KR101480891B1 - Performance testing apparatus for treating waste water and wastewater treatment apparatus using aerobic treatment having the same - Google Patents

Abstract

The present invention relates to a wastewater treatment performance test apparatus capable of simply testing the performance of a wastewater treatment facility for treating wastewater in an aerobic manner and an aerobic wastewater treatment apparatus having the same. An apparatus for testing a wastewater treatment performance according to the present invention comprises a collecting hood which is provided so as to cover a part of a water surface of wastewater in a treated water tank provided with a diffuser and in which an inlet through which gas generated from wastewater flows is formed on a bottom surface, An analyzer connected to the branch pipe, an analysis gas suction pump for sucking gas into the branch pipe, a gas suction pump, an analyzer and an analysis gas suction pipe A controller for controlling the pump; a controller for controlling the pump; and a controller for controlling the pump, wherein the controller is disposed to float above the water surface of the wastewater in the collection hood and is raised by the suction force of the gas collection tube when the pressure inside the gas collection tube is excessively low, To prevent gas from entering the gas collection pipe.

Description

TECHNICAL FIELD [0001] The present invention relates to a wastewater treatment performance testing apparatus and a breathing wastewater treatment apparatus having the wastewater treatment performance testing apparatus.

The present invention relates to a wastewater treatment performance test apparatus, and more particularly, to a wastewater treatment performance test apparatus capable of simply testing the performance of a wastewater treatment facility for treating wastewater in an aerobic manner, and an aerobic wastewater treatment apparatus having the same .

Wastewater treatment methods include physical and chemical methods and biological methods. Physical and chemical methods require less facility investment and faster processing speeds, but require more operating costs due to chemical consumption. In addition, since the treated product must be reprocessed or disposed, there is another disadvantage of causing environmental contamination of other types.

Biological methods, on the other hand, do not harm the natural environment. Biological methods use bacteria, fungi, algae, protozoa, etc. to decompose or decontaminate contaminants in wastewater, converting organic materials to carbon dioxide or methane gas. Biological methods are widely used for secondary treatment of city living sewage and industrial wastewater treatment process containing organic matter.

The types of microorganisms that grow in the biological treatment process can be divided into floating growth and deposition growth. In the treatment with floating growth, degradation of the substrate and cell growth occur in the suspended state in the wastewater. Treatment methods using floating growth include activated sludge method, frozen suspension, and anaerobic digestion method.

In the case of adherent growth, organic matter is decomposed and cells grow, resulting in a thin mucous biofilm on the solid surface. The wastewater treatment method using this is called biofilm process or fixed film process. Examples of biofilm processes include the flesh-transfer method, spinning disc method, sedimentation method, and anaerobic biofilm method.

Biological treatment process can be divided into aerobic process and anaerobic process depending on whether oxygen is used or not. Anaerobic treatment utilizes the anaerobic metabolism of anaerobic microorganisms, ie anaerobic respiration and fermentation, which does not require oxygen supply. Anaerobic digestion, corruption, anaerobic digestion, and anaerobic biofilm.

Aerobic treatment utilizes aerobic respiration of microorganisms using oxygen, such as activated sludge method, live sludge method, rotary disc method, sedimentation method. Aerobic treatment has disadvantages such as energy consumption for supplying oxygen, but it does not harm the natural environment because organic matter is decomposed to generate carbon dioxide and water. In addition, the growth of microorganisms is fast and the treatment is rapid.

In the aerobic treatment method, oxygen supply is essential for the growth and activity of aerobic microorganisms, and an air supply device is used for this purpose. The air supply apparatus includes a plurality of air diffusers provided in the aeration tank (reaction tank) to supply air to the liquid wastewater stored in the aeration tank, and a blower for feeding air by the air diffuser. In the aeration tank, since the gas exists in the liquid phase as a dispersed phase, the size of the bubble, the amount of the retention, the contact between the gas phase and the liquid phase, and the flow characteristics thereof have a significant influence on the operating condition, performance and efficiency of the aeration tank.

The wastewater treatment device for supplying air to the wastewater with the air diffuser is disclosed in Korean Patent Publication No. 0481729 (published on Mar. 12, 2004), Korean Patent Publication No. 0621793 (published on July 24, 2006) 0762919 (registered on September 21, 2007).

The performance of the air supply system greatly affects the wastewater treatment capacity of the aeration tank. In order to improve the aeration performance of the air supply device, there is a method of increasing the number of the air diffuser devices or increasing the output of the air blower to supply air to the air diffuser device.

However, if the number of installation of the air diffuser is increased or the output of the blower is increased, the initial installation cost is increased and the processing cost is increased. Therefore, in order to realize an efficient wastewater treatment facility, it is necessary to select an appropriate number of the aeration devices and determine the output of the blower to an appropriate value. To do this, it is necessary to test the wastewater treatment performance of wastewater treatment facilities.

It is an object of the present invention to provide a device for testing the performance of a wastewater treatment facility capable of quickly testing the performance of a wastewater treatment facility by a simple method and an aerobic wastewater treatment device having the same .

In order to accomplish the above object, the apparatus for testing a wastewater treatment performance according to the present invention is provided with a treatment water tank provided with an air diffuser for supplying air, covering a part of the water surface of the wastewater stored in the treatment water tank, A gas collecting pipe connected to a connecting port provided in the collecting hood for guiding the gas introduced into the collecting hood; and a gas collecting pipe connected to the middle of the gas collecting pipe An analyzer connected to the branch for analyzing the gas flowing through the branch, an analyzing gas suction pump connected to the branch for sucking gas into the branch, A controller for controlling the analysis gas suction pump; And a cap which prevents the wastewater in the collecting hood from flowing into the gas collecting tube by shielding the connecting port of the collecting hood by a suction force of the gas collecting tube when the pressure inside the gas collecting tube becomes excessively low, .

The apparatus for testing a wastewater treatment performance according to the present invention may further include a guide bar coupled to the cap to extend into the gas collection pipe and a guide bar provided in the gas collection pipe for guiding the up and down movement of the guide bar, And a support member having a guide groove to be inserted therein.

The apparatus for testing wastewater treatment performance according to the present invention may further include a sealing member provided on an outer surface of the plug to block a gap between the collecting hood and the plug when the plug covers the connecting port of the collecting hood.

Wherein the collecting hood includes a hood body having the inlet and the connecting port formed therein and a float coupled to an outer surface of the hood body to impart buoyancy to the hood body, And a guide surface for guiding the gas impinging on the float to the outside of the hood body may be provided.

Wherein the collecting hood comprises a hood body having the inlet and the connecting port formed therein, a float for imparting buoyancy to the hood body, and a connecting mechanism for connecting the hood body and the float, And a through hole for discharging the gas generated in the outside air into the outside air.

The apparatus for testing a wastewater treatment performance according to the present invention comprises a gas collection pipe opening / closing valve provided in the gas collection pipe for opening and closing a channel inside the gas collection pipe, An air suction pipe connected to the pipe downstream of the gas collection pipe opening / closing valve, and an air suction pipe opening / closing valve installed in the air suction pipe to open / close a flow path inside the air suction pipe.

The wastewater treatment performance test apparatus according to the present invention may further include a gas suction pump connected to the gas collection pipe for sucking gas into the gas collection pipe.

The apparatus for testing wastewater treatment performance according to the present invention is characterized in that it is connected to the air diffuser and connected to an air supply pipe for supplying air to the air diffuser to detect a flow rate of air supplied to the air diffuser, An air pressure meter for detecting the pressure of the air supplied to the air diffuser and providing the detection signal to the analyzer, and an air flow meter connected to the analyzer and disposed upstream of the analyzer, An analyzing gas flow meter for detecting a flow rate and providing the detection signal to the analyzer, and an analyzing gas pressure gauge for detecting a pressure of the gas supplied to the analyzer and providing the detection signal to the analyzer, And the gas collecting pipe is disposed upstream of the connecting portion between the gas collecting pipe An inlet gas meter for detecting the flow rate of the gas flowing along the gas collection tube and providing the detection signal to the analyzer and a suction gas pressure gauge for detecting the pressure of the gas flowing along the gas collection tube and providing the detection signal to the analyzer .

According to an aspect of the present invention, there is provided an apparatus for treating aerated wastewater, comprising: a treatment water tank having a storage space for storing wastewater; a diffuser device disposed in the treatment water tank for supplying air to wastewater stored in the treatment water tank; A blower connected to the air diffuser to supply air to the air diffuser; and an inflow port provided so as to cover a part of the water surface of the wastewater stored in the treatment water tank and into which gas generated in the wastewater flows by aerobic treatment, A gas collection pipe connected to a connection port provided in the collection hood for guiding gas introduced into the collection hood; a branch pipe connected to the middle of the gas collection pipe; An analyzer connected to the branch for analyzing gas flowing through the branch, A controller for controlling the blower, the analyzer, and the analysis gas suction pump; and a controller for controlling the flow rate of the analyzer gas, which is disposed in the collection hood above the water surface of the wastewater, And a cap which is raised by the suction force of the gas collecting tube when the suction force rises excessively to block the connecting port of the collecting hood to prevent the wastewater in the collecting hood from flowing into the gas collecting tube.

The apparatus for testing wastewater treatment performance according to the present invention can quickly test the performance of the aerobic wastewater treatment apparatus such as the oxygen transfer efficiency of the oxidizer for supplying air to the wastewater by a simple method, Can be used.

Further, the apparatus for testing wastewater treatment performance according to the present invention provides data on the wastewater treatment performance of the treatment water tank, thereby designing an optimized aerobic wastewater treatment apparatus such as an optimum output setting of the blower employed, . ≪ / RTI >

Further, the apparatus for testing wastewater treatment performance according to the present invention includes a cap which can seal the connection port of the collection hood inside the collection hood installed in the treatment water tank for trapping the gas generated in the treatment water tank, When the pressure is excessively lowered, the plug is raised by the suction force of the gas collecting tube, thereby blocking the connection port of the collecting hood and preventing the wastewater in the collecting hood from flowing into the gas collecting tube through the inlet of the collecting hood.

Further, the apparatus for treating aerobic wastewater according to the present invention can smoothly and efficiently treat wastewater by controlling the operation of the blower and the like in real time based on the wastewater treatment performance analyzed by the wastewater treatment performance testing apparatus.

1 is a side view showing an aerobic wastewater treatment apparatus according to an embodiment of the present invention.
2 is a block diagram showing a main configuration of an aerobic wastewater treatment apparatus according to an embodiment of the present invention.
FIG. 3 is an illustration of a collection hood and its surrounding components of an aerobic wastewater treatment apparatus according to an embodiment of the present invention.
4 is a side view showing a wastewater treatment performance testing apparatus according to another embodiment of the present invention.
5 is a plan view showing some components of a wastewater treatment performance testing apparatus according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a wastewater treatment performance test apparatus and an aerobic wastewater treatment apparatus having the same according to the present invention will be described in detail with reference to the accompanying drawings.

In describing the present invention, the sizes and shapes of the components shown in the drawings may be exaggerated or simplified for clarity and convenience of explanation. In addition, the terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. These terms are to be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the contents throughout the present specification.

FIG. 1 is a side view showing an aerobic wastewater treatment apparatus according to an embodiment of the present invention. FIG. 2 is a block diagram showing a main configuration of an aerobic wastewater treatment apparatus according to an embodiment of the present invention. The collection hood of the aerobic wastewater treatment apparatus according to an embodiment and peripheral components thereof are illustrated.

1 and 2, an aerobic wastewater treatment apparatus 10 according to an embodiment of the present invention includes a treatment water tank 12 for treating wastewater in an aerobic manner, And a wastewater treatment performance test apparatus 20 for collecting and analyzing a sample of gas. The wastewater is supplied to the treatment water tank 12 through the wastewater inflow pipe 13 and a plurality of air diffusers 14 for supplying air into the wastewater are provided in the treatment water tank 12, as in a conventional aerobic wastewater treatment apparatus Is installed. A plurality of diffuser (14) is connected to the air supply pipe (15). When the blower 16 connected to the air supply pipe 15 is operated, air is supplied in the form of bubbles to the wastewater stored in the process water tank 12 through the air supply pipe 15 and the plurality of the air diffusers 14.

Various air detectors capable of detecting various physical properties of air supplied to the air diffuser 14 such as the air flow meter 17, the air pressure gauge 18 and the air thermometer 19 are connected to the air supply pipe 15. The air flow meter 17, the air pressure gauge 18 and the air temperature gauge 19 detect the flow rate, pressure and temperature of the air supplied to the air diffuser 14, respectively, And provides it to the analyzer 34. The types of air detectors can be varied.

The wastewater treatment performance test apparatus 20 includes a collecting hood 21 installed in the treatment water tank 12 and a gas collecting pipe 30 connected to the collecting hood 21 and guiding the collected gas to the collecting hood 21 An analyzer 34 installed in a branch pipe 31 connected to the middle of the gas collection pipe 30, and a controller 35. [ The wastewater treatment performance test apparatus 20 can quickly test the wastewater treatment performance of the treatment water tank 12 by sampling and analyzing a sample of the gas generated in the treatment water tank 12. [

The collecting hood 21 is installed so as to float on the water surface of the wastewater while covering a part of the water surface of the wastewater in the treatment water tank 12. The gas collected in the collecting hood 21 flows along the gas collecting pipe 30, Is introduced into the analyzer (34) through the branch pipe (31) connected to the pipe (30). A gas suction pump 32 for sucking the gas collected in the collecting hood 21 to the gas collecting pipe 30 is connected to the gas collecting pipe 30 and a gas collecting pipe 30 is connected to the branch pipe 31 And an analyzing gas suction pump 33 for sucking the gas flowing along the analyzer 34 side is connected.

When analyzing the gas generated in the treatment tank 12, the gas suction pump 32 and the analytical gas suction pump 33 operate together. Therefore, most of the gas collected in the collecting hood 21 and flowing along the gas collecting pipe 30 passes through the gas suction pump 32 and is discharged into the outside air. A part of the gas flows through the analyzer 34 through the branch pipe 31, . The collecting hood 21 can be moved up and down in accordance with the level of the waste water in the treating water tank 12 so that the gas collecting pipe 30 is made of a flexible material that can be deformed by the movement of the collecting hood 21, It can be in the form of a corrugated tube.

An air suction pipe (36) is connected to one side upstream of the connecting portion of the branch pipe (31) of the gas collecting pipe (30). The air suction pipe 36 is for introducing the outside air into the gas collection pipe 30, and an air suction pipe open / close valve 37 is connected in the middle thereof. Although various kinds of valves capable of opening and closing the internal flow path of the air suction pipe 36 may be used, the air suction pipe opening / closing valve 37 may be a solenoid valve controlled by the controller 35. [ Air supplied to the gas collection pipe 30 through the air suction pipe 36 is used for cleaning the analyzer 34 and the like.

A gas collection pipe opening / closing valve 38 is provided upstream of the connection portion of the air suction pipe 36 of the gas collection pipe 30. The gas collection pipe opening / closing valve 38 may be various kinds of valves capable of opening and closing the internal flow path of the gas collection pipe 30. Preferably, a solenoid valve controlled by the controller 35 may be used as the gas collection pipe opening / closing valve 38. [

The flow rate of the gas sucked into the gas collecting pipe 30 such as the suction gas flow meter 39, the suction gas pressure gauge 40 and the suction gas thermometer 41 is provided upstream of the connecting portion of the branch pipe 31 of the gas collecting pipe 30 Various kinds of suction gas detectors for detecting various physical properties of gas such as pressure, temperature, etc. are installed. These suction gas flow meter 39, suction gas pressure gauge 40 and suction gas temperature gauge 41 respectively detect the physical properties of the gas and provide the detection signal to the controller 35. The type of the intake gas detector can be variously changed.

The flow rate, pressure, and temperature of the gas flowing toward the analyzer 34 such as the analyzer gas flow meter 42, the analytical gas manometer 43, the analytical gas thermometer 44, etc., upstream of the analyzer 34 of the branch pipe 31, Various kinds of analytical gas detectors for detecting various physical properties of the sample are installed. The analyzing gas flow meter 42, the analyzing gas manometer 43 and the analyzing gas thermometer 44 respectively detect the physical properties of the gas and provide the detecting signal to the controller 35. The type of analyzer gas detector can be variously changed.

The analyzer 34 connected to the branch pipe 31 measures the oxygen and the carbon dioxide contained in the reference air and the gas discharged from the treatment water tank 12 and calculates the dissolved oxygen change rate of the dissolved oxygen in the wastewater, (12). The analyzer 34 can also measure the oxygen transfer efficiency of the air diffuser 14 by measuring the oxygen fraction of the gas discharged from the treatment tank 12 and calculate the oxygen mole fraction of the supply and discharge air, ), The degree of saturation of dissolved oxygen can be estimated.

The analyzer 34 may include various detection sensors such as an oxygen sensor for detecting oxygen and a carbon dioxide sensor for detecting carbon dioxide. The analyzer 34 also includes an air flow meter 17, an air pressure gauge 18, an air thermometer 19, an inlet gas flow meter 39, an inlet gas pressure gauge 40, an inlet gas thermometer 41, ), The analysis gas pressure gauge 43, the analysis gas thermometer 44, and the like.

1 and 3, the collecting hood 21 includes a hood body 22 having an inlet 23 through which the gas generated from the wastewater flows, the hood body 22 being provided on a bottom surface thereof, And a float (25) coupled to an outer surface of the hood body (22). A hood body 22 is provided at its upper surface with a hood 24 for introducing the gas collected in the hood body 22 into the gas collecting pipe 30. A gas collecting pipe 30 is connected to the hood 24, . The float 25 may be made of various materials that can float above the water surface and may be formed on the outer surface of the float 25 to guide the gas generated from the wastewater to the float 25 to the outside of the hood body 22 A guide surface 26 is provided. The guide surface 26 has a curved surface inclined upward from the lower end of the hood body 22 so that the gas striking the float 25 floating in the wastewater can not flow into the hood body 22, And flows outwardly of the hood body 22 along the inner surface 26 of the hood body 22.

The wastewater treatment performance test apparatus 20 collects and analyzes a sample of gas floating in a part of the water surface of the wastewater stored in the treatment water tank 12 and analyzes the characteristics of the gas floating in the treatment water tank 12 and the characteristics of the water in the treatment water tank 12, To evaluate the aerobic treatment performance. Therefore, the gas collected in the collecting hood 21 should float only on the surface of the wastewater covered by the collecting hood 21. That is, only the gas floating on the water surface of the area corresponding to the inflow port 23 set to a certain size must be collected by the collection hood 21, so that the characteristics of the gas floating on the entire water surface can be grasped accurately from this. The guide surface 26 is provided on the outer surface of the float 25 to guide the gas striking the float 25 to the outside of the trapping hood 21 so that the gas hits the float 25, 21).

On the other hand, a cap 50 for shielding the connecting port 24 of the collecting hood 21 is disposed inside the collecting hood 21. The cap 50 is made of a material that can float above the water surface and floats on the water surface of the wastewater in the collection hood 21. When the pressure in the gas collection pipe 30 becomes excessively low, So as to shield the connecting port 24 of the collecting hood 21. When the pressure inside the gas collecting pipe 30 is excessively lowered, not only the gas collected in the collecting hood 21 but also the wastewater in the collecting hood 21 can be sucked into the gas collecting pipe 30. If the wastewater is sucked into the gas collection pipe 30 and the wastewater flows into the gas suction pump 32, the analysis gas suction pump 33 and the analyzer 34, a failure may occur in these devices. This problem can be prevented by blocking the connecting hole 24 of the hood 21.

As shown, the plug 50 preferably has a shape gradually increasing in width from the top to the bottom so that the plug 24 can be stably closed, but its shape is not limited. A sealing member 51 is provided on the outer surface of the stopper 50. The sealing member 51 prevents the gap between the collecting hood 21 and the cap 50 from clogging when the cap 50 rises and shields the connecting port 24 of the collecting hood 21, Thereby preventing moisture from flowing into the connector 24.

A guide bar 52 is provided at the upper end of the stopper 50 so as to extend into the gas collection pipe 30 to guide upward and downward movement of the stopper 50. The guide bar 52 is slidably coupled to a support member 55 installed in the gas collection tube 30. [ A guide groove 56 into which the guide bar 52 is inserted is provided at the center of the support member 55 and a through hole 57 for the flow of gas is formed around the guide groove 56 of the support member 55 do. The guide bar 52 is supported on the support member 55 so that the stopper 50 floats on the water surface immediately below the connection hole 24 and rises when the pressure inside the gas collection pipe 30 becomes excessively low, Thereby sealing the connecting hole 24 with the screw. A release preventing member 53 having a size larger than that of the guide groove 56 is provided at an end of the guide bar 52 to prevent the guide bar 52 from deviating from the support member 55.

The operation of the wastewater treatment performance testing apparatus 20 and the aerobic wastewater treatment apparatus 10 according to an embodiment of the present invention will be described below with reference to the accompanying drawings.

When the wastewater flows into the treatment water tank 12 through the wastewater inflow pipe 13, the blower 16 operates to supply air into the wastewater through the air diffuser 14. At this time, the air flow meter 17, the air pressure gauge 18, and the air thermometer 19 connected to the air supply pipe 15 transmit information on the flow rate, pressure and temperature of air supplied to the air diffuser 14 to the analyzer 34, . When the air is supplied into the wastewater, the aerobic microorganisms in the wastewater function to purify pollutants in the wastewater by aerobic treatment. While the aerobic treatment is performed on the wastewater in the treatment tank 12, the gas coming from the wastewater is collected in the collection hood 21.

The controller 35 closes the air intake pipe open / close valve 37 and opens the gas collection pipe open / close valve 38 while the wastewater is being aerated in the treatment water tank 12, The suction pump 33 is operated to suck the gas collected in the collecting hood 21 through the gas collecting pipe 30. The gas drawn through the gas collecting pipe 30 moves mostly toward the gas suction pump 32 along the gas collecting pipe 30 and is discharged to the outside. Part of the gas moving along the gas collecting pipe 30 And flows into the analyzer 34 along the branch pipe 31. The suction gas flow meter 39, the suction gas pressure gauge 40 and the suction gas temperature gauge 41 provided on the gas collecting pipe 30 are connected to the gas collecting pipe 30 and the branch pipe 31, Pressure and temperature of the gas sucked into the collecting pipe 30 to the analyzer 34 and supplies the analyzing gas flow meter 42, the analyzing gas manometer 43 and the analysis gas The thermometer 44 provides information to the analyzer 34 about the flow rate, pressure and temperature of the gas flowing into the analyzer 34 along the branch pipe 31.

The analyzer 34 can obtain the information necessary for the analysis with only a small amount of gas. The analyzer 34 measures oxygen, carbon dioxide, and the like contained in the gas flowing into the branch pipe 31, calculates various physical properties of the supplied air supplied from the above-described various detectors, various properties of the collected gas The rate of change in dissolved oxygen of oxygen dissolved in the wastewater, and the like to analyze the wastewater treatment performance of the treatment water tank 12 in real time. The gas collecting area of the collecting hood 21, the flow rate of the gas sucked into the gas collecting pipe 30, the pressure, the temperature, the flow rate of the gas flowing into the analyzer 34, The analyzer 34 can analyze the gas flowing into the branch pipe 31 to calculate the characteristics of the gas generated in the entire treatment water tank 12. [

The analysis result of the analyzer 34 is provided to the controller 35 and the controller 35 controls the operation of the blower 16 so that the wastewater treatment can be smoothly and efficiently performed in the treatment water tank 12, 12). In addition, when the treating water tank 12 is provided with a device for treating wastewater in addition to the medicine feeding device and the stirrer or the like, the anaerobic tank 14 is provided with the analysis result of the analyzer 34, The operation can be controlled in real time.

The optimum output of the blower 16 employed in the treatment water tank 12 and the optimum number of the devices 14 to be installed are set from the wastewater treatment performance of the treatment water tank 12 analyzed by the analyzer 34 . This data can then be used to design an optimized aerobic wastewater treatment plant.

When the gas collected in the collecting hood 21 is mostly discharged through the gas collecting pipe 30 during the analysis of the wastewater treatment performance in the treating water tank 12, the pressure inside the gas collecting pipe 30 is lowered. The waste water in the collection hood 21 may be introduced into the gas collection pipe 30 through the inlet 23 of the collection hood 21 if the pressure inside the gas collection pipe 30 is excessively low. The plug 50 is raised by the suction force of the gas collection tube 30 to block the inlet 23 so that the problem of the wastewater flowing into the gas collection tube 30 does not occur. When the stopper 50 blocks the inlet 23 and the pressure inside the gas collection pipe 30 drops further, the controller 35 detects the inside of the gas collection pipe 30 from the suction gas flow meter 39 and the suction gas pressure gauge 40 The gas suction pump 32 or the analytical gas suction pump 33 is stopped or the air suction pipe open / close valve 37 is opened to allow outside air to flow into the gas collection pipe 30, Thereby preventing the components such as the suction pump 32 and the analysis gas suction pump 33 from being overloaded or damaging the components.

On the other hand, when the analyzer 34 is cleaned, when the analysis gas suction pump 32 is operated while the gas collection pipe open / close valve 38 is closed and the air suction pipe open / close valve 37 is opened, The outside air is introduced into the gas collection pipe 30 through the gas discharge pipe 30. The air introduced into the gas collecting pipe 30 is supplied to the analyzer 34 along the branch pipe 31 so that the gas remaining in the gas collecting pipe 30, the branch pipe 31, the analyzer 34, And can be discharged to the outside and removed.

4 is a side view showing a wastewater treatment performance testing apparatus 60 according to another embodiment of the present invention. FIG. 5 is a side view showing a wastewater treatment performance testing apparatus 60 according to another embodiment of the present invention. Fig.

4 and 5, the wastewater treatment performance testing apparatus 60 according to another embodiment of the present invention is configured such that the configuration of the collection hood 61 is somewhat larger than that of the wastewater treatment performance testing apparatus 20 described above The specific structure of the remaining components is the same as that of the wastewater treatment performance testing apparatus 20 described above.

The collecting hood 61 includes a hood body 22 having an inlet port 23 through which gas generated from the wastewater flows and a hood body 22 connected to the hood body 22 for imparting buoyancy to the hood body 22 A float 62 and a connecting mechanism 63 for connecting the hood body 22 and float 62. The hood body 22 is similar to that described above. The hood body 22 is provided at its upper portion with a connecting hole 24, and the gas collecting pipe 30 is connected thereto. When the pressure inside the gas collecting tube 30 is excessively lowered, the hood body 22 is lifted by the suction force of the gas collecting tube 30 to stop the closure cap 50 of the hood body 22 Is installed.

The float 62 may be made of a variety of materials that can float above the water surface, and the connection mechanism 63 is provided with a plurality of through holes 64 for discharging the gas generated in the wastewater to the outside air. The gas that hits the float 62 and hits the hood body 22 and the gas that hits the connection mechanism 63 is discharged into the outside air through the through hole 64 of the connection mechanism 63 and flows into the hood body 22 As shown in Fig. The structure of the connection mechanism 63 is not limited to that shown in the drawings and can be variously changed.

In the present invention, the gas suction pump 32 connected to the gas collecting pipe 30 for sucking the gas collected in the collecting hoods 21 and 61 to the gas collecting pipe 30 may be omitted. In this case, the gas collected in the collecting hoods 21 and 61 can flow to the outside through the open end of the gas collecting tube 30, The gas collected in the gas-liquid separator 61 can be sucked into the analyzer 34 through the gas collection pipe 30 and the branch pipe 31. [

When the gas suction pump 32 is omitted and the end of the gas collection pipe 30 is open to the outside, the air suction pipe 36 and the air suction pipe opening / closing valve 37 for introducing the outside air into the gas collection pipe 30 ) May be omitted. When the analysis gas suction pump 33 is operated with the gas collection pipe open / close valve 38 closed, when the air suction pipe 36 and the air suction pipe open / close valve 37 are omitted, The analyzer 34 can be cleaned by flowing into the gas collecting pipe 30 and the branch pipe 31 through the open end.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art can improve and modify the technical idea of the present invention in various forms. Accordingly, these modifications and variations are intended to fall within the scope of the present invention as long as it is obvious to those skilled in the art.

10: aerobic wastewater treatment device 12: water treatment tank
14: Diffuser 15: Air supply line
16: blower 17: air flow meter
18: air pressure gauge 19: air thermometer
20, 60: wastewater treatment performance test apparatus 21, 61: collecting hood
22: hood body 23: inlet
24: connector 25, 62: float
30: gas collection pipe 31: branch pipe
32: Gas suction pump 33: Analysis gas suction pump
34: Analyzer 35: Controller
36: air suction pipe 37: air suction pipe opening / closing valve
38: Gas collection pipe opening / closing valve 39: Suction gas flow meter
40: suction gas pressure gauge 41: suction gas thermometer
42: Analytical gas flow meter 43: Analytical gas manometer
44: Analysis gas thermometer 50: Plug
51: sealing member 52: guide bar
55: support member 63: connecting member

Claims (9)

A collecting hood installed to cover a part of the water surface of the wastewater stored in the treatment water tank in a treatment water tank provided with an air diffuser for air supply and having an inlet through which gas generated from the wastewater flows into the bottom surface by aerobic treatment;
A gas collecting pipe connected to a connecting port provided in the collecting hood for guiding the gas introduced into the collecting hood;
A branch pipe connected to the middle of the gas collection pipe;
An analyzer connected to the branch for analyzing gas flowing through the branch;
An analytical gas suction pump connected to the branch pipe for sucking gas into the branch pipe;
A controller for controlling the analyzer and the analysis gas suction pump; And
Wherein the gas hose is arranged to float in the collection hood above the water surface of the wastewater and is raised by the suction force of the gas collection pipe when the pressure inside the gas collection pipe is excessively lowered to shield the connection port of the collection hood, And a plug for preventing the gas from flowing into the gas collection pipe,
Wherein the collecting hood includes a hood body having the inlet and the connecting port formed therein and a float coupled to an outer surface of the hood body to impart buoyancy to the hood body, A guide surface for guiding the gas impinging on the float to the outside of the hood body is provided,
Wherein the gas collecting tube is made of a flexible material that can be deformed in accordance with the movement of the collecting hood, or at least part of the gas collecting tube is in the form of a corrugated tube.
A collecting hood installed to cover a part of the water surface of the wastewater stored in the treatment water tank in a treatment water tank provided with an air diffuser for air supply and having an inlet through which gas generated from the wastewater flows into the bottom surface by aerobic treatment;
A gas collecting pipe connected to a connecting port provided in the collecting hood for guiding the gas introduced into the collecting hood;
A branch pipe connected to the middle of the gas collection pipe;
An analyzer connected to the branch for analyzing gas flowing through the branch;
An analytical gas suction pump connected to the branch pipe for sucking gas into the branch pipe;
A controller for controlling the analyzer and the analysis gas suction pump; And
Wherein the gas hose is arranged to float in the collection hood above the water surface of the wastewater and is raised by the suction force of the gas collection pipe when the pressure inside the gas collection pipe is excessively lowered to shield the connection port of the collection hood, And a plug for preventing the gas from flowing into the gas collection pipe,
Wherein the collecting hood comprises a hood body having the inlet and the connecting port formed therein, a float for imparting buoyancy to the hood body, and a connecting mechanism for connecting the hood body and the float, And has a through hole for discharging gas,
Wherein the gas collecting tube is made of a flexible material that can be deformed in accordance with the movement of the collecting hood, or at least part of the gas collecting tube is in the form of a corrugated tube.
3. The method according to claim 1 or 2,
A guide bar coupled to the plug to extend into the gas collection tube; And
Further comprising: a support member installed in the gas collection tube for guiding the guide bar to move up and down, and having a guide groove into which the guide bar is slidably inserted.
3. The method according to claim 1 or 2,
Further comprising a sealing member provided on an outer surface of the cap to block a gap between the collection hood and the cap when the cap shields the connection port of the collection hood.

3. The method according to claim 1 or 2,
A gas collection pipe opening / closing valve provided in the gas collection pipe for opening and closing a flow passage inside the gas collection pipe;
An air suction pipe connected downstream of the gas collection pipe opening / closing valve of the gas collection pipe to introduce outside air into the gas collection pipe; And
Further comprising: an air suction pipe opening / closing valve installed on the air suction pipe to open / close a flow path inside the air suction pipe.
3. The method according to claim 1 or 2,
An air flow meter connected to the air diffuser and connected to an air supply pipe for supplying air to the air diffuser to detect a flow rate of air supplied to the air diffuser and provide a detection signal to the analyzer, An air pressure gauge for detecting the pressure of air and providing the detection signal to the analyzer;
An analyzer gas flow meter connected to the branch pipe so as to be disposed upstream of the analyzer and detecting a flow rate of gas supplied to the analyzer and providing the detection signal to the analyzer, An analysis gas pressure gauge for providing a detection signal to the analyzer; And
An inlet gas flow meter connected to the gas collection pipe so as to be disposed upstream of a connection between the gas collection pipe and the branch pipe and detecting a flow rate of gas flowing along the gas collection pipe and providing the detection signal to the analyzer; And an intake gas pressure gauge for detecting the pressure of the gas flowing along the gas collection pipe and providing the detection signal to the analyzer.
3. The method according to claim 1 or 2,
Further comprising a gas suction pump connected to the gas collection tube for sucking gas into the gas collection tube.
A processing bath having a storage space for storing waste water;
A diffuser disposed in the treatment bath for supplying air to wastewater stored in the treatment bath;
A blower connected to the air diffuser to supply air to the air diffuser;
A collecting hood installed to cover a part of the water surface of the wastewater stored in the treatment water tank and having an inlet through which a gas generated from the wastewater flows by aerobic treatment,
A gas collecting pipe connected to a connecting port provided in the collecting hood for guiding the gas introduced into the collecting hood;
A branch pipe connected to the middle of the gas collection pipe;
An analyzer connected to the branch for analyzing gas flowing through the branch;
An analysis gas suction pump connected to the branch pipe for sucking gas into the branch pipe;
A controller for controlling the blower, the analyzer and the analysis gas suction pump; And
Wherein the gas collecting tube is disposed so as to float above the water surface of the wastewater in the collecting hood and is raised by a suction force of the gas collecting tube when the suction force through the gas collecting tube rises excessively to shield the connecting port of the collecting hood, And a plug for preventing wastewater from flowing into the gas collection pipe,
Wherein the collecting hood includes a hood body having the inlet and the connecting port formed therein and a float coupled to an outer surface of the hood body to impart buoyancy to the hood body, A guide surface for guiding the gas impinging on the float to the outside of the hood body is provided,
Characterized in that the gas collection pipe is made of a flexible material that can be deformed in accordance with the movement of the collection hood or at least part of the gas collection pipe is in the form of a corrugated pipe.
A processing bath having a storage space for storing waste water;
A diffuser disposed in the treatment bath for supplying air to wastewater stored in the treatment bath;
A blower connected to the air diffuser to supply air to the air diffuser;
A collecting hood installed to cover a part of the water surface of the wastewater stored in the treatment water tank and having an inlet through which a gas generated from the wastewater flows by aerobic treatment,
A gas collecting pipe connected to a connecting port provided in the collecting hood for guiding the gas introduced into the collecting hood;
A branch pipe connected to the middle of the gas collection pipe;
An analyzer connected to the branch for analyzing gas flowing through the branch;
An analytical gas suction pump connected to the branch pipe for sucking gas into the branch pipe;
A controller for controlling the blower, the analyzer and the analysis gas suction pump; And
Wherein the gas collecting tube is disposed so as to float above the water surface of the wastewater in the collecting hood and is raised by a suction force of the gas collecting tube when the suction force through the gas collecting tube rises excessively to shield the connecting port of the collecting hood, And a plug for preventing wastewater from flowing into the gas collection pipe,
Wherein the collecting hood comprises a hood body having the inlet and the connecting port formed therein, a float for imparting buoyancy to the hood body, and a connecting mechanism for connecting the hood body and the float, And has a through hole for discharging gas,
Wherein the gas collection pipe is made of a flexible material that can be deformed according to the movement of the collection hood, or at least part of the gas collection pipe is in the form of a corrugated pipe.

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