CN214004213U - Water quality monitoring equipment - Google Patents

Abstract

The utility model relates to a water quality monitoring device, which consists of a multi-parameter water quality on-line monitor and a micro-reagent water quality on-line monitor; the multi-parameter water quality on-line monitor further comprises a first cabinet, a water distribution pipeline which is arranged in the first cabinet and at least has two-stage filtering, sand settling, overflowing and backwashing functions, a water collecting device which is used for taking and distributing the measured water to the water distribution pipeline arranged in the first cabinet, a reagent-free water quality monitoring device which is arranged and connected on the water distribution pipeline, and a high-pressure flushing device which is arranged and connected on the reagent-free water quality monitoring device. The utility model relates to a water quality monitoring equipment has that the integrated level is high, filtration and pipe-line system retrench, go out that the testing data is quick, characteristics such as less reagent consumption.

Description

Water quality monitoring equipment

Technical Field

The patent relates to a water quality monitoring field especially relates to a highly integrated water quality monitoring equipment's pipeline structure.

Background

With the implementation of various systems and technical specifications, the country further strengthens the protection and supervision of rivers and lakes. Wherein, the water quality monitoring is carried out efficiently and rapidly, and more effective monitoring data is provided. The existing water quality monitoring equipment generally has the defects of large floor area, complex pipeline, long data output period, large reagent consumption and the like. Therefore, it is necessary to design and develop a water quality monitoring device with high integration level, simplified filtration and pipeline system, fast detection data output and less reagent consumption.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the defect that exists to above-mentioned background art, provide a water quality monitoring equipment that the integrated level is high, filtration and pipe-line system retrench, go out the testing data fast, less reagent consumption.

In order to realize the purpose, the utility model relates to a water quality monitoring device, which consists of a multi-parameter water quality on-line monitor and a micro-reagent water quality on-line monitor; the multi-parameter water quality on-line monitor further comprises a first cabinet, a water distribution pipeline which is arranged in the first cabinet and at least has two-stage filtering, sand settling, overflowing and backwashing functions, a water collecting device which is used for taking and distributing the measured water to the water distribution pipeline arranged in the first cabinet, a reagent-free water quality monitoring device which is arranged and connected on the water distribution pipeline, and a high-pressure flushing device which is arranged and connected on the reagent-free water quality monitoring device.

Furthermore, the water distribution pipeline further comprises a water inlet pipeline, a water storage sand settling tank, a bottom water outlet pipeline, a reagent-free flow cell group, an overflow and drainage and back flushing pipeline and a secondary filtering device.

Further, the water storage sand settling tank further comprises a drinking water pipe and drinking water pipe caps packaged at two ends of the drinking water pipe, and the water storage sand settling tank is provided with a water inlet pipe, a bottom water outlet pipe, a side liquid level observation pipe, a side overflow pipe and a top vent pipe which are all communicated with the drinking water pipe.

Furthermore, the water inlet pipeline is formed by sequentially connecting a measured water inlet pipeline, a first filter, a flowmeter and a UPVC pipeline with the outer diameter of 32 mmUPVC.

Furthermore, the secondary filtering device is communicated with the water storage sand settling tank through a secondary filtering water intake arranged on the drinking water pipe body.

Furthermore, the second-stage filtering device is formed by sequentially connecting a straight-through filter for finely filtering the water to be measured, a three-way electromagnetic valve and a fine filtering water storage tank, and the straight-through filter is connected to the second-stage filtering water intake.

Furthermore, the bottom water outlet pipeline further comprises an emptying and back flushing pipeline and a reagent-free testing pipeline.

Furthermore, the evacuation and backwash pipeline is composed of an electromagnetic valve and an evacuation and backwash pipe.

Furthermore, the overflow drain and back flush pipeline further comprises a measured water outlet pipeline and a tap water inlet pipeline.

Furthermore, the reagent-free water quality monitoring device comprises a spectrum sensor, an ion sensor, a dissolved oxygen sensor and a conductivity sensor.

Furthermore, the high-pressure flushing device consists of an air compressor, an air filter, a high-pressure air electromagnetic valve, a three-way electromagnetic valve and a plurality of pipelines.

Furthermore, the air compressor, the air filter, the high-pressure air electromagnetic valve and the spectral sensor, the ion sensor, the dissolved oxygen sensor and the conductivity sensor in the reagent-free water quality monitoring device are sequentially connected to form a first high-pressure flushing pipeline.

Furthermore, the air compressor, the air filter, the high-pressure air electromagnetic valve and the three-way electromagnetic valve are sequentially connected to form a second high-pressure flushing pipeline.

Furthermore, the online micro-reagent water quality monitor further comprises a second cabinet, a micro-reagent water quality detection device installed in the second cabinet, a filter for performing third-stage filtration on the detected water, a pure water barrel for providing the detected water to the micro-reagent water quality detection device, and a waste liquid barrel for collecting waste liquid generated by the micro-reagent water quality detection device.

Furthermore, the online micro-reagent water quality monitor further comprises a micro-reagent total phosphorus online analyzer and a micro-reagent total nitrogen online analyzer which are arranged in the second cabinet.

To sum up, the water quality monitoring device of the utility model has high integration degree, and the water distribution, filtration, sand settling, secondary filtration, control, transmission, power failure monitoring, temperature and humidity monitoring and monitoring devices are arranged in a set of device, which is convenient for carrying and installation, and the water quality monitoring device of the utility model has simple filtration and pipeline system, can effectively realize the functions of filtration, sand settling, secondary filtration and the like, and simultaneously has the maintenance functions of back washing, high-pressure air cleaning and the like; the water quality monitoring equipment is simultaneously and specifically free of a reagent and a micro-reagent detection mode, so that the reagent is free of reagent consumption, and monitoring data can be rapidly issued; the micro reagent has low dosage, can not be replaced for a long time, and effectively prolongs the maintenance period.

Drawings

Fig. 1 is the utility model relates to a water quality monitoring device's a cabinet body schematic diagram.

Fig. 2 is the utility model discloses a water quality monitoring device's a cabinet internal portion front structure layout sketch map.

Fig. 3 is the back structure layout diagram of the inside of a cabinet of the water quality monitoring device of the utility model.

Fig. 4 is a schematic view of a water distribution pipeline of the water quality monitoring device of the present invention.

Detailed Description

In order to explain the technical content, structural features, and achieved objects and effects of the present invention in detail, the following embodiments are described in detail with reference to the accompanying drawings.

Referring to fig. 1 to 3, the water quality monitoring apparatus 100 of the present invention comprises a multi-parameter water quality on-line monitor 1 and a micro-reagent water quality on-line monitor 2.

The multi-parameter water quality on-line monitor 1 further comprises a first cabinet 11, a water distribution pipeline 12 which is arranged in the first cabinet 11 and has at least two-stage filtering, sand settling, overflowing and backwashing functions, a water collecting device (not shown in the figure) for taking the measured water and distributing the measured water to the water distribution pipeline 12 arranged in the first cabinet 11, a reagent-free water quality monitoring device 13 which is arranged and connected on the pipeline of the water distribution pipeline 12, and a high-pressure flushing device 14 which is arranged and connected on the reagent-free water quality monitoring device 13. The water collecting device (not shown in the figure) adopts a double-pump mode to collect water.

The multi-parameter online water quality monitor 1 further comprises a data acquisition and transmission device 15 for acquiring and transmitting the monitoring data of the measured water, an electric control system 16 for controlling and supplying power to the multi-parameter online water quality monitor 1, and a device 17 for detecting power failure and temperature and humidity states of the multi-parameter online water quality monitor 1.

The water distribution pipeline 12 further comprises a water inlet pipeline 121, a water storage sand settling tank 122, a bottom water outlet pipeline 123, a reagent-free flow cell group 124, an overflow and drain and back flush pipeline 125 and a secondary filtering device 127.

The water inlet pipeline 121 is formed by sequentially connecting a measured water inlet pipeline 1211, a first filter 1212, a flowmeter 1213 and a UPVC pipeline with the outer diameter of 32 mmUPVC. The first filter is a Y-shaped mesh filter, and the Y-shaped mesh filter adopts a 40-mesh filter screen.

The water-storing sand-settling tank 122 further includes a cylindrical drinking water pipe 1221 and drinking water pipe caps 1222 sealed at both ends of the drinking water pipe 1221. The water storage sand settling tank 122 is provided with a water inlet pipe 1223, a bottom water outlet pipe 1224, a side liquid level observation pipe 1225, a side overflow pipe 1226 and a top vent pipe 1228 which are communicated with the drinking water pipe 1221. Further, the secondary filtering device 127 is communicated with the water storage sand settling tank 122 through a secondary filtering water intake 1227 arranged on the body of the drinking water pipe 1221.

The bottom outlet line 123 further comprises an evacuation and back-flushing line (not shown) and a reagent-free testing line (not shown).

The evacuation and backwash line is comprised of a solenoid valve 1231 and an evacuation and backwash line 1232.

The overflow drain and back flush line 125 further comprises a measured water outlet line 1251 and a tap water inlet line 1252.

The bottom outlet pipe 123 is in communication with the bottom outlet pipe 1224.

The second-stage filtering device 127 is formed by sequentially connecting a straight-through filter 1271 for finely filtering the water to be measured, a three-way electromagnetic valve 1272 and a fine filtering water storage tank 1273, and the straight-through filter 1271 is connected to the second-stage filtering water intake 1227.

The reagent-free water quality monitoring device 13 comprises a spectrum sensor 131, an ion sensor 132, a dissolved oxygen sensor 133 and a conductivity sensor 134, and the reagent-free water quality monitoring device 13 can be at least used for detecting the permanganate index, chlorophyll, turbidity, ammonia nitrogen, PH, water temperature, dissolved oxygen and conductivity of the detected water.

The high pressure flushing device 14 is composed of an air compressor (not shown), an air filter (not shown), a high pressure air solenoid valve 141, a three-way solenoid valve 1272, and a plurality of pipelines (not shown).

The air compressor (not shown), the air filter (not shown), the high-pressure air solenoid valve 141, and the spectrum sensor 131, the ion sensor 132, the dissolved oxygen sensor 133, and the conductivity sensor 134 of the reagent-free water quality monitoring device 13 together form a first high-pressure flushing pipeline.

The spectral sensor 131, the ion sensor 132, the dissolved oxygen sensor 133 and the conductivity sensor 134 are all provided with high-pressure air cleaning structures, and the detection parts can be washed through the input of high-pressure air, so that the detection accuracy is ensured.

The air compressor (not shown), the air filter (not shown), the high-pressure air solenoid valve 141 and the three-way solenoid valve 1272 together form a second high-pressure flushing pipeline. By high pressure air backwash of the straight through filter 11271, long term use of the straight through filter 11271 is effectively assured.

After the water is collected by the water collection device (not shown in the figure), the measured water reaches the first filter 1212 through the measured water inlet pipeline 1211, and is subjected to primary filtration by the first filter 1212, so as to filter out larger particles and suspended matters; the measured water is filtered by the first filter 1212, passes through a flowmeter 1213, and then enters the water storage sand settling tank 122 through a water inlet pipe 1223 arranged on the drinking water pipe 1221; the tested water in the sand storage tank 122 flows into the bottom water outlet pipeline 123 through the bottom water outlet pipe 1224, and after flowing out near the bottom water outlet pipeline 123, the tested water can flow into the non-reagent flow-through cell group 124 through the non-reagent test pipeline 1233 for testing of the tested water, and can also be discharged through the emptying and backwashing pipeline 1230; during normal detection, the detected water flows into the reagent-free flow cell stack 1124 through the reagent-free test pipeline 1233 and then enters the overflow drain and backwash pipeline 125, the overflow drain and backwash pipeline 125 can drain the detected water through the detected water drain pipeline 1251, or can be connected with a tap water pipeline (not shown in the figure) through the tap water inlet pipeline 1252, and by controlling the tap water inlet ball valve 12521 on the tap water inlet pipeline 1252, tap water can enter through the tap water inlet pipeline 1252, reversely flush the reagent-free flow cell stack 124, and finally drain out from the emptying and backwash pipeline 1230 through the electromagnetic valve 1231.

The online micro-reagent water quality monitor 2 further comprises a second cabinet 21, a micro-reagent water quality detection device 22 installed in the second cabinet 21, a filter 23 for performing third-stage filtration on the detected water, a pure water tank 24 for supplying the detected water to the micro-reagent water quality detection device 22, and a waste liquid tank 25 for collecting waste liquid generated by the micro-reagent water quality detection device 22.

The micro-reagent water quality detection device 22 further comprises a micro-reagent total phosphorus on-line analyzer 221 and a micro-reagent total nitrogen on-line analyzer 222 which are installed in the second cabinet 21.

To sum up, the water quality monitoring device 100 of the utility model has high integration degree, and places water distribution, filtering, sand settling, secondary filtering, control, transmission, power failure monitoring, temperature and humidity monitoring and monitoring devices in a set of devices, which is convenient for carrying and installation, and the water quality monitoring device 100 of the utility model has simple filtering and pipeline system, can effectively realize the functions of filtering, sand settling, secondary filtering and the like, and simultaneously has the maintenance functions of backwashing, high-pressure air cleaning and the like; the water quality monitoring equipment is simultaneously and specifically free of a reagent and a micro-reagent detection mode, so that the reagent is free of reagent consumption, and monitoring data can be rapidly issued; the micro reagent has low dosage, can not be replaced for a long time, and effectively prolongs the maintenance period.

The above-mentioned technical solution is only the preferred embodiment of the water quality monitoring device 100 of the present invention, which is not used for limiting the protection scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the water quality monitoring apparatus 100 of the present invention is included in the protection scope of the present invention.

Claims (15)

1. A water quality monitoring device is characterized in that: the water quality monitoring equipment consists of a multi-parameter water quality on-line monitor and a micro-reagent water quality on-line monitor; the multi-parameter water quality on-line monitor further comprises a first cabinet, a water distribution pipeline which is arranged in the first cabinet and at least has two-stage filtering, sand settling, overflowing and backwashing functions, a water collecting device which is used for taking and distributing the measured water to the water distribution pipeline arranged in the first cabinet, a reagent-free water quality monitoring device which is arranged and connected on the water distribution pipeline, and a high-pressure flushing device which is arranged and connected on the reagent-free water quality monitoring device.

2. A water quality monitoring apparatus according to claim 1, characterised in that: the water distribution pipeline further comprises a water inlet pipeline, a water storage sand settling tank, a bottom water outlet pipeline, a reagent-free flow cell group, an overflow and drainage and back flushing pipeline and a secondary filtering device.

3. A water quality monitoring apparatus according to claim 2, wherein: the water storage sand settling tank further comprises a drinking water pipe and drinking water pipe caps packaged at two ends of the drinking water pipe, and the water storage sand settling tank is provided with a water inlet pipe, a bottom water outlet pipe, a side liquid level observation pipe, a side overflow pipe and a top vent pipe which are all communicated with the drinking water pipe.

4. A water quality monitoring apparatus according to claim 2 or 3, wherein: the water inlet pipeline is formed by sequentially connecting a measured water inlet pipeline, a first filter, a flowmeter and a UPVC pipeline with the outer diameter of 32 mmUPVC.

5. A water quality monitoring apparatus according to claim 3 wherein: the second-stage filtering device is communicated with the water storage sand settling tank through a second-stage filtering water intake arranged on the drinking water pipe body.

6. A water quality monitoring apparatus according to claim 2, wherein: the second-stage filtering device is formed by sequentially connecting a straight-through filter for finely filtering the water to be measured, a three-way electromagnetic valve and a fine filtering water storage tank, and the straight-through filter is connected to the second-stage filtering water intake.

7. A water quality monitoring apparatus according to claim 2, wherein: the bottom water outlet pipeline further comprises an emptying and back flushing pipeline and a reagent-free testing pipeline.

8. A water quality monitoring apparatus according to claim 7 wherein: the evacuation and backwash pipeline is composed of an electromagnetic valve and an evacuation and backwash pipe.

9. A water quality monitoring apparatus according to claim 2, wherein: the overflow drain and back flush pipeline further comprises a measured water outlet pipeline and a tap water inlet pipeline.

10. A water quality monitoring apparatus according to claim 2, wherein: the reagent-free water quality monitoring device comprises a spectrum sensor, an ion sensor, a dissolved oxygen sensor and a conductivity sensor.

11. A water quality monitoring apparatus according to claim 10 wherein: the high-pressure flushing device consists of an air compressor, an air filter, a high-pressure air electromagnetic valve, a three-way electromagnetic valve and a plurality of pipelines.

12. A water quality monitoring apparatus according to claim 11 wherein: the air compressor, the air filter, the high-pressure air electromagnetic valve and the spectrum sensor, the ion sensor, the dissolved oxygen sensor and the conductivity sensor in the reagent-free water quality monitoring device are sequentially connected to form a first high-pressure flushing pipeline.

13. A water quality monitoring apparatus according to claim 11 wherein: and the air compressor, the air filter, the high-pressure air electromagnetic valve and the three-way electromagnetic valve are sequentially connected to form a second high-pressure flushing pipeline.

14. A water quality monitoring apparatus according to claim 1, characterised in that: the micro-reagent water quality on-line monitor further comprises a second cabinet, a micro-reagent water quality detection device arranged in the second cabinet, a filter used for carrying out third-stage filtration on the detected water, a pure water barrel used for providing the detected water to the micro-reagent water quality detection device, and a waste liquid barrel used for collecting waste liquid generated by the micro-reagent water quality detection device.

15. A water quality monitoring apparatus according to claim 14 wherein: the micro-reagent water quality detection device further comprises a micro-reagent total phosphorus online analyzer and a micro-reagent total nitrogen online analyzer which are arranged in the second cabinet.

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