality of additives.

The mixing equipment comprises a mixing tank body, the mixing tank body is connected with an output port of the primary filtering tank body through a first conveying pipe, and a first conveying pump is mounted on the first conveying pipe; the mixing tank body is also connected with an input port of the detection tank body through a second conveying pipe, and a second conveying pump is mounted on the second conveying pipe;

the mixing tank body is divided into a plurality of mixing cavities by partition plates, stirring blades driven to rotate by a motor are installed in the mixing cavities, and a plurality of adding ports used for injecting additives are formed in the mixing tank body corresponding to the mixing cavities;

and the adjacent mixing cavities are communicated through a conveying pipe III, and a conveying pump III is arranged on the conveying pipe III.

A middle clapboard is arranged in the detection tank body, and an installation seat is arranged at the upper end of the middle clapboard; a baffle plate is arranged on one side of the mounting seat close to the input port of the detection tank body;

the baffle, mount pad separate the detection jar body inner chamber of median septum top for get into the chamber, the chamber of stewing, backward flow chamber, get into the chamber and stew chamber lower extreme intercommunication, stew chamber and backward flow chamber upper end intercommunication.

The middle partition plate is provided with a through hole for communicating the reflux cavity with a lower cavity below the middle partition plate; a second discharge port is formed at the bottom of the detection tank body;

and a third electromagnetic valve is arranged in the through hole.

The inlet is lower than the communication port of the standing cavity and the reflux cavity;

a liquid level sensor is installed on one side, close to the mounting seat, of the baffle, and the liquid level sensor is higher than the inlet.

An output port of the detection tank body is communicated with an input port of the filtering tank body through a conveying pipe five, and a conveying pump five is installed on the conveying pipe five;

a second filter layer is arranged in the filter tank body;

the output port of the filtering tank body is communicated with the second conveying pipe through the sixth conveying pipe, and the sixth conveying pipe is provided with the sixth conveying pump.

The application method of the benzalkonium chloride suction filtration detection device comprises the following steps:

s1, connecting a delivery pipe IV with a raw material tank of a solution to be detected, pumping the solution to be detected into a primary filtering tank body by a delivery pump IV, and filtering impurities in the solution to be detected by a filtering layer I;

s2, pumping the filtered solution to be detected into a mixing cavity of a mixing tank body through a first conveying pump, injecting additives through an adding port, starting a motor to stir uniformly, pumping the solution to be detected into a next mixing cavity through a third conveying pump, and injecting the additives again to mix uniformly;

s3, pumping the solution to be detected mixed with the additive to a detection tank body by a second delivery pump; after the solution to be detected enters the standing cavity and overflows the inlet, opening a first electromagnetic valve; after the solution to be detected enters the inner cavity, closing the first electromagnetic valve;

s4, opening an ultrasonic vibrating rod to remove bubbles in the solution to be detected in the inner cavity;

and S5, starting a detector, and after detecting the solution to be detected, starting a second electromagnetic valve to enable the solution to flow into the backflow cavity.

S5, when the detection result is qualified, opening the electromagnetic valve III, and discharging the solution through the discharge port II after the solution flows into the lower cavity; and when the detection result is unqualified, closing the electromagnetic valve III, starting the delivery pump V, pumping the solution into the filtering tank body by the delivery pump V for filtering, pumping the solution into the delivery pipe II by the delivery pump VI, and detecting the solution again by the detection equipment.

The invention has the beneficial effects that: the application can filter the solution to be detected and can mix the solution with various additives step by step and at regular time before detection, thereby completing pretreatment. The influence of solution disturbance brought by pipeline conveying on the detection result can be avoided, bubbles in the solution to be detected can be eliminated, and the detection precision is prevented from being influenced by the bubbles. This application can carry check out test set again after filtering the unqualified solution of first detection.

Drawings

FIG. 1 is a schematic structural diagram of the present application;

fig. 2 is a schematic view of the internal structure of the mount of the present application.

Labeled in the figure as: the device comprises a primary filter tank body 101, a first filter layer 102, a fourth delivery pump 103, a fourth delivery pipe 104, a first discharge port 105, a first delivery pipe 106, a first delivery pump 107, a mixing tank body 108, a stirring blade 109, an adding port 110, a motor 111, a partition plate 112, a third delivery pipe 113, a third delivery pump 114, a second delivery pump 115, a second delivery pipe 116, a detection tank body 201, an inlet cavity 202, a baffle plate 203, a liquid level sensor 204, a standing cavity 205, a backflow cavity 206, a mounting seat 207, a through hole 208, a middle partition plate 209, a second discharge port 210, a lower cavity 211, a fifth delivery pipe 301, a fifth delivery pump 302, a filter tank body 303, a second filter layer 304, a sixth delivery pipe 305, a sixth delivery pump 306, an inner cavity 401, an ultrasonic vibrating rod 402, an inlet 403, a first electromagnetic valve 404, a detector 405, an outlet 406 and a second electromagnetic valve 407.

Detailed Description

Example one

As shown in figure 1-2, a benzalkonium chloride suction filtration detection device comprises a primary filtration device, a mixing device and a detection device; the primary filtering equipment is used for filtering impurities in the solution to be detected; the mixing equipment is used for mixing the filtered solution to be detected with the additive; the detection equipment is used for detecting the solution to be detected mixed with the additive.

Specifically, the primary filter equipment comprises a primary filter tank body 101, wherein a delivery pipe four 104 is installed at the input port of the primary filter tank body 101, and a delivery pump four 103 is installed on the delivery pipe four 104. A first filter layer 102 is arranged in the primary filter tank body 101. The bottom of the primary filter tank body 101 is provided with a first discharge port 105. And connecting a fourth delivery pipe 104 with a raw material tank of the solution to be detected, pumping the solution to be detected into the primary filtering tank body 101 through a fourth delivery pump 103, and filtering impurities in the solution to be detected through a first filtering layer 102. When the primary filter tank body 101 needs to be cleaned, the first discharge port 105 can be opened to discharge residual liquid in the tank body.

The mixing device is used for gradually mixing the filtered solution to be detected with a plurality of additives. The solution to be detected can be mixed with various additives step by step, and the mixing time of the solution to be detected and each additive can be controlled, so that the solution to be detected is pretreated.

Specifically, the mixing device comprises a mixing tank 108, the mixing tank 108 is connected with the output port of the primary filter tank 101 through a first delivery pipe 106, and a first delivery pump 107 is mounted on the first delivery pipe 106. The filtered solution to be tested can be pumped into the mixing tank 108 by the first delivery pump 107. The mixing tank 108 is also connected with the input port of the detection tank 201 through a second conveying pipe 116, and a second conveying pump 115 is installed on the second conveying pipe 116. After the solution to be detected is mixed with the additive, the mixture can be pumped to the detection tank 201 by the second delivery pump 115.

The mixing tank 108 is divided into a plurality of mixing chambers by partition plates 112, stirring blades 109 driven to rotate by a motor 111 are installed in the mixing chambers, and a plurality of adding ports 110 used for injecting additives are arranged on the mixing tank 108 corresponding to the mixing chambers. Additives can be added to the mixing chamber through addition port 110.

The adjacent mixing cavities are communicated through a delivery pipe III 113, and a delivery pump III 114 is installed on the delivery pipe III 113. When the mixing time of the solution to be detected and the additive reaches a set value, the third delivery pump 114 can be started to pump the solution to be detected to the next mixing cavity.

The detection equipment comprises a detection tank body 201, wherein a mounting seat 207 is arranged in the detection tank body 201, and an inner cavity 401 is arranged in a seat body of the mounting seat 207. The inner cavity 401 is communicated with the outside of the mounting seat 207 through an inlet 403, and a first electromagnetic valve 404 is mounted on the inlet 403. An ultrasonic vibration rod 402 is installed in the inner chamber 401. The mounting seat 207 seat body is also internally provided with a detection cavity communicated with the inner cavity 401, the detection cavity is internally provided with a detector 405, the detection cavity is communicated with the outside of the mounting seat 207 seat body through an outlet 406, and the outlet 406 is provided with a second electromagnetic valve 407.

After opening the first solenoid valve 404, the solution to be tested enters the inner cavity 401, and then the first solenoid valve 404 is closed. The ultrasonic vibrator 402 is turned on to remove air bubbles from the solution, and then the solution is detected by the detector 405. After the detection is completed, the second solenoid valve 407 is opened to allow the solution to flow out of the outlet 406.

A middle partition plate 209 is arranged in the detection tank body 201, and the mounting seat 207 is arranged at the upper end of the middle partition plate 209. A baffle plate 203 is arranged on one side of the mounting seat 207 close to the input port of the detection tank body 201. The baffle 203 and the mounting seat 207 divide the inner cavity of the detection tank body 201 above the middle partition plate 209 into an inlet cavity 202, a standing cavity 205 and a return cavity 206, the inlet cavity 202 is communicated with the lower end of the standing cavity 205, and the standing cavity 205 is communicated with the upper end of the return cavity 206.

The inlet 403 is lower than the communication port of the rest chamber 205 and the reflux chamber 206. The baffle 203 is provided with a liquid level sensor 204 at one side close to the mounting seat 207, and the liquid level sensor 204 is higher than the inlet 403.

Through setting up baffle 203, can avoid causing the solution that has in the detection jar body 201 from the solution that the second 116 of conveyer pipe flows out to set up the chamber 205 that stews, can let some bubbles that solution carried automatic elimination earlier. The inlet 403 is lower than the communication port between the standing cavity 205 and the reflux cavity 206, and the solution is made to flow over the inlet 403 and then the first electromagnetic valve 404 is opened, so that a large amount of foam existing on the solution surface can be prevented from entering the inner cavity 401, and the influence of the foam and the bubbles on the detection result can be reduced.

Example two

Furthermore, the middle partition 209 is provided with a through hole 208 for communicating the reflow chamber 206 with a lower chamber 211 below the middle partition 209. The bottom of the detection tank body 201 is provided with a second outlet 210. And a third electromagnetic valve is arranged in the through hole 208.

An output port of the detection tank body 201 is communicated with an input port of the filtering tank body 303 through a conveying pipe five 301, and a conveying pump five 302 is installed on the conveying pipe five 301. And a second filter layer 304 is arranged in the filter tank 303. The output port of the filtering tank body 303 is communicated with the second conveying pipe 116 through a sixth conveying pipe 305, and a sixth conveying pump 306 is installed on the sixth conveying pipe 305.

When the detection result is qualified, the third electromagnetic valve is opened, and the solution flows into the lower cavity 211 and then is discharged through the second discharge port 210. And when the detection result is unqualified, closing the electromagnetic valve III, opening the delivery pump V302, pumping the solution into the filtering tank body 303 for filtering by the delivery pump V302, pumping the solution into the delivery pipe II 116 by the delivery pump VI 306, and detecting the solution again by the detection equipment.

Based on the above embodiment, the application also provides a use method of the benzalkonium chloride suction filtration detection device, which comprises the following steps:

s1, connecting a fourth conveying pipe 104 with a raw material tank of a solution to be detected, pumping the solution to be detected into a primary filtering tank body 101 through a fourth conveying pump 103, and filtering impurities in the solution to be detected through a first filtering layer 102;

s2, pumping the filtered solution to be detected into a mixing cavity of a mixing tank 108 through a first delivery pump 107, injecting additives through an adding port 110, starting a motor 111, uniformly stirring, pumping to the next mixing cavity through a third delivery pump 114, and injecting the additives again to uniformly mix;

s3, pumping the solution to be detected mixed with the additive to the detection tank body 201 by using a second delivery pump 115; after the solution to be detected enters the standing cavity 205 and overflows through the inlet 403, opening a first electromagnetic valve 404; after the solution to be detected enters the inner cavity 401, closing the first electromagnetic valve 404;

s4, opening the ultrasonic vibrating rod 402 to remove bubbles in the solution to be detected in the inner cavity 401;

and S5, starting the detector 405, after detecting the solution to be detected, starting the second electromagnetic valve 407, and enabling the solution to flow into the reflux cavity 206.

In S5, when the detection result is qualified, the electromagnetic valve III is opened, and the solution flows into the lower cavity 211 and is discharged through the discharge port II 210; and when the detection result is unqualified, closing the electromagnetic valve III, opening the delivery pump V302, pumping the solution into the filtering tank body 303 for filtering by the delivery pump V302, pumping the solution into the delivery pipe II 116 by the delivery pump VI 306, and detecting the solution again by the detection equipment.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a benzalkonium chloride suction filtration detection device which characterized in that: comprises primary filtering equipment, mixing equipment and detection equipment; the primary filtering equipment is used for filtering impurities in the solution to be detected; the mixing equipment is used for mixing the filtered solution to be detected with the additive; the detection equipment is used for detecting the solution to be detected mixed with the additive;

the detection equipment comprises a detection tank body (201), wherein a mounting seat (207) is arranged in the detection tank body (201), and an inner cavity (401) is arranged in a seat body of the mounting seat (207); the inner cavity (401) is communicated with the outside of the base body of the mounting base (207) through an inlet (403), and a first electromagnetic valve (404) is mounted at the inlet (403);

an ultrasonic vibrating rod (402) is arranged in the inner cavity (401);

still be equipped with the detection chamber with inner chamber (401) intercommunication in mount pad (207) seat body, detect the intracavity and install detector (405), detect the chamber and communicate with mount pad (207) seat body outside through export (406), export (406) are installed solenoid valve two (407).

2. The benzalkonium chloride suction filtration detection device of claim 1, characterized in that: the primary filtering equipment comprises a primary filtering tank body (101), wherein a fourth conveying pipe (104) is installed at an input port of the primary filtering tank body (101), and a fourth conveying pump (103) is installed on the fourth conveying pipe (104);

a first filter layer (102) is arranged in the primary filter tank body (101); the bottom of the primary filter tank body (101) is provided with a first discharge port (105).

3. The benzalkonium chloride suction filtration detection device of claim 2, wherein: the mixing device is used for mixing the filtered solution to be detected with a plurality of additives step by step.

4. The benzalkonium chloride suction filtration detection device of claim 3, characterized in that: the mixing equipment comprises a mixing tank body (108), the mixing tank body (108) is connected with an output port of the primary filtering tank body (101) through a first conveying pipe (106), and a first conveying pump (107) is installed on the first conveying pipe (106); the mixing tank body (108) is also connected with an input port of the detection tank body (201) through a second conveying pipe (116), and a second conveying pump (115) is installed on the second conveying pipe (116);

the mixing tank body (108) is internally divided into a plurality of mixing cavities by partition plates (112), stirring blades (109) driven to rotate by a motor (111) are arranged in the mixing cavities, and a plurality of adding ports (110) used for injecting additives are arranged on the mixing tank body (108) corresponding to the mixing cavities;

the adjacent mixing cavities are communicated through a conveying pipe III (113), and a conveying pump III (114) is installed on the conveying pipe III (113).

5. The benzalkonium chloride suction filtration detection device of claim 1, which is characterized in that: a middle partition plate (209) is arranged in the detection tank body (201), and a mounting seat (207) is arranged at the upper end of the middle partition plate (209); a baffle plate (203) is arranged on one side of the mounting seat (207) close to the input port of the detection tank body (201);

the baffle (203) and the mounting seat (207) divide the inner cavity of the detection tank body (201) above the middle partition plate (209) into an inlet cavity (202), a standing cavity (205) and a backflow cavity (206), the inlet cavity (202) is communicated with the lower end of the standing cavity (205), and the standing cavity (205) is communicated with the upper end of the backflow cavity (206).

6. The benzalkonium chloride suction filtration detection device of claim 5, characterized in that: a through hole (208) used for communicating the reflux cavity (206) with a lower cavity (211) below the middle clapboard (209) is arranged on the middle clapboard (209); a second discharge port (210) is formed at the bottom of the detection tank body (201);

a third electromagnetic valve is arranged in the through hole (208).

7. The benzalkonium chloride suction filtration detection device of claim 5, characterized in that: the inlet (403) is lower than the communication port of the standing cavity (205) and the reflux cavity (206);

a liquid level sensor (204) is installed on one side, close to the mounting seat (207), of the baffle plate (203), and the liquid level sensor (204) is higher than the inlet (403).

8. The benzalkonium chloride suction filtration detection device of claim 4, wherein: an output port of the detection tank body (201) is communicated with an input port of the filtering tank body (303) through a fifth delivery pipe (301), and a fifth delivery pump (302) is installed on the fifth delivery pipe (301);

a second filter layer (304) is arranged in the filter tank body (303);

an output port of the filtering tank body (303) is communicated with the second conveying pipe (116) through a sixth conveying pipe (305), and a sixth conveying pump (306) is installed on the sixth conveying pipe (305).

9. The use method of the benzalkonium chloride suction filtration detection device according to any one of claims 1-8, characterized by comprising the following steps:

s1, connecting a fourth delivery pipe (104) with a raw material tank of the solution to be detected, pumping the solution to be detected into a primary filtering tank body (101) by a fourth delivery pump (103), and filtering impurities in the solution to be detected by a first filtering layer (102);

s2, pumping the filtered solution to be detected into a mixing cavity of a mixing tank body (108) through a first delivery pump (107), injecting additives through an adding port (110), starting a motor (111) to stir uniformly, pumping the solution to be detected into the next mixing cavity through a third delivery pump (114), and injecting the additives again to mix uniformly;

s3, pumping the solution to be detected mixed with the additive to a detection tank body (201) by a second delivery pump (115); after the solution to be detected enters the standing cavity (205) and overflows through the inlet (403), opening a first electromagnetic valve (404); after the solution to be detected enters the inner cavity (401), closing the first electromagnetic valve (404);

s4, opening the ultrasonic vibrating rod (402) and removing bubbles in the solution to be detected in the inner cavity (401);

and S5, opening the detector (405), after detecting the solution to be detected, opening the second electromagnetic valve (407), and enabling the solution to flow into the reflux cavity (206).

10. The method for using the benzalkonium chloride suction filtration detection device according to claim 9, comprising the steps of:

in S5, when the detection result is qualified, the electromagnetic valve III is opened, and the solution flows into the lower cavity (211) and is discharged through the discharge port II (210); and when the detection result is unqualified, closing the electromagnetic valve III, opening the delivery pump V (302), pumping the solution into the filtering tank body (303) by the delivery pump V (302) for filtering, pumping the solution into the delivery pipe II (116) by the delivery pump VI (306), and detecting again by the detection equipment.

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