CN216870535U - Real-time water body detection cup - Google Patents

Abstract

The utility model relates to the technical field of water treatment, in particular to a real-time water body detection cup, wherein an overflow baffle is arranged in the detection cup, and the height of the overflow baffle is smaller than that of the inner space of the detection cup; the overflow baffle divides the interior of the detection cup to form a plurality of parallel detection cavities; a liquid inlet communicated with the detection cavity is formed in the side wall of the detection cup, and a first liquid outlet is formed in the symmetrical end face of the detection cup; the upper end of the detection cup of any detection cavity is provided with a corresponding detection port, and the lower end of the detection cup is provided with a corresponding liquid collection port; and a valve is arranged on the liquid collecting port. The utility model solves the problems that the existing water body detection process usually adopts a water body submission mode, but the mode can influence the maintenance and overhaul efficiency, and simultaneously, the water body is difficult to ensure not to be polluted by the external environment in the submission process, so that the detection result is not accurate enough.

Description

Real-time water body detection cup

Technical Field

The utility model relates to the technical field of water treatment, in particular to a real-time water body detection cup.

Background

The water treatment mode comprises physical treatment, chemical treatment and biological treatment, wherein the physical method comprises the steps of utilizing different filter materials with different pore sizes, utilizing an adsorption or blocking mode to remove impurities in water, the more important one in the adsorption mode is adsorption by using activated carbon, and the blocking method is to pass water through the filter materials, so that the impurities with larger volume cannot pass through, and then clean water is obtained. In addition, the physical method also comprises a precipitation method, namely, impurities with smaller specific gravity are floated on the water surface and fished out, or impurities with larger specific gravity are precipitated under the water surface, and then the impurities are obtained; the chemical method is to convert impurities in water into substances which are less harmful to human bodies by various chemicals or concentrate the impurities, and the longest history chemical treatment method can be that alum is added into water, and after the impurities in the water are collected, the volume of the water is increased, and then the impurities can be removed by a filtration method.

In the existing water treatment process, a plurality of flow-based operations are usually required to ensure clean water quality, so in the process of maintenance and repair, sampling detection needs to be performed on the water quality after each operation to determine whether the flow in the current step is executed smoothly.

However, the existing water quality sampling detection generally needs to deliver water to detect, so that the problem that the water quality is polluted by substances generated in the detection process or detection equipment is influenced due to the fact that the water is detected on site, but the detection result cannot be obtained in real time due to the adoption of the delivery detection mode, the overhauling and maintenance efficiency is influenced, and meanwhile, the stability of the water in the transportation process is difficult to ensure, and the detection result is inaccurate is solved.

SUMMERY OF THE UTILITY MODEL

The utility model provides a real-time water body detection cup, which mainly solves the problem that in the existing water body detection process, a water body inspection mode is usually adopted, but the maintenance and overhaul efficiency is influenced by the mode, and meanwhile, the problem that the detection result is not accurate enough because the water body is not polluted by the external environment in the inspection process is difficult to ensure is solved.

The utility model provides a real-time water body detection cup, wherein an overflow baffle is arranged in the detection cup, and the height of the overflow baffle is smaller than that of the inner space of the detection cup; the overflow baffle divides the interior of the detection cup to form a plurality of parallel detection cavities; a liquid inlet communicated with the detection cavity is formed in the side wall of the detection cup, and a first liquid outlet is formed in the symmetrical end face of the detection cup; the upper end of the detection cup of any detection cavity is provided with a corresponding detection port, and the lower end of the detection cup is provided with a corresponding liquid collection port; and a valve is arranged on the liquid collecting port.

Preferably, the liquid collecting device further comprises a liquid collecting cavity communicated with all the liquid collecting ports, and a second liquid outlet is formed in the side wall of the liquid collecting cavity.

Preferably, the liquid collecting cavity is arranged at the lower end of the detection cup; the bottom of the detection cavity is an inclined plane, and the liquid collection port is arranged at the lower end of the upper horizontal plane of the bottom of the detection cavity.

Preferably, a plurality of observation windows are arranged on the detection cup, and any observation window corresponds to any detection cavity; all the observation windows are distributed in parallel and are vertically arranged.

Preferably, the observation window is formed with a depth gauge.

Preferably, the overflow baffle is vertically disposed.

Preferably, the volumes of all the detection chambers are uniform.

From the above, the following beneficial effects can be obtained by applying the technical scheme provided by the utility model:

firstly, the water body detection cup provided by the utility model provides a portable test container for water body detection, so that the real-time performance of the water body detection is realized, the detection efficiency is improved, meanwhile, the correlation between a sample and a body is ensured by the water body detected in real time, and the accuracy of detection data is further ensured;

secondly, the water body detection provided by the utility model is provided with a plurality of detection cavities, so that different detections can be carried out on the water body, and detection data can cover all values required by the detection;

thirdly, the liquid collecting cavity is arranged on the water body detection cup, so that substances formed by the detected water body sample can be extracted, and observation and next detection are facilitated;

fourthly, the observation window is arranged on the water body detection cup provided by the utility model, so that the water body content and the water body color can be conveniently recorded and calculated, the content of the detection agent required by detection can be further calculated, the color of a product after reaction can be observed, and the like, and the observation is convenient.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic front structural view of a water body detection cup in an embodiment of the utility model;

FIG. 2 is a schematic side view of a water body detection cup according to an embodiment of the utility model.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It is to be understood that the described embodiments are merely exemplary of the utility model, and not restrictive of the full scope of the utility model. All other embodiments, which can be obtained by a person skilled in the art without inventive effort based on the embodiments of the present invention, are within the scope of the present invention.

In the existing water body detection process, water bodies in different steps need to be detected respectively, multiple water body samples need to be inspected, maintenance efficiency is reduced, and even the detection result is inaccurate due to pollution in transportation.

As shown in fig. 1 and fig. 2, in order to solve the above problem, the present embodiment provides a real-time water body detection cup, an overflow baffle 10 is disposed in the detection cup, and the height of the overflow baffle 10 is smaller than the height of the inner space of the detection cup; the overflow baffle 10 divides the interior of the detection cup to form a plurality of parallel detection cavities 20; a liquid inlet 31 communicated with the detection cavity 20 is formed in the side wall of the detection cup, and a first liquid outlet 32 is formed in the symmetrical section of the detection cup; the upper end of the detection cup of any detection cavity 20 is provided with a corresponding detection port 34, and the lower end is provided with a corresponding liquid collection port 35; a valve is arranged on the liquid collecting port 35.

Preferably, but not limitatively, the overflow baffles 10 are arranged vertically in this embodiment.

Preferably, but not limitatively, the volume of all detection chambers 20 is the same in this embodiment.

Preferably, but not limited to, in this embodiment, the level of the liquid inlet 31 is located below the level of the upper end surface of the overflow baffle 10, so as to prevent the water body at the liquid inlet 31 from splashing to the second detection chamber 20 due to large impact force, which affects the detection result. Preferably, the liquid inlet 31 is communicated with a liquid inlet channel, and the downward extending end of the liquid inlet channel is arranged near the bottom of the first detection cavity 20.

Preferably, but not limited to, the liquid inlet 31 and the liquid outlet are located on the same horizontal plane in this embodiment.

Preferably, but not limited to, the detection port 34 and the liquid collection port 35 are disposed on the central axis of each detection chamber 20 in the present embodiment.

More specifically, the liquid collecting chamber 40 is further included, and the side wall of the liquid collecting chamber 40 is provided with a second liquid outlet 33.

Preferably, but not limited to, in the present embodiment, the cavity length of the liquid collecting cavity 40 is equal to the cavity length of all the detection cavities 20, that is, the cavity length of the liquid collecting cavity 40 is equal to the length of the detection cup.

In this embodiment, when a corresponding detection reaction occurs in the detection chamber 20 and generates a substance or changes a color, etc., the water body can be controlled to flow to the liquid collection chamber 40 through the liquid collection port 35, and discharged from the second liquid outlet 33 or a detection sample, etc. can be obtained from the second liquid outlet 33.

More specifically, the liquid collection chamber 40 is disposed at the lower end of the detection cup; the bottom of the detection chamber 20 is an inclined plane, and the liquid collection port 35 is arranged at the lower end of the horizontal plane on the bottom of the detection chamber 20.

Preferably, but not limited to, the liquid collecting chamber 40 is disposed below all the detection chambers 20 in the present embodiment, so that the water drained from the liquid collecting port 35 can move toward the liquid collecting chamber 40 due to its own weight.

More specifically, a plurality of observation windows 50 are formed on the detection cup, and any observation window 50 corresponds to any detection cavity 20; all viewing windows 50 are distributed parallel and vertically.

Preferably, the observation window 50 is formed with a depth gauge in the present embodiment.

Preferably, but not limited to, the observation window 50 is installed by using a transparent colorless glass.

Preferably, but not limitatively, the viewing window 50 is of elongate shape in this embodiment and its upper end should be at least at the same level as the upper end of the overflow baffle 10.

In conclusion, this embodiment provides a real-time water body detection cup, and it mainly through providing real-time, convenient detection container for the water body detects, avoids the censorship step, has improved detection efficiency, avoids the environmental pollution of censorship in-process simultaneously, has further ensured the accuracy of detection data.

The above-described embodiments do not limit the scope of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the above-described embodiments should be included in the protection scope of the technical solution.

Claims (7)

1. A real-time water body detection cup is characterized in that: an overflow baffle is arranged in the detection cup, and the height of the overflow baffle is smaller than that of the inner space of the detection cup; the overflow baffle divides the interior of the detection cup to form a plurality of parallel detection cavities; a liquid inlet communicated with the detection cavity is formed in the side wall of the detection cup, and a first liquid outlet is formed in the symmetrical end face of the detection cup; the upper end of the detection cup of any detection cavity is provided with a corresponding detection port, and the lower end of the detection cup is provided with a corresponding liquid collection port; and a valve is arranged on the liquid collecting port.

2. The real-time water body detection cup according to claim 1, wherein: the liquid collecting device is characterized by further comprising a liquid collecting cavity communicated with all the liquid collecting ports, and a second liquid outlet is formed in the side wall of the liquid collecting cavity.

3. The real-time water body detection cup of claim 2, wherein: the liquid collecting cavity is arranged at the lower end of the detection cup; the bottom of the detection cavity is an inclined plane, and the liquid collection port is arranged at the lower end of the upper horizontal plane of the bottom of the detection cavity.

4. A real-time water body detection cup according to any one of claims 1 to 3, wherein: a plurality of observation windows are formed in the detection cup, and any observation window corresponds to any detection cavity; all the observation windows are distributed in parallel and are vertically arranged.

5. The real-time water body detection cup according to claim 4, wherein: and a depth gauge is formed on the observation window.

6. The real-time water body detection cup according to claim 5, wherein: the overflow baffle is vertically arranged.

7. The real-time water body detection cup of claim 6, wherein: the volumes of all the detection cavities are consistent.

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