CN214844782U - Optical path-variable multi-parameter water quality monitoring device based on spectrum method - Google Patents

Abstract

The utility model discloses a multi-parameter water quality monitoring device with variable optical path based on a spectrum method, which comprises an upper shell, a lower shell, a light source, a power supply, a collimating lens, an optical sorting reflector, an optical filter, a temperature sensor, a central microprocessor, a memory and a motor; the upper shell and the lower shell are rotatably connected through a bearing, and grooves with different heights are oppositely arranged at the joint of the upper shell and the lower shell; light-transmitting windows are correspondingly arranged on the upper panel and the lower panel of the groove; the lower panel of each groove can rotate 360 degrees along with the lower shell; an optical sorting reflector, a collimating lens and a light source are sequentially arranged in the lower shell below the lower panel of one of the grooves from top to bottom, and a first photoelectric detector is arranged on one side of the optical sorting reflector; a second photoelectric detector and a third photoelectric detector are respectively arranged in the upper shell above the upper panels of the two grooves; and the front of the input end of the photoelectric detector is provided with an optical filter.

Description

Optical path-variable multi-parameter water quality monitoring device based on spectrum method

Technical Field

The utility model relates to a water quality monitoring field, especially a multi-index quality of water on-line monitoring device of variable optical path that can make real-time concentration correction according to current turbidity based on spectrum method.

Background

With the development of economy and the acceleration of urbanization process in China, the problem of environmental pollution is becoming more serious. Water resources are closely related to production and life of people, and the water environment is seriously damaged by illegal discharge of industrial wastewater, use of chemical pesticides, substandard treatment of urban domestic wastewater and the like. The most direct impact of pollution is a serious threat to human health. Because China is still in a high-incidence stage of pollution events, particularly water pollution events are the most frequent and the most serious in harm, aiming at the characteristic that water pollution has burst property and diffusivity, management and control are conducted from the source, the construction of an online monitoring and analyzing instrument and a platform is enhanced, the monitoring strength is improved, and meanwhile, water quality is timely and accurately tracked and monitored in key water areas, particularly areas where a plurality of key rivers are intersected, industrial and agricultural are developed, and interaction between underground water and surface water is frequent.

The water quality monitoring is a process for monitoring and measuring the concentration and the change trend of specific pollutants in a water body and evaluating the water quality according to the concentration and the change trend, and is important for implementing water environment protection and water resource management. Some of the important indicators for evaluating water quality include: temperature, chromaticity, turbidity, pH, conductivity, suspended matter, Dissolved Oxygen (DO), Chemical Oxygen Demand (COD), Biochemical Oxygen Demand (BOD), nitrate Nitrogen (NO)₃-N), etc. The method mainly comprises the following steps: biological, chemical, spectroscopic methods, and the like.

The water quality analyzer based on the biological method is generally large and bloated in size, and a sensing element is easy to generate irreversible reaction, so that the identification precision is influenced, the maintenance cost is high, and the water quality analyzer is not used as a main monitoring means.

Domestic water quality measurement by a spectroscopic method starts late, so that most of national standards adopt a chemical method. But the chemical method water quality analyzer has obvious defects: the measurement requires reagent consumption, high power consumption, and requires professional operation. Has the characteristics of secondary pollution, long sampling test period, incapability of tracking water quality change, complex maintenance and high cost.

Spectroscopy is different from biological and chemical methods, and can measure multiple indices simultaneously. No reagent is needed, secondary pollution is avoided, the analysis speed is high, online analysis is easy to realize, the device is simple and convenient to maintain, and the use cost is low. The existing water quality analyzer with a spectrum method mainly comprises an Ultraviolet (UV)/ultraviolet-visible light (UV-VIS)/fluorescence absorption spectrum analysis method.

However, most of the existing on-line spectrum monitoring devices adopt cabinet structures and can only monitor one parameter, and have high power consumption and large volume, so that the deployment flexibility is low, and in-situ detection cannot be carried out. When the water body has complex components and serious pollution, the turbidity of the water body seriously interferes with the accuracy. The narrow optical path is also easily blocked by contaminants, suspended particles and microorganisms, which has a large influence on the measurement accuracy. In addition, due to the characteristics of the spectrum method, the measurement precision can not be ensured when the water sample with large pollutant concentration span is faced.

The span of light absorbing species/target contaminant concentration in natural water is large. The optical path length, molar absorption coefficient as a function of the wavelength of the light used, and the light-absorbing species concentration are constrained by a description of the equation on the right of beer-lambert law. This also results in the fact that at shorter wavelengths, the contrast of the signal of a typical fixed optical path sensor cannot be maintained at a high level, and therefore a lower concentration of light absorbing species cannot be accurately measured. But beer-lambert law also provides a solution: changing the optical path length, and using a longer optical path length at low concentration and a shorter optical path length at high concentration. There are researchers who insert a transparent medium in the optical path to change the optical path length (JP2006194775A), see fig. 1, but it is obvious that it is not suitable for long-term in-situ measurement devices.

The above disadvantages lead to the water quality sensors available on the market not being suitable for in-situ, long-term, stable and accurate monitoring of water quality.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the not enough among the prior art, provide a variable optical path multi-parameter water quality monitoring device based on spectrum method, satisfy small in size, analysis time weak point, do not receive the influence of pollutant concentration, measuring result accuracy to receive disturb little, maintain convenient characteristics, the specially adapted carries out the normal position long-term measurement of multiple spot to quality of water.

The utility model aims at realizing through the following technical scheme:

a multi-parameter water quality monitoring device with variable optical path based on a spectrum method comprises an upper shell, a lower shell, a light source, a power supply, a collimating lens, an optical sorting reflector, a temperature sensor, a central microprocessor, a memory and a motor; the upper shell and the lower shell are both of cylindrical cavity structures, the upper shell and the lower shell are rotatably connected through a bearing, and grooves with different heights are oppositely arranged at the joint of the upper shell and the lower shell; light-transmitting windows are correspondingly arranged on the upper panel and the lower panel of the groove; the lower panel of each groove can rotate 360 degrees along with the lower shell; an optical sorting reflector, a collimating lens and a light source are sequentially arranged in the lower shell below the lower panel of one of the grooves from top to bottom, and a first photoelectric detector is arranged on one side of the optical sorting reflector; a second photoelectric detector and a third photoelectric detector are respectively arranged in the upper shell above the upper panels of the two grooves; when the light source is ultraviolet light, optical filters are arranged in front of the input ends of the first photoelectric detector, the second photoelectric detector and the third photoelectric detector; when the light source is a full-spectrum light source, concave holographic gratings are arranged in front of the input ends of the first photoelectric detector, the second photoelectric detector and the third photoelectric detector; the temperature sensor, the central microprocessor, the memory, the power supply and the motor are all arranged in the upper shell; the central microprocessor is connected with the temperature sensor, the memory, the power supply, the motor, the first photoelectric detector, the second photoelectric detector and the third photoelectric detector; the motor transmission shaft is connected with the lower shell, and 360-degree rotation of the lower shell is achieved through manual operation or motor control.

Further, a seal is arranged between the upper shell and the lower shell.

Further, the lower housing is smaller than the upper housing.

Furthermore, the top of the upper shell is provided with an interface, and the central microprocessor is connected with an external system through the interface.

Compared with the prior art, the utility model discloses a beneficial effect that technical scheme brought is:

1. the utility model provides an on-line monitoring device, the design is exquisite, and cylindrical airtight shell is hard corrosion-resistant, is applicable to various waters such as fresh water, sea water, highly polluted water. Can be applied to various harsh industrial and natural environments.

2. The utility model discloses inside used component small in size makes portablely simple, and the repacking is convenient, can deal with multiple condition in a flexible way, provides the normal position for multiple water and measures. Meanwhile, a plurality of parameters can be measured, so that the cost is effectively reduced, and the information content is improved. The system can be applied to large-scale deployment for the purposes of environmental protection monitoring, scientific research and the like.

3. The utility model discloses analysis time is short, stability is high, can real-time supervision and measuring result accurate. And meanwhile, a local calculation and storage module is provided, so that the device can be independently used for carrying out long-term in-situ measurement. The communication and power-on interface at the top makes it possess excellent scalability, makes it can match multiple cleanness, sensor cluster, protection device. And the external unit can be connected through a cable to provide additional power supply, calculation and storage capacity, so that longer-term in-situ measurement is realized.

4. The utility model provides an on-line monitoring appearance uses the optics method, under the condition that does not introduce secondary pollution, the content of a plurality of parameters in quick accurate sign aquatic. The provided functions of turbidity correction and temperature correction overcome the interference to the measurement accuracy when the water body components are complex and the turbidity is high.

5. The utility model discloses a structure can change key element according to the different demands of precision, target pollutant, realizes the switching of ultraviolet ray, ultraviolet-visible light method.

6. The utility model discloses a structure can the physics change the optical path to can change the target pollutant concentration and make judgement and reflect in real time, automatic or manual change optical path, overcome the concentration and stride big interference to signal contrast, measurement accuracy more. Can ensure consistent signal contrast and measurement precision at any time and any place.

7. The utility model discloses but upper and lower two parts casing split. A consumable is contained within the cavity of the lower housing. The light source is replaced, and the service life of the instrument is prolonged.

8. The utility model discloses water quality monitoring device can help the jam of pollutant, suspended particle and microorganism in the clean narrow light path. And the early warning and cleaning are carried out by self through the judgment of the received signal. Meanwhile, the sampling accuracy is ensured, and the maintenance times are reduced.

Drawings

Fig. 1 is a schematic diagram of changing a light path using a transparent medium.

Fig. 2 is a schematic structural diagram of the device of the present invention.

FIG. 3 is a diagram of a central microprocessor.

FIG. 4 is a schematic flow diagram of a water quality monitoring method.

Detailed Description

The present invention will be described in further detail with reference to the following drawings and specific embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The utility model discloses water quality sensor based on spectrum method utilizes different materials in the water to carry out assay to the extinction mechanism of ultraviolet ray (190-. The method is characterized in that a UV Light Emitting Diode (LED) is used as a deep ultraviolet (190-. Due to the development of photoelectric elements and the improvement of materials science in recent years, the volume of a required device can be greatly reduced, and the effects of multipoint in-situ measurement, portability and flexible deployment are achieved.

According to Beer-lambert Law (Beer-Lamber Law), the material absorbance can be expressed as:

wherein A is the absorbance, I_tIs the intensity of transmitted light, I₀Is the incident light intensity,. epsilon.is the molar absorption coefficient, b is the optical path length, and C is the light-absorbing species concentration.

To achieve this measurement, the UV/UV-VIS light source in the apparatus will illuminate the body of water on the light path. Light absorbing substances/target contaminants in the water body will absorb part of the light at a specific wavelength, attenuating the incident light intensity. The attenuated transmitted light is irradiated onto a photodetector at the other end of the optical path, thereby generating a photocurrent. The photocurrent is converted by the transimpedance amplifier to output voltage, so as to generate a signal to judge the absorbance of the substance, and further calculate the concentration of the light absorption substance.

However, in a high turbidity environment, turbidity causes nonlinear increase to the whole ultraviolet-visible spectrum, and scattering loss caused by an analyte greatly influences the judgment of absorbance. For example: at λ wavelength, the absorbance measured A (λ) ═ A_Contaminants(λ)+A_{Turbidity of water}(λ)+A_{Interfering substance}(lambda). If the absorbance of other interferents is zero, the absorbance of the contaminant is obtained by subtracting the absorbance A of turbidity at the current wavelength from the actually measured absorbance A (lambda)_{Turbidity of water}And (lambda) can accomplish the correction of turbidity. The absorbance and turbidity are approximately linear due to turbidity at the same wavelength. Thus, with the support of a large amount of data and known turbidity, the user can select the type of particulate matter on a case-by-case basis or calculate the turbidity absorbance A using preset intermediate values_{Turbidity of water}(λ)。

The utility model discloses reach the purpose that changes light path length at any time in order to adapt to the concentration change with the physical design of monitoring devices itself.

The light source adopts the ultraviolet ray in this embodiment, as shown in the left monitoring devices in fig. 2, the embodiment of the utility model provides an in the device structure contain after simplifying circuit, other auxiliary component and battery: an upper housing 12, a lower housing 13, a light source 1, a collimating lens 2, an optical sorting mirror 3, a filter 5, a temperature sensor 9, a central microprocessor 10, a memory 11, and a motor 15; the upper shell 12 and the lower shell 13 are both cylindrical cavity structures, the upper shell 12 and the lower shell 13 are rotatably connected through a bearing, and grooves with different heights are oppositely arranged between the connection positions of the upper shell 12 and the lower shell 13 to be used as measurement areas; the upper panel 16 and the lower panel 17 of the groove are respectively provided with a light-transmitting window correspondingly for forming a light path channel 4; the lower panel 17 of each groove can rotate 360 degrees with the lower shell 13; an optical sorting reflector 3, a collimating lens 2 and a light source 1 are sequentially arranged in the lower shell below the lower panel 17 of one groove from top to bottom, and a condensing lens can be arranged between the collimating lens 2 and the light source 1 in the specific implementation process; one side of the optical sorting reflector 3 is sequentially provided with a photoelectric detector 7; photoelectric detectors 6 and 8 are respectively arranged in the upper shell above the upper panels of the two grooves; the optical filters 5 are arranged in front of the input ends of the photoelectric detectors 7, 6 and 8; the temperature sensor 9, the central microprocessor 10, the memory 11 and the power supply are all arranged in the upper shell; the central microprocessor 10 is connected with the temperature sensor 9, the memory 11, the power supply, the motor 15, the photoelectric detector 7, the photoelectric detector 6 and the photoelectric detector 8; in this embodiment, the motor 15 is disposed at a joint of the upper housing and the lower housing, and the motor shaft is connected to the lower housing, so that the lower housing can be rotated by 360 degrees manually or by controlling the motor.

In the embodiment, of the two grooves, the relatively narrow groove is used for measuring the low-concentration short-range optical path, and the relatively wide groove is used for measuring the high-concentration long-range optical path;

specifically, the material of the upper housing 12 and the lower housing 13 may be made of corrosion-resistant materials such as stainless steel and titanium. The upper housing 12 and the lower housing 13 are linked and sealed by freely rotatable bearings. The lower structure is small, and can be manually or automatically rotated by 360 degrees under the drive of a motor. Such rotation may serve the purpose of physically changing the optical path while helping to clear contaminants, suspended particles, microorganisms, etc. that may have become lodged in the measurement area. All components can be driven by high performance lithium batteries in the superstructure and also can be operated for longer periods of time by external power supply using the top interface 14 connection cable, thereby providing multiple monitoring schemes to suit different situations.

The control structure of the central microprocessor is shown in fig. 3. The central microprocessor 10 in the upper chamber is used to process the signals of the photodetectors, temperature sensors, etc., and incorporates the functions of signal calculation and turbidity correction. Be responsible for simultaneously judging monitoring devices state itself, include: electric quantity, smooth condition of light path, concentration change, motor load, storage capacity, temperature and the like, and correspondingly reacts. The device can give instructions to drive a motor, send an alarm signal, enter a power saving mode, enter a protection mode and the like. All recorded data will be stored in the memory 11.

The light source 1 and the filter 5 may be selected as appropriate for use with Ultraviolet (UV), ultraviolet-visible (UV-VIS) light sources and corresponding filters. All the photoelectric detectors in the embodiment are composed of photodiodes, and when the light source is UV-VIS, the photoelectric detectors are composed of a plurality of photodiodes to form an array form, so that a multi-channel detector is formed; in addition, the filter in fig. 2 should also become a grating. The light generated by the light source 1 will first pass through a collimating lens according to the optical path shown in fig. 2, and the collimating lens may use optical materials such as ultraviolet optical quartz glass to achieve a light transmittance of more than 90% at the full spectrum. Then, a part of the reference light passes through the optical sorting mirror 3 and is emitted to the photodetector 7 as a reference light through an optical filter, and a photocurrent is generated and is converted into a voltage by a transimpedance amplifier and then is output to the central microprocessor 10 as a reference signal R. The other part can be realized by two measuring areas of different lengths, i.e. by rotating the lower housing structure. When a low concentration contaminant is measured using a short optical path, the lower housing 13 is rotated to position a in fig. 2. When measuring high concentrations of contaminants using a long optical path, the lower housing 13 is rotated 180 degrees from position a to position B in fig. 2. This light, after passing through the light absorbing substance/target contaminant in the water, is incident on the upper housing 12, passes through the optical filter toward the photodetector 6 for low concentration measurement or the photodetector 8 for high concentration measurement, and generates a photocurrent. The photocurrent is converted to a voltage by a transimpedance amplifier and output as a measurement signal M to the central microprocessor 10. At this time, the central microprocessor performs the above-described turbidity correction on the result according to the preset value of the user, calculates the final result and stores the final result in the memory.

The present invention is not limited to the above-described embodiments. The above description of the embodiments is intended to describe and illustrate the technical solutions of the present invention, and the above embodiments are merely illustrative and not restrictive. Without departing from the spirit of the invention and the scope of the appended claims, the person skilled in the art can make many changes in form and detail within the teaching of the invention.

Claims (4)

1. A multi-parameter water quality monitoring device with variable optical path based on a spectrum method is characterized by comprising an upper shell, a lower shell, a light source, a power supply, a collimating lens, an optical sorting reflector, a temperature sensor, a central microprocessor, a memory and a motor; the upper shell and the lower shell are both of cylindrical cavity structures, the upper shell and the lower shell are rotatably connected through a bearing, and grooves with different heights are oppositely arranged at the joint of the upper shell and the lower shell; light-transmitting windows are correspondingly arranged on the upper panel and the lower panel of the groove; the lower panel of each groove can rotate 360 degrees along with the lower shell; an optical sorting reflector, a collimating lens and a light source are sequentially arranged in the lower shell below the lower panel of one of the grooves from top to bottom, and a first photoelectric detector is arranged on one side of the optical sorting reflector; a second photoelectric detector and a third photoelectric detector are respectively arranged in the upper shell above the upper panels of the two grooves; when the light source is ultraviolet light, optical filters are arranged in front of the input ends of the first photoelectric detector, the second photoelectric detector and the third photoelectric detector; when the light source is a full-spectrum light source, concave holographic gratings are arranged in front of the input ends of the first photoelectric detector, the second photoelectric detector and the third photoelectric detector; the temperature sensor, the central microprocessor, the memory, the power supply and the motor are all arranged in the upper shell; the central microprocessor is connected with the temperature sensor, the memory, the power supply, the motor, the first photoelectric detector, the second photoelectric detector and the third photoelectric detector; the motor transmission shaft is connected with the lower shell, and 360-degree rotation of the lower shell is achieved through manual operation or motor control.

2. The apparatus of claim 1, wherein a seal is disposed between the upper housing and the lower housing.

3. The apparatus of claim 1, wherein the lower housing is smaller than the upper housing.

4. The apparatus of claim 1, wherein an interface is provided on the top of the upper housing, and the central microprocessor is connected to an external system via the interface.

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