CN215179639U - Spectrophotometry total phosphorus water quality on-line monitoring analyzer - Google Patents

Abstract

The utility model discloses a total phosphorus quality of water on-line monitoring analysis appearance of spectrophotometry, including the monitoring analysis appearance body, the top of monitoring analysis appearance body fixedly connected with refrigeration case, pump and water tank from the front to the back in proper order, the back intercommunication of pump has the drinking-water pipe, the back of drinking-water pipe and the positive bottom of water tank intercommunication, the front intercommunication of pump has the drain pipe, the back fixedly connected with condenser plate of refrigeration case inner chamber, the front fixedly connected with condenser pipe of condenser plate, the utility model discloses through setting up pump, drinking-water pipe, drain pipe, condenser plate, condenser pipe and back flow, can refrigerate the air in the refrigeration case, through setting up rotating electrical machines and flabellum, can blow the air conditioning in the refrigeration case into the inside of monitoring analysis appearance body, dispel the heat to the electronic component inside the monitoring analysis appearance body, through setting up above structure, possess the advantage fast to the inside electronic component radiating rate of monitoring analysis appearance.

Description

Spectrophotometry total phosphorus water quality on-line monitoring analyzer

Technical Field

The utility model relates to a monitoring analysis appearance technical field specifically is a total phosphorus quality of water on-line monitoring analysis appearance of spectrophotometry.

Background

The total phosphorus water quality on-line analyzer is an instrument type which is used for hydrolyzing polyphosphate and other phosphorus-containing compounds in water under high-temperature and high-pressure acidic conditions to generate phosphate radicals, and oxidizing other phosphorus compounds which are difficult to oxidize by a strong oxidant sodium persulfate to obtain phosphate radicals, so that the total phosphorus content in a sample is obtained, and the total phosphorus water quality on-line analyzer is simple to operate and stable in performance; because monitoring analysis appearance electronic component can produce the heat in the course of the work, need dispel the heat to it, prevent electronic component damage, and traditional radiating mode adopts single fan to dispel the heat mostly, and this kind of radiating mode's radiating rate is slow, and is inefficient, can't be timely dispel the heat to monitoring analysis appearance, and it is very inconvenient to use, for this reason we provide a total phosphorus water quality on-line monitoring analysis appearance of spectrophotometry, solve above problem that provides.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a total phosphorus quality of water on-line monitoring analysis appearance of spectrophotometry possesses the fast advantage of electronic component radiating rate to monitoring analysis appearance inside, has solved that traditional radiating mode adopts single fan to dispel the heat mostly, and this kind of radiating mode's radiating rate is slow, and is inefficient, can not be timely dispel the heat to monitoring analysis appearance, the problem of using very inconvenient.

In order to achieve the above object, the utility model provides a following technical scheme: an online monitoring analyzer for total phosphorus water quality by a spectrophotometric method comprises a monitoring analyzer body, wherein the top of the monitoring analyzer body is fixedly connected with a refrigerating box, a pump and a water tank in sequence from front to back, the back of the pump is communicated with a water pumping pipe, the back of the water pumping pipe is communicated with the front bottom of the water tank, the front of the pump is communicated with a water draining pipe, the back of the inner cavity of the refrigerating box is fixedly connected with a condensing plate, the front of the condensing plate is fixedly connected with a condensing pipe, one end, far away from the pump, of the water draining pipe penetrates through the condensing plate and is communicated with one end of the condensing pipe, one end, far away from the water draining pipe, of the condensing pipe is communicated with a return pipe, the back of the return pipe penetrates through the refrigerating box and is communicated with the front top of the water tank, the bottom of the inner cavity of the refrigerating box is communicated with a ventilation pipe, the bottom of the ventilation pipe penetrates through the monitoring analyzer body and extends to the inner cavity of the monitoring analyzer body, the inner cavity of the ventilation pipe is fixedly connected with a rotary motor through a support rod, the output end of the rotary motor is fixedly connected with fan blades, the left side of the bottom of the inner cavity of the monitoring analyzer body is fixedly connected with a dust collection box, the right side of the dust collection box is provided with a dust collection assembly, and the bottom of the inner cavity of the monitoring analyzer body is fixedly connected with an inclined plate.

Preferably, the dust absorption subassembly includes the air exhauster, the bottom of air exhauster and the left side fixed connection of monitoring analysis appearance body inner chamber bottom, the top intercommunication of air exhauster has the exhaust pipe, the one end and the top intercommunication on dust collection box right side that the air exhauster was kept away from to the exhaust pipe, the right side intercommunication of air exhauster has the dust absorption pipe, fixedly connected with suction hood is located at the center of swash plate bottom, the one end that the air exhauster was kept away from to the dust absorption pipe communicates with suction hood's bottom.

Preferably, the inner cavity of the dust collection box is fixedly connected with a filter screen, and the right side of the bottom of the inner cavity of the dust collection box is communicated with an exhaust pipe.

Preferably, a discharge pipe is communicated with the left side of the inner cavity of the dust collection box and positioned above the filter screen, and a valve is arranged at the pipe orifice of the discharge pipe.

Preferably, the bottom fixedly connected with of monitoring analysis appearance body inner chamber places the board, the surface of placing the board has evenly seted up the through-hole.

Preferably, the center of the top of the water tank is communicated with a water injection pipe, and the bottom of the right side of the water tank is communicated with a water changing pipe.

Compared with the prior art, the beneficial effects of the utility model are as follows:

1. the utility model discloses a set up the suction pump, the drinking-water pipe, the drain pipe, the cold plate, condenser pipe and back flow, can refrigerate the air of refrigeration incasement, through setting up rotating electrical machines and flabellum, can blow in the inside of monitoring analysis appearance body with the air conditioning of refrigeration incasement, dispel the heat to the inside electronic component of monitoring analysis appearance body, through setting up above structure, possess the fast advantage of the inside electronic component radiating rate of monitoring analysis appearance, it adopts single fan to dispel the heat mostly to have solved traditional radiating mode, and this kind of radiating mode's radiating rate is slow, low efficiency, can not be timely dispel the heat to the monitoring analysis appearance, use very inconvenient problem.

2. The utility model can absorb the dust in the monitoring analyzer body by arranging the exhaust fan, the exhaust pipe, the dust absorption pipe and the dust hood, thereby preventing the dust from accumulating on the surface of the electronic element and causing interference to the operation of the electronic element;

the dust can be filtered by arranging the filter screen, and the exhaust pipe is arranged to facilitate the exhaust of waste gas;

the collected dust can be conveniently discharged by arranging the discharge pipe and the valve;

the water quality to be detected can be conveniently placed by arranging the placing plate, and the cold air can conveniently circulate by arranging the through holes;

through setting up the water injection pipe, can conveniently toward the water tank internal water injection.

Drawings

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

FIG. 2 is a cross-sectional view of the structure of the present invention;

FIG. 3 is a side cross-sectional view of the refrigeration case and water tank arrangement of the present invention;

fig. 4 is a partial enlarged view of a portion a in the structure diagram of the present invention 2.

In the figure: 1. monitoring the analyzer body; 2. a refrigeration case; 3. pumping; 4. a water tank; 5. a water pumping pipe; 6. a drain pipe; 7. a condensing plate; 8. a condenser tube; 9. a return pipe; 10. a vent pipe; 11. a rotating electric machine; 12. a fan blade; 13. a dust collection box; 14. a dust collection assembly; 141. an exhaust fan; 142. an exhaust duct; 143. a dust collection pipe; 144. a dust hood; 15. a filter screen; 16. placing the plate; 17. a through hole; 18. a sloping plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, an online monitoring analyzer for total phosphorus water quality by spectrophotometry comprises a monitoring analyzer body 1, wherein the top of the monitoring analyzer body 1 is fixedly connected with a refrigeration box 2, a pump 3 and a water tank 4 in sequence from front to back, the back of the pump 3 is communicated with a water pumping pipe 5, the back of the water pumping pipe 5 is communicated with the front bottom of the water tank 4, the front of the pump 3 is communicated with a water draining pipe 6, the back of the inner cavity of the refrigeration box 2 is fixedly connected with a condensation plate 7, the front of the condensation plate 7 is fixedly connected with a condensation pipe 8, one end of the water draining pipe 6 far away from the pump 3 penetrates through the condensation plate 7 and is communicated with one end of the condensation pipe 8, one end of the condensation pipe 8 far away from the water draining pipe 6 is communicated with a return pipe 9, the back of the return pipe 9 penetrates through the refrigeration box 2 and is communicated with the front top of the water tank 4, the bottom of the inner cavity of the refrigeration box 2 is communicated with a ventilation pipe 10, the bottom of the ventilation pipe 10 penetrates through the monitoring analyzer body 1 and extends to the inner cavity of the monitoring analyzer body 1, the inner cavity of the ventilation pipe 10 is fixedly connected with a rotating motor 11 through a supporting rod, the output end of the rotating motor 11 is fixedly connected with a fan blade 12, the left side of the bottom of the inner cavity of the monitoring analyzer body 1 is fixedly connected with a dust collection box 13, the right side of the dust collection box 13 is provided with a dust collection assembly 14, the bottom of the inner cavity of the monitoring analyzer body 1 is fixedly connected with an inclined plate 18, the air in the refrigeration box 2 can be refrigerated by arranging a pump 3, a water pumping pipe 5, a water drainage pipe 6, a condensation plate 7, a condensation pipe 8 and a return pipe 9, the cold air in the refrigeration box 2 can be blown into the monitoring analyzer body 1 by arranging the rotating motor 11 and the fan blade 12, electronic elements in the monitoring analyzer body 1 are radiated, the structure has the advantage of high radiating speed of the electronic elements in the monitoring analyzer body, and the problem that most of traditional radiating modes adopt a single fan to radiate heat is solved, the heat dissipation method has the problems of low heat dissipation speed, low efficiency, incapability of dissipating heat to the monitoring analyzer in time and inconvenience in use.

Referring to fig. 2 and 4, the dust collection assembly 14 includes an exhaust fan 141, a bottom of the exhaust fan 141 is fixedly connected to a left side of a bottom of an inner cavity of the monitoring analyzer body 1, a top of the exhaust fan 141 is communicated with an exhaust duct 142, an end of the exhaust duct 142 away from the exhaust fan 141 is communicated with a top of a right side of the dust collection box 13, a right side of the exhaust fan 141 is communicated with a dust collection duct 143, a center of a bottom of the inclined plate 18 is fixedly connected with a dust collection cover 144, an end of the dust collection duct 143 away from the exhaust fan 141 is communicated with a bottom of the dust collection cover 144, and the exhaust fan 141, the exhaust duct 142, the dust collection duct 143 and the dust collection cover 144 are arranged to absorb dust inside the monitoring analyzer body 1, so as to prevent the dust from accumulating on a surface of an electronic component and interfering with operation of the electronic component.

Referring to fig. 2 and 4, a filter screen 15 is fixedly connected to an inner cavity of the dust collection box 13, an exhaust pipe is communicated with the right side of the bottom of the inner cavity of the dust collection box 13, dust can be filtered by the filter screen 15, and exhaust gas can be conveniently exhausted by the exhaust pipe.

Referring to fig. 2, a discharge pipe is connected to the left side of the inner cavity of the dust collecting box 13 and above the filter screen 15, a valve is disposed at the opening of the discharge pipe, and collected dust can be discharged conveniently by disposing the discharge pipe and the valve.

Referring to fig. 2, the bottom fixedly connected with of the inner cavity of the monitoring analyzer body 1 is provided with a placing plate 16, through holes 17 are evenly formed in the outer surface of the placing plate 16, the placing plate 16 is arranged, water quality to be detected can be conveniently placed, and through the through holes 17, cold air circulation can be facilitated.

Referring to fig. 1 and 3, the center of the top of the water tank 4 is communicated with a water injection pipe, the bottom of the right side of the water tank 4 is communicated with a water changing pipe, and water can be conveniently injected into the water tank 4 by arranging the water injection pipe.

When the device is used, plugs of the suction pump 3, the rotary motor 11 and the exhaust fan 141 are powered on, when heat dissipation needs to be carried out on the inside of the monitoring analyzer body 1, a peripheral switch of the suction pump 3 is started, the suction pump 3 pumps water in the water tank 4 through the suction pipe 5, then the water is discharged into the condensation pipe 8 through the drain pipe 6, air in the refrigeration box 2 is refrigerated through the action of the condensation pipe 8 and the condensation plate 7, then the peripheral switch of the rotary motor 11 is started, the rotary motor 11 drives the fan blades 12 to rotate, cold air in the refrigeration box 2 is blown into the monitoring analyzer body 1 through the fan blades 12, heat dissipation is carried out on electronic elements in the monitoring analyzer body 1, finally the peripheral switch of the exhaust fan 141 is started, dust in the monitoring analyzer body 1 is absorbed through the dust hood 144 and the dust suction pipe 143, and then the dust is discharged into the dust collection box 13 through the exhaust pipe 142, after filtering through filter screen 15, waste gas passes through the blast pipe and discharges, through setting up above structure, possesses the fast advantage of electronic component radiating rate to monitoring analysis appearance inside, has solved that traditional radiating mode adopts single fan to dispel the heat mostly, and this kind of radiating mode's radiating rate is slow, and is inefficient, can not be timely dispel the heat to monitoring analysis appearance, uses very inconvenient problem.

The control mode of the present application is controlled by an external controller, and the control circuit of the controller can be realized by a simple circuit of a person skilled in the art, which belongs to the common knowledge in the art, and the present application mainly protects a mechanical device, so the control mode and the circuit connection are not explained in detail in the present application.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a total phosphorus quality of water on-line monitoring analysis appearance of spectrophotometry, includes monitoring analysis appearance body (1), its characterized in that: the monitoring analyzer comprises a monitoring analyzer body (1), wherein the top of the monitoring analyzer body (1) is fixedly connected with a refrigerating box (2), a suction pump (3) and a water tank (4) from the front to the back in sequence, the back of the suction pump (3) is communicated with a water pumping pipe (5), the back of the water pumping pipe (5) is communicated with the front bottom of the water tank (4), the front of the suction pump (3) is communicated with a water discharging pipe (6), the back of the inner cavity of the refrigerating box (2) is fixedly connected with a condensing plate (7), the front of the condensing plate (7) is fixedly connected with a condensing pipe (8), one end, away from the suction pump (3), of the water discharging pipe (6) penetrates through the condensing plate (7) and is communicated with one end of the condensing pipe (8), one end, away from the water discharging pipe (6), of the condensing pipe (8) is communicated with a return pipe (9), the back of the return pipe (9) penetrates through the refrigerating box (2) and is communicated with the front top of the water tank (4), the bottom intercommunication of refrigeration case (2) inner chamber has ventilation pipe (10), the bottom of ventilation pipe (10) runs through monitoring analysis appearance body (1) and extends to the inner chamber of monitoring analysis appearance body (1), the inner chamber of ventilation pipe (10) passes through branch fixedly connected with rotating electrical machines (11), output fixedly connected with flabellum (12) of rotating electrical machines (11), the left side fixedly connected with dust collection box (13) of monitoring analysis appearance body (1) inner chamber bottom, the right side of dust collection box (13) is provided with dust absorption component (14), the bottom fixedly connected with swash plate (18) of monitoring analysis appearance body (1) inner chamber.

2. The spectrophotometry total phosphorus water quality on-line monitoring analyzer according to claim 1, which is characterized in that: dust absorption subassembly (14) include air exhauster (141), the bottom of air exhauster (141) and the left side fixed connection of monitoring analysis appearance body (1) inner chamber bottom, the top intercommunication of air exhauster (141) has exhaust pipe (142), the one end and the top intercommunication on dust collection box (13) right side of air exhauster (141) are kept away from in exhaust pipe (142), the right side intercommunication of air exhauster (141) has dust absorption pipe (143), fixedly connected with suction hood (144) are located at the center of swash plate (18) bottom, the one end that air exhauster (141) were kept away from in suction pipe (143) and the bottom intercommunication of suction hood (144).

3. The spectrophotometry total phosphorus water quality on-line monitoring analyzer according to claim 1, which is characterized in that: the filter screen (15) is fixedly connected to the inner cavity of the dust collection box (13), and the right side of the bottom of the inner cavity of the dust collection box (13) is communicated with an exhaust pipe.

4. The spectrophotometry total phosphorus water quality on-line monitoring analyzer according to claim 1, which is characterized in that: the left side of the inner cavity of the dust collection box (13) and the upper part of the filter screen (15) are communicated with a discharge pipe, and a valve is arranged at the pipe orifice of the discharge pipe.

5. The spectrophotometry total phosphorus water quality on-line monitoring analyzer according to claim 1, which is characterized in that: the bottom fixedly connected with of monitoring analysis appearance body (1) inner chamber places board (16), through-hole (17) have evenly been seted up to the surface of placing board (16).

6. The spectrophotometry total phosphorus water quality on-line monitoring analyzer according to claim 1, which is characterized in that: the center of the top of the water tank (4) is communicated with a water injection pipe, and the bottom of the right side of the water tank (4) is communicated with a water changing pipe.

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