CN211999325U - Water purification apparatus and water treatment system using the same - Google Patents

Abstract

A water purifying apparatus and a water treatment system using the same, wherein the water purifying apparatus includes: a first aeration system (2) and a water purification system (3), wherein the first aeration system (2) comprises a first water intake mechanism (21) for injecting water to be purified; a first jet mechanism (23) communicated with a water outlet channel of the first water taking mechanism (21); and a first air intake mechanism (22) in communication with the first fluidic mechanism (23); wherein the first air inlet mechanism (22) is arranged at the inlet front end of the first jet mechanism (23), the water purifying system (3) mixes the water purifying agent with the water body, and distributes the mixed water purifying agent liquid to the inlet front end of the first jet mechanism (23) so as to discharge the water purifying agent liquid through the first jet mechanism (23). The water purification equipment can integrate multiple water treatment functions such as aeration, water purification, microorganism addition and the like, has simple and compact structure, high automation degree and low energy consumption.

Description

Water purification apparatus and water treatment system using the same

Technical Field

The present disclosure relates to an apparatus for purifying water, and more particularly, to a water purifying apparatus for treating the quality of a water body and a water treatment system using the same.

Background

The water treatment objects mainly comprise natural water bodies and artificial water bodies. Such as river and lake water bodies, garden landscape water bodies, culture water bodies, fountains, swimming pools, water parks and the like. Most of the water bodies have the characteristics of low pollutant concentration, diversified pollution sources, great water quantity and turbidity in rainy days. The urban built-up area has higher requirements on water quality and sanitary conditions, and can continuously generate artificial or non-artificial pollution in the operation process.

For example, river black and odorous is a representative bad fruit and important problem to be solved for urban environmental pollution and ecological destruction in China, and the exceeding of organic indexes such as ammonia nitrogen, total phosphorus and the like is a prominent problem to be solved urgently in many urban black and odorous river channels at present. The main pollution sources of the river water body are the injection of external pollutants and substances released by river bottom sludge accumulated for a long time. In addition, the water body is lack of necessary circulation, the dissolved oxygen is too low, and the living environment of aquatic animals and plants is lacked, so that the water body gradually loses the self-cleaning capability and is easy to blacken and smell. In addition, the injection amount of external pollutants is random, and particularly for areas with more rainwater, rainwater can concentrate to bring more external pollutants, so that the water quality of the river water body is rapidly deteriorated.

As for the current technology for remedying the polluted water body of the river channel, the biological-ecological technology is a more scientific way for remedying the polluted water body. According to the ecological principle, the self-purification capability of aquatic ecological animals and plants and microorganisms is utilized to absorb organic pollutants in the water body, so that the aim of purifying the water quality can be fulfilled.

The current bio-ecological technology is generally built in the form of artificial wetlands, biological oxidation ponds, biological filter beds and the like. This method requires a large amount of infrastructure construction, which leads to an increase in cost and maintenance, and this water treatment scheme limits the amount and place of treatment and cannot flexibly cope with rapid deterioration of water quality. Furthermore, the existing water treatment devices placed in watercourses and other water bodies cannot be adjusted in real time or adaptively according to the change of the water bodies.

SUMMERY OF THE UTILITY MODEL

In order to solve at least one of the above technical problems, according to an aspect of the present disclosure, there is provided a water purifying apparatus, characterized by comprising: first aeration systems and water purification system, wherein, first aeration systems includes: a first water taking mechanism for injecting water to be purified; the first jet mechanism is communicated with the water outlet channel of the first water taking mechanism; and a first air intake mechanism in communication with the first fluidic mechanism; the first air inlet mechanism is arranged at the front inlet end of the first jet flow mechanism, the water purifying system mixes the water purifying agent with the water body and distributes the mixed water purifying agent liquid to the front inlet end of the first jet flow mechanism so as to discharge the water purifying agent liquid through the first jet flow mechanism.

According to the water purification apparatus of the embodiment of the present disclosure, optionally, the first air intake mechanism of the first aeration system comprises a first main air intake pipe and a first branch air intake pipe, one end of the first main air intake pipe is connected to a first valve, and the other end of the first main air intake pipe is connected to the first branch air intake pipe of the first air intake mechanism located at the front end of the inlet of the first jet mechanism (23).

The water purification apparatus according to the embodiment of the present disclosure, optionally, further comprises a controller controlling the first valve, wherein in the aeration mode, the controller controls the first valve to be opened, and in the purification mode, the controller controls the first valve to be closed.

The water purifying device according to the embodiment of the present disclosure optionally further comprises a second aeration system and a microorganism system, wherein the second aeration system comprises a second water taking mechanism for injecting water to be purified, a second jet mechanism communicated with a water outlet channel of the second water taking mechanism, and a second air inlet mechanism communicated with the second jet mechanism, and the second air inlet mechanism is arranged at the front end of an inlet of the second jet mechanism; the microbiological system includes a distributor connected to the inlet front end of the second fluidic mechanism.

According to the water purification apparatus of the embodiment of the present disclosure, optionally, the second air intake mechanism of the second aeration system includes a second air intake main pipe and a second air intake branch pipe, one end of the second air intake main pipe is connected to the second valve, the other end of the second air intake main pipe is connected to the second air intake branch pipe, and the distributor of the microbial system is connected to the second air intake branch pipe of the second air intake mechanism.

The water purification apparatus according to the embodiment of the present disclosure, optionally, further comprises a controller controlling the second valve, wherein in the aeration mode, the controller controls the second valve to be opened, and in the microorganism adding mode, the controller controls the second valve to be closed. A controller may be used to control the first valve and the second valve.

According to the water purifying apparatus of the embodiment of the present disclosure, optionally, the first automatic water taking mechanism includes an inlet channel, a water storage cavity, a pump and an outlet channel along a water flow direction, wherein the outlet channel is set to be higher than the water storage cavity.

According to the water purifying apparatus of the embodiment of the present disclosure, optionally, the first jet mechanism includes a water outlet pipe, and a spiral member is disposed inside the water outlet pipe.

According to the water purifying device of the embodiment of the disclosure, optionally, the water purifying system comprises a water purifying agent channel for throwing the water purifying agent, a water preparing channel for adding the water body, a water purifying agent bucket for mixing the water purifying agent and the water body into water purifying agent liquid, and a throwing channel for throwing the water purifying agent liquid.

According to the water purifying apparatus of the embodiment of the present disclosure, optionally, the water purifying agent passage includes a water purifying agent tank in which the water purifying agent is placed and a regulating valve that controls an application amount of the water purifying agent, and the modulating water passage includes a water pump that can control a water inflow amount.

According to the water purification apparatus of the embodiment of the present disclosure, optionally, the feeding channel includes a metering pump and a distributor, wherein the metering pump quantitatively feeds the water purifying agent liquid according to the water quality requirement, and the distributor uniformly distributes the water purifying agent liquid.

According to the water purification apparatus of the embodiment of the present disclosure, optionally, the second jet mechanism includes a water outlet pipe, a plurality of feeding holes are formed in the water outlet pipe, and a filler is disposed on the feeding holes.

According to the water purifying apparatus of the embodiment of the present disclosure, optionally, the microorganism system includes a microorganism bucket filled with microorganisms, a solenoid valve, and a distributor, wherein the distributor is connected with the second air inlet branch pipe of the second air inlet mechanism through a pipeline.

According to this water purification unit of this disclosed embodiment, optionally, still include the water quality analysis sensor that detects water quality.

According to another aspect of the present disclosure, there is provided a water treatment system comprising the aforementioned water purification apparatus and a body carrying the water purification apparatus such that the system can float on the surface of water.

According to the water purification equipment disclosed by the embodiment of the disclosure, water treatment functions such as aeration, water purification and microorganism adding can be integrated, and the structure is simple and compact. The device also utilizes the negative pressure self-absorption principle to discharge the water purifying agent liquid and put in microorganisms, thereby saving energy. In addition, the equipment can automatically set corresponding parameters according to the water quality condition of the water body and execute related functions, so that the automation degree of water treatment is improved.

Drawings

To more clearly illustrate the technical solutions of the embodiments of the present disclosure, the drawings of the embodiments will be briefly introduced below, and it is apparent that the drawings in the following description relate only to some embodiments of the present disclosure and are not limiting to the present disclosure.

Fig. 1 shows a schematic view from above of a water purification apparatus according to an embodiment of the present disclosure;

FIG. 2 illustrates a schematic cross-sectional view of an aeration system of a water purification apparatus according to one embodiment of the present disclosure;

fig. 3 shows a schematic cross-sectional view of a water purification system of a water purification apparatus according to an embodiment of the present disclosure;

fig. 4 shows a schematic diagram of a control flow of a water purification apparatus according to an embodiment of the present disclosure.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be described clearly and completely with reference to the drawings of the embodiments of the present disclosure. It is to be understood that the described embodiments are only a few embodiments of the present disclosure, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the disclosure without any inventive step, are within the scope of protection of the disclosure.

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this disclosure belongs. The use of "first," "second," and similar terms in the description and claims of the present disclosure are not intended to indicate any order, quantity, or importance, but rather are used to distinguish one element from another. Also, the use of the terms "a" or "an" and the like do not necessarily denote a limitation of quantity. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

Fig. 1 is a schematic view of a top view of a water purifying apparatus according to one embodiment of the present disclosure. As shown in fig. 1, the water purification apparatus may include a first aeration system 2, a second aeration system 5, a water purification system 3, and a microorganism system 4. The water purification apparatus may further include a control system (not shown) for controlling the operation of the first aeration system 2, the second aeration system 5, the water purification system 3, the microorganism system 4, and the like. The control system may be implemented using a single or multiple controllers.

The water purification apparatus may be carried by a body 1 (e.g. a ship hull) so that the apparatus floats on the water surface, forming a mobile water treatment system. The mobile water treatment system can also be provided with a steering system for controlling the running direction of the mobile water treatment system, and the steering system can be designed to be operated on site or remotely, so that a worker can conveniently control the mobile water treatment system to realize directional movement on the water surface.

Although the first aeration system 2 and the second aeration system 5 are shown in fig. 1, the present embodiment is not limited to two sets of aeration systems. The number of aeration systems may be determined as desired. The aeration system can aerate and oxygenate the water body and provide power for the equipment to move forwards. Each aeration system can work independently under the control of the control system.

Fig. 2 shows a schematic cross-sectional view of an aeration system of a water purification apparatus according to an embodiment of the present disclosure. The structure and operation of the first aeration system 2 will now be described with reference to fig. 1 and 2. The first aeration system 2 may include an automatic water intake mechanism 21, an air intake mechanism 22, and a jet mechanism 23. The water flow end of the automatic water taking mechanism 21 is connected with the fluidic mechanism 23, and the upper end of the fluidic mechanism 23 is connected with the air intake mechanism 22.

The automatic water intake mechanism 21 is provided with a grill 211, an inlet channel 212, a water storage chamber 213, a pump 214 (e.g., a wet and dry pump) and an outlet channel 215 in the water flow direction, wherein the wet and dry pump is connected to the outlet of the water storage chamber, and the outlet channel is connected to the outlet of the wet and dry pump. When the automatic water intake mechanism 21 works, water is injected into the water storage cavity 213 until the water level of the water storage cavity 213 reaches the maximum, and then the water filling port is sealed, so that only the water inlet channel 212 is left as the water inlet. The wet and dry pump 214 is then activated to deliver the water within the water storage chamber 213 to the water outlet channel 215 and then into the jet mechanism 23. At this time, the water level of the water storage cavity 213 is gradually decreased to gradually decrease the air pressure in the cavity to form a negative pressure, and the external water is filtered by the grating 211 and gradually rises from the water inlet 212 to the water storage cavity 213. The water outlet channel 215 is designed to be raised (i.e. higher than the water storage chamber 213), so as to facilitate the water storage of the water storage chamber 213. The structure of the automatic water taking mechanism 21 solves the limitation of the wet and dry pump 214 on the water level requirement, and simultaneously reduces the height and draft of the equipment, so that the environmental requirements (the water level requirement of the water body, the height of a bridge on the water surface and the like) of the equipment on the use site are reduced, and the universality is stronger.

The air intake mechanism 22 includes an air intake main pipe 221 having one end connected to a valve 222 and the other end connected to one or more air intake branch pipes 223. The jet mechanism 23 is connected with the air inlet mechanism 22, wherein a spiral part 232 is arranged in an outlet pipe 231 of the jet mechanism 23, so that water in the spiral part is in a spiral circulation mode, and the mixing is more uniform.

During operation in the aeration mode, the valve 222 is opened, and the water body after water is taken by the automatic water taking mechanism 21 passes through the jet mechanism 23. The jet mechanism 23 may create a negative pressure such that air enters through the valve 222 of the air intake mechanism 22 and mixes with the water body in the outlet pipe 231, thereby aerating and oxygenating the water body.

The second aeration system 5 is similar in structure to the first aeration system and may include an automatic water intake mechanism 51, an air intake mechanism 52, and a jet mechanism 53. The water flow end of the automatic water intake mechanism 51 is connected to the jet mechanism 53, and the upper end of the jet mechanism 53 is connected to the air intake mechanism 52. Since the structure of the automatic water intake mechanism of the second aeration system 5 is the same as that of the first aeration system 2, it is not shown repeatedly in fig. 2. The structure and operation of the automatic water intake mechanism of the second aeration system 5 can be referred to the description of the automatic water intake mechanism 21 of the first aeration system 2 above. Fig. 2 schematically shows the air intake mechanism 52 and the jet mechanism 53 of the second aeration system 5.

The intake mechanism 52 includes an intake main 524. The main intake pipe 524 is connected at one end to a valve 525 and at the other end to one or more branch intake pipes 526. The jet mechanism 53 is connected with the air inlet mechanism 52, wherein a plurality of feeding holes 534 are arranged on a water outlet pipe 533 of the jet mechanism 53, and the feeding holes 534 are provided with fillers 535.

In the operation process of the aeration mode, the valve 525 is opened, the water body after the automatic water taking mechanism takes water passes through the jet mechanism 53, the jet mechanism 53 forms negative pressure, so that air enters through the valve 525 of the air inlet mechanism 52, and the air and the water body are mixed in the water outlet pipe 533, thereby aerating and oxygenating the water body.

Valve 222 and valve 525 may be controlled by the control system and opened upon activation of the aeration system. The number of aeration systems can be increased as desired. The first aeration system and the second aeration system can also be used independently, namely, the water purifying device can only comprise the first aeration system or the second aeration system according to the requirement. The control of the first aeration system and the second aeration system will be described in detail below with reference to fig. 4. Valves 222 and 525 may be automatic valves that can be controlled by a control system.

Fig. 3 shows a schematic cross-sectional view of a water purification system of a water purification apparatus according to an embodiment of the present disclosure. The structure and operation of the water purification system will be described with reference to fig. 1-3.

The water purification system 3 may include a water purifying agent passage 31, a brewing water passage 32, a dosing passage 33, and a water purifying agent bucket 34. The water purifying agent passage 31 is a water purifying agent dosing passage, and may include a water purifying agent tank 311 and an adjusting valve 312. The amount of the purifying agent in the purifying agent tank 311 entering the purifying agent tank 34 is controlled by the regulating valve 312. The modulated water passage 32 is a passage for quantitatively adding the water body mixed with the water purifying agent. A water pump 321 in the brew water channel 32 controls the amount of water entering the water purifying agent tank 34. The water purifying agent and the water body are uniformly mixed under the action of a stirrer 35 in the water purifying agent barrel 34. The adding channel 33 quantitatively and uniformly adds the mixed water purifying agent liquid, and may include a metering pump 331, a distributor 332 and a pipeline 333. The adding amount of the mixed water purifying agent liquid can be controlled by a metering pump 331 according to the water quality requirement, the added water purifying agent liquid is uniformly distributed to the air inlet branch pipe 223 of the air inlet mechanism 22 through a distributor 332 and then enters the water outlet pipe 231, so that the water purifying agent liquid and the water body in the water inlet mechanism are uniformly mixed in a swirling flow mode under the action of the spiral part 232 and then are discharged in a jetting manner, and a better water purifying effect is obtained. The jet flow discharge mode stirs nearby water areas, so that the influence range of the water purifying agent liquid is wider, and the actual treated water quantity is larger and more uniform.

Although the water purification system 3 is shown to be connected to the intake branch pipe 223 of the intake mechanism, the water purification system 3 may be connected to other positions of the inlet front end of the jet mechanism. As long as the water purification system 3 is connected to the inside of the negative pressure region at the front end of the inlet of the jet mechanism, the water purifying agent liquid can be sucked into the water outlet pipe 231 by the negative pressure action of the jet mechanism.

According to the structure, the aeration system 2 and the water purification system 3 are used in a mixed mode, and the water purification agent and the water body are improved in the contact influence range by aeration and stirring of the water body. Further, the water purification system 3 discharges the water purifying agent liquid by sharing the jet mechanism 23 with the first aeration system by connecting to the inlet front end of the jet mechanism, for example, the intake branch pipe 223 of the intake mechanism 22. When the water purification system 3 is in operation (i.e. in the purification mode), the valve 222 is closed. Because the jet mechanism 23 forms negative pressure, the water purifying agent liquid is sucked into the water outlet pipe 231 and is thrown into the water body through the action of the negative pressure. Thereby, energy required for adding the water purifying agent liquid is saved and equipment (such as a water pump) required for adding is reduced.

Referring back to fig. 1, the microbial system 4 may include a microbial tank 41, a solenoid valve 42, a distributor 43, and a pipe 44. Microorganisms are stored in the microorganism barrel 41, and the microorganisms can be in the forms of primary microorganism bacteria liquid or microorganism bacteria liquid prepared and cultured by microbial inoculum and nutrient solution, and the like. The microorganism tank 41 is connected with the air inlet branch pipe 526 of the air inlet mechanism 52 of the second aeration system through the distributor 43 and the pipe 44.

Although the figure shows the microbial system 4 connected to the air inlet branch 526 of the air inlet means, the microbial system 4 may be connected to other positions of the inlet front end of the fluidic means. As long as the microorganism system 4 is connected to the negative pressure region at the front end of the inlet of the jet mechanism, the microorganism liquid can be sucked into the water outlet pipe 533 by using the negative pressure effect of the jet mechanism.

As can be seen from the above structure, the microorganism system 4 feeds the microorganism solution by connecting to the inlet front end of the jet mechanism, for example, the air inlet branch pipe 526 of the air inlet mechanism 52, and sharing the jet mechanism 53 with the second aeration system. When the microbial system 4 is operating (i.e., in the microbial dosing mode), the valve 525 is closed. Because the jet mechanism 53 forms negative pressure, the microbial liquid in the microbial system 4 is sucked into the water outlet pipe 533 and flows out from the feeding hole 534, so that the microbial liquid is attached to the filler 535 to grow and reproduce, and is used for degrading organic matters in the water body.

In the device, the second aeration system 5 and the microorganism system 4 are used together, aeration and stirring of the water body improve the contact of the microorganisms and pollutants, and the provided dissolved oxygen (Do) activates the biological activity of the microorganisms. The filler 535 is arranged to provide a colonizing carrier for the microorganism, so that a more suitable growth environment is created for the proliferation, proliferation and growth and inhabitation of the microorganism, the phenomenon that the added microorganism falls into water to form a zoogloea and is rapidly precipitated to the bottom of the tank due to aeration stirring is avoided, and energy required by adding the microorganism liquid is saved.

Fig. 4 shows a schematic diagram of a control flow of a control system of a water purification apparatus according to an embodiment of the present disclosure.

The control system includes one or more controllers and may be controlled on-site or remotely. The control system may also include a memory for recording various operational parameters of the plant (including, but not limited to, operational parameters of the aeration system, water purification system, microbial system; operational parameters of the valves and water pumps; detected water quality parameters, etc.) and transmitting them to a control center or data center for real-time monitoring or data analysis.

The control system first acquires data relating to the water quality measured by the water quality analysis sensor (step 401). The water quality analyzing sensor 6 may be installed in the water purifying apparatus, may be installed in other apparatuses, or may be a separate detecting apparatus. The water quality analysis sensor can detect Chemical Oxygen Demand (COD), ammonia nitrogen content (NH3-N), dissolved oxygen (Do), water turbidity (H), water temperature, PH parameters and the like of the water body to be treated. The control system can automatically adjust the operation modes of the equipment according to the water quality condition to be treated, and can automatically adjust the operation parameters under each operation mode according to the water quality parameters.

Judgment of H_MeasuringAnd H_{Is provided with}The relationship between (step 410). When the measured water turbidity H_MeasuringLess than a set or desired water turbidity H_{Is provided with}When is H_Measuring＜H_{Is provided with}The time is low, the water transparency is poor, the water is turbid, and the suspended particles are large, such as the water after raining. At this point, the water purification system 3 may be started (step 411) to add the water purifying agent liquid to the water body. During operation of the water purification system 3, the control system may determine the amount of water purifying agent and water purifying agent liquid using the following process:

1. determining water treatment capacity Q of dry and wet pump_{Water (W)}(i.e. determining pumping by wet and dry pumpsThe amount of water). Because of the jet form, the actual water treatment ratio Q is affected_{Water (W)}Large, so that nQ can be used_{Water (W)}The actual water treatment is shown (the value of n is determined by the jet strength).

2. According to nQ_{Water (W)}Determining the adding amount m of the water purifying agent_{Medicine for treating rheumatism}Wherein the adding amount of the water purifying agent is m_{Medicine for treating rheumatism}Will be controlled by the regulating valve 312:

m_{medicine for treating rheumatism}＝nQ_{Water (W)}η₁(η₁For adding the proportionality coefficient, in general, eta₁An empirical value, which is related to the turbidity of the water, the more turbid the water, the larger the dosing factor).

3. According to m_{Medicine for treating rheumatism}Determining the water inflow Q of the water pump 321:

Q＝m_{medicine for treating rheumatism}/η₂(η₂Is the dilution ratio of the water purifying agent, and is generally an empirical value).

4. The total amount of the water purifying agent liquid is Q_{Medicine for treating rheumatism}＝Q+m_{Medicine for treating rheumatism}I.e. the amount of the water purifying agent liquid to be fed is controlled by the metering pump 331.

The work flow of the water purification system 3 can refer to the block 413 of fig. 4. First, the valve 222 is closed to cut off the passage of the intake mechanism 22; the wet and dry pump 214 is started, wherein the water treatment capacity of the wet and dry pump is Q_{Water (W)}(ii) a The regulating valve 312 adds m according to the calculated water purifying agent_{Medicine for treating rheumatism}Putting a water purifying agent; the water pump 321 controls the water inflow Q to enter the water purifying agent barrel 34; the blender 35 is activated to uniformly mix the water purifying agent in the water purifying agent tank with the water. The mixed water purifying agent liquid is quantitatively added into the water body by the metering pump 331 according to the calculation result. Because of the water inflow Q and the adding amount m of the water purifying agent_{Medicine for treating rheumatism}It may be determined that the metering pump 331 may also be omitted.

The above calculation may be performed when the water purification system 3 starts operating, or may be adjusted in real time according to conditions such as the water quality of the water body, the water treatment amount of the wet and dry pump 214, and the water amount of the water area to be treated.

If H is determined_MeasuringGreater than or equal to a set or desired water turbidity H_{Is provided with}When is H_Measuring≥H_{Is provided with}When the transparency of the water body is better or meets the requirement, the first exposure is carried outThe gas system 2 may be activated without operating the water purification system 3. When the first aeration system 2 is started, the valve 222 is opened, so that the gas enters the gas inlet mechanism 22.

In addition, it can also be judged whether the content of organic pollutants in the water exceeds the standard, for example, whether the content of ammonia nitrogen meets the requirement (step 420). When (NH3-N)_Measuring＞(NH3-N)_{Is provided with}At this time (step 421), the organic matter content in the water body is high, and the microbial system 4 is activated. Referring to block 423 of fig. 4, valve 525 is first closed to close the passage of intake mechanism 52; starting a wet and dry pump (not shown) of the second aeration system; the electromagnetic valve 42 is started to enable the microbial liquid to enter the water outlet pipe and then flow out of the adding hole 534.

When (NH3-N)_Measuring≤(NH3-N)_{Is provided with}When the ammonia nitrogen content of the water body is satisfactory, the second aeration system 5 may be activated (step 425) without operating the microbial system 4. When the second aeration system 5 is activated, the valve 525 is opened to allow gas to enter the gas inlet means 52.

Besides the ammonia nitrogen content, COD (chemical oxygen demand) or BOD (biochemical oxygen demand) and the like can be used as parameters for judging whether the content of the organic pollutants exceeds a set value.

In addition, when Do_Measuring＜Do_{Is provided with}When it is indicated that the water body may be anoxic, the function of the aeration system 2 and/or 5 is activated, and accordingly the valve 222 and/or 525 is opened, thereby communicating with the channel of the air intake means 22 and/or 52 for normal aeration.

According to the water purification equipment disclosed by the invention, the water treatment functions such as aeration, water purification and microorganism addition can be integrated, and the structure is simple and compact.

According to the water purification unit of the embodiment of this disclosure, can realize one or several in following technological effect: according to the embodiment of the disclosure, the water purifying equipment can intersect and mix the aeration system and the water purifying system for use, the water purifying agent liquid is discharged through the jet mechanism, the contact influence range of the water purifying agent and the water body is increased, and the water quantity which can be treated by the water purifying agent is larger and more uniform. Because the water purification system is connected with the jet mechanism, the water purifying agent liquid can be discharged by utilizing the negative pressure self-absorption function of the jet mechanism, the energy required by adding the water purifying agent liquid is saved, and equipment required by adding is reduced. In addition, according to the embodiment of the disclosure, the device can also be used by combining and mixing the aeration system and the microorganism system, the contact of the microorganisms and pollutants is increased by stirring the water body by using aeration, and the biological activity of activating the microorganisms by dissolved oxygen is provided. The device also utilizes the negative pressure self-absorption principle to put in the microorganisms, thereby saving energy. The equipment integrates various water treatment functions, can automatically set corresponding parameters according to the water quality condition of the water body and execute related functions, and improves the automation degree of water treatment.

The above description is intended to be exemplary of the present disclosure, and not to limit the scope of the present disclosure, which is defined by the claims appended hereto.

Claims (15)

1. A water purifying device is characterized in that,

the method comprises the following steps: a first aeration system (2) and a water purification system (3),

wherein the content of the first and second substances,

a first aeration system (2) comprising:

a first water intake mechanism (21) for injecting water to be purified,

a first jet means (23) communicating with the water outlet passage of the first water intake means (21), and

a first air intake mechanism (22) in communication with the first jet mechanism (23);

wherein the first air inlet mechanism (22) is arranged at the front end of the inlet of the first jet mechanism (23),

the water purification system (3) mixes the water purifying agent with the water body and distributes the mixed water purifying agent liquid to the inlet front end of the first jet mechanism (23) to discharge the water purifying agent liquid through the first jet mechanism (23).

2. The water purification apparatus according to claim 1, wherein the first air intake mechanism (22) of the first aeration system (2) comprises a first air intake main pipe (221) and a first air intake branch pipe (223), one end of the first air intake main pipe (221) is connected to a first valve (222), and the other end thereof is connected to the first air intake branch pipe (223), and the water purification system (3) is connected to the first air intake branch pipe (223) of the first air intake mechanism (22) located at the inlet front end of the first jet mechanism (23).

3. The water purification apparatus of claim 2, further comprising a controller that controls the first valve (222), wherein in the aeration mode, the controller controls the first valve (222) to be open, and in the purification mode, the controller controls the first valve (222) to be closed.

4. The water purification apparatus according to claim 1 or 2, further comprising a second aeration system (5) and a microorganism system (4), wherein the second aeration system (5) comprises a second water intake mechanism (51) for injecting the water body to be purified, a second jet mechanism (53) communicating with a water outlet channel of the second water intake mechanism (51), and a second air intake mechanism (52) communicating with the second jet mechanism (53), the second air intake mechanism (52) being provided at an inlet front end of the second jet mechanism (53); the microbiological system (4) comprises a distributor connected to the inlet front end of said second fluidic means (53).

5. The water purification apparatus according to claim 4, wherein the second air intake mechanism (52) of the second aeration system (5) comprises a second air intake main pipe (524) and a second air intake branch pipe (526), one end of the second air intake main pipe (524) is connected to a second valve (525), and the other end thereof is connected to the second air intake branch pipe (526), and the distributor of the microbial system is connected to the second air intake branch pipe (526) of the second air intake mechanism (52).

6. The water purification apparatus of claim 5, further comprising a controller that controls the second valve (525), wherein in the aeration mode, the controller controls the second valve (525) to be opened, and in the microorganism dosing mode, the controller controls the second valve (525) to be closed.

7. The water purification apparatus according to claim 1 or 2, wherein the first water intake mechanism comprises an inlet channel (212), a water storage chamber (213), a pump (214) and an outlet channel (215) in the direction of the water flow, wherein the outlet channel (215) is arranged higher than the height of the water storage chamber (213).

8. Water purification apparatus according to claim 1 or 2, wherein the first jet means (23) comprises a water outlet pipe, inside which a screw (232) is arranged.

9. The water purification apparatus according to claim 1 or 2, wherein the water purification system (3) comprises a purifying agent passage (31) for introducing a purifying agent, a conditioning water passage (32) for adding a water body, a purifying agent tank (34) for mixing the purifying agent and the water body into a purifying agent liquid, and an introducing passage (33) for introducing the purifying agent liquid.

10. The water purifying apparatus as claimed in claim 9, wherein the water purifying agent passage (31) includes a water purifying agent tank (311) in which the water purifying agent is placed and a control valve (312) for controlling the amount of the water purifying agent to be applied, and the modulated water passage (32) includes a water pump (321) capable of controlling the amount of the introduced water.

11. The water purification device of claim 9, wherein the dosing channel (33) comprises a metering pump (331) and a distributor, wherein the metering pump (331) doses the water purifying agent liquid quantitatively according to the water quality requirement, and the distributor distributes the water purifying agent liquid uniformly.

12. The water purification apparatus of claim 4, wherein the second jet mechanism (53) comprises a water outlet pipe, a plurality of dosing holes (534) are formed in the water outlet pipe, and a filler (535) is arranged on the dosing holes (534).

13. The water purification apparatus of claim 5, wherein the microorganism system (4) comprises a microorganism tank (41) containing microorganisms, a solenoid valve (42), and a distributor, wherein the distributor is connected to the second air inlet branch pipe (526) of the second air inlet mechanism (52) through a pipe (44).

14. The water purification apparatus of claim 1 or 2, further comprising a water quality analysis sensor (6) for detecting the water quality of the water body.

15. A water treatment system comprising a water purification apparatus as claimed in any one of claims 1 to 14 and a body carrying the water purification apparatus such that the system can float on the surface of water.

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