CN219156736U

CN219156736U - Tail water treatment all-in-one machine

Info

Publication number: CN219156736U
Application number: CN202320319626.3U
Authority: CN
Inventors: 杨艺荣; 林文峰
Original assignee: Guangzhou Yangke Equipment Manufacturing Co ltd
Current assignee: Guangzhou Yangke Equipment Manufacturing Co ltd
Priority date: 2023-02-27
Filing date: 2023-02-27
Publication date: 2023-06-09
Anticipated expiration: 2033-02-27

Abstract

The utility model discloses a tail water treatment integrated machine, which comprises: particle filter, anaerobic filtration module, first water pump, good oxygen first order filtration module, good oxygen second order filtration module, ozone mixer, ultraviolet sterilization ware, second water pump, handle cell body, conveyer pipe and spray tube, particle filter sets up in first accommodation space in order to carry out particle filtration to the tailwater that breeds the pond and export, anaerobic filtration module sets up in the bottom of first accommodation space, first water pump setting is in the bottom of second accommodation space, good oxygen first order filtration module, good oxygen second order filtration module, ozone mixer sets up, ultraviolet sterilization ware and second water pump all set up in the second accommodation cavity. Through the mode, the tail water treatment integrated machine disclosed by the utility model can treat the tail water in the culture pond for recycling, so that the waste of water can be reduced, and the culture cost is effectively reduced.

Description

Tail water treatment all-in-one machine

Technical Field

The utility model relates to the technical field of aquaculture, in particular to a tail water treatment integrated machine.

Background

The aquaculture is not separated from the aquaculture pond, the aquaculture pond is a large field communicated with a natural water source, particularly the modern industrial high-density aquaculture industry is raised, the aquaculture pond is mainly, and the industrial aquaculture is most in the aquaculture pond because the aquaculture pond is convenient and smooth to drain and has the characteristic of preventing ecological natural water flow.

In general, in order to keep the clean of the culture pond, the culture pond is cleaned, so that tail water (namely sewage) of the culture pond is treated, and in the traditional mode, the tail water of the culture pond is directly drained, but on one hand, water resources are wasted, the culture cost is increased, and on the other hand, the environment is polluted, so that the method is not environment-friendly.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides a tail water treatment integrated machine for solving the technical problems.

(II) technical scheme

In order to solve the technical problems, the utility model provides the following technical scheme: the utility model provides a tail water treatment all-in-one, includes particle filter, anaerobism filtration module, first water pump, good oxygen one-level filtration module, good oxygen two-level filtration module, ozone mixer, ultraviolet sterilizer and second water pump, its characterized in that includes: the treatment tank body is provided with a first accommodating cavity and a second accommodating cavity which is not communicated with the first accommodating cavity, wherein the first accommodating cavity is internally provided with a first partition plate so as to divide the first accommodating cavity into a first accommodating space and a second accommodating space for accommodating tail water output from the culture tank through the first partition plate, the second accommodating cavity is internally provided with a second partition plate, a third partition plate, a fourth partition plate, a fifth partition plate, a sixth partition plate, a seventh partition plate and an eighth partition plate so as to divide the second accommodating cavity into a first treatment space, a second treatment space, a third treatment space, a fourth treatment space, a fifth treatment space, a sixth treatment space, a seventh treatment space and an eighth treatment space, the particle filter is arranged in the first accommodating space so as to carry out particle filtration treatment on the tail water output from the culture tank, the anaerobic filtration module is arranged at the bottom of the first accommodating space, and the particle filter is arranged at the bottom of the second water pump after passing through the anaerobic filtration module and being conveyed to the second accommodating space; one end of the conveying pipe is communicated with the output port of the first water pump; a spray pipe, one end of which is communicated with the other end of the conveying pipe, and the other end of which is positioned above the first treatment space, wherein a plurality of spray holes are arranged in the other end of the spray pipe at intervals; the first water pump filters the first water in the first treatment space, then flows into the third treatment space through the second treatment space, and then flows into the fifth treatment space through the fourth treatment space after being filtered by the second filtering module, and then flows into the fifth treatment space through the sixth treatment space after being treated by the ozone mixer, and then flows into the eighth treatment space after being sterilized by the ultraviolet sterilizer in the seventh treatment space, and then flows into the culture pond through the return pipe.

Further, the first partition plate is arranged at the top of the first accommodating cavity, and the height of the first partition plate is smaller than the depth of the first accommodating cavity, so that water in the first accommodating space flows into the second accommodating space from the bottom of the first partition plate.

Further, the second partition plate, the third partition plate, the fourth partition plate, the fifth partition plate, the sixth partition plate, the seventh partition plate and the eighth partition plate are sequentially arranged in the second accommodating cavity at intervals along the horizontal direction.

Further, the second partition plate is disposed at the top of the second receiving chamber, and the height of the second partition plate is smaller than the depth of the second receiving chamber, so that water in the first treatment space flows from the bottom thereof into the second treatment space.

Further, the third partition plate is arranged at the bottom of the second accommodating cavity, and the height of the third partition plate is smaller than the depth of the second accommodating cavity, so that water in the second treatment space flows into the third treatment space from the top of the third partition plate.

Further, the fourth partition plate is disposed at the top of the second accommodating cavity, and the height of the fourth partition plate is smaller than the depth of the second accommodating cavity, so that water in the third treatment space flows into the fourth treatment space from the bottom thereof.

Further, the fifth partition plate is disposed at the bottom of the second accommodating cavity, and the height of the fifth partition plate is smaller than the depth of the second accommodating cavity, so that water in the fourth treatment space flows from the top of the fifth partition plate into the fifth treatment space.

Further, the sixth partition is disposed at the top of the second receiving chamber, and the height of the sixth partition is smaller than the depth of the second receiving chamber, so that water in the fifth treatment space flows from the bottom thereof into the sixth treatment space.

Further, the seventh partition is disposed at the bottom of the second accommodating cavity, and the height of the seventh partition is smaller than the depth of the second accommodating cavity, so that water in the sixth treatment space flows into the seventh treatment space from the top thereof; the eighth partition plate is arranged at the top of the second accommodating cavity, and the height of the eighth partition plate is smaller than the depth of the second accommodating cavity, so that water in the seventh processing space flows into the eighth processing space from the bottom of the eighth partition plate.

(III) beneficial effects

Compared with the prior art, the utility model provides a tail water treatment integrated machine, which has the following beneficial effects: the utility model discloses a tail water treatment integrated machine, which comprises: particle filter, anaerobic filtration module, first water pump, good oxygen first order filtration module, good oxygen second order filtration module, ozone mixer, ultraviolet sterilization ware, second water pump, handle cell body, conveyer pipe and spray tube, particle filter sets up in first accommodation space in order to carry out particle filtration to the tailwater that breeds the pond and export, anaerobic filtration module sets up in the bottom of first accommodation space, first water pump setting is in the bottom of second accommodation space, good oxygen first order filtration module, good oxygen second order filtration module, ozone mixer sets up, ultraviolet sterilization ware and second water pump all set up in the second accommodation cavity. Through the mode, the tail water treatment integrated machine disclosed by the utility model can treat the tail water in the culture pond for recycling, so that the waste of water can be reduced, the culture cost is effectively reduced, and meanwhile, the environment is not polluted, and the environment is protected.

Drawings

FIG. 1 is a schematic diagram of a tail water treatment integrated machine according to the present utility model;

FIG. 2 is a schematic front view in cross section of the tail water treatment integrated machine of FIG. 1;

FIG. 3 is a schematic view showing a sectional structure of a treatment tank body of the tail water treatment integrated machine in FIG. 1;

fig. 4 is a schematic top sectional view of the tail water treatment integrated machine of fig. 1.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 4, the utility model provides a tail water treatment integrated machine, which comprises a treatment tank body 10, a particle filter 11, an anaerobic filter module 12, a first water pump 13, a conveying pipe 131, a spraying pipe 132, an aerobic primary filter module 14, an aerobic secondary filter module 15, an ozone mixer 16, an ultraviolet sterilizer 17 and a second water pump 18.

The treatment tank 10 includes a first housing chamber 101 and a second housing chamber 102 which is not in communication with the first housing chamber 101. It should be understood that the top of the first accommodating cavity 101 is provided with an opening, so that the tail water output by the culture pond enters the first accommodating cavity 101 from the opening of the first accommodating cavity 101.

Preferably, the first accommodating cavity 101 and the second accommodating cavity 102 are rectangular.

It should be understood that the top of the second accommodating cavity 102 is sealed, and one end of the second accommodating cavity 102 near the first accommodating cavity 101 is provided with a boss 103, the boss 103 is provided with an inner cavity communicating with the second accommodating cavity 102, and the top of the boss 103 is provided with an opening, so that water output from the first accommodating cavity 101 enters the second accommodating cavity 102 from the opening of the boss.

In the present embodiment, a first partition 1010 is provided in the first housing chamber 101 to divide the first housing chamber 101 into a first housing space 1011 and a second housing space 1012 for housing the tail water outputted from the cultivation pond by the first partition 1010.

Preferably, the first partition 1010 is disposed at the top of the first receiving chamber 101, wherein the height of the first partition 1010 is smaller than the depth of the first receiving chamber 101, such that water in the first receiving space 1011 flows from the bottom thereof into the second receiving space 1012. It should be appreciated that the tail water output from the pond is fed from the first housing space 1011 (e.g., conveyed via a conveying pipe).

In this embodiment, the particle filter 11 is disposed in the first housing space 1011 to perform particle filtration treatment on the tail water outputted from the cultivation pond. It will be appreciated that the tailwater output from the pond is fed directly to the inlet of the particulate filter 11.

Further, the anaerobic filter module 12 is disposed at the bottom of the first accommodating space 101, so that the water output from the particle filter 11 is filtered by the anaerobic filter module 12 and is transferred to the second accommodating space 1012. That is, the anaerobic filter module 12 is disposed at the outlet of the bottom of the first housing space 101 such that the water filtered by the particulate filter 11 is outputted from the outlet of the bottom of the first housing space 101.

Preferably, the first water pump 13 is disposed at the bottom of the second receiving space 1012 to pump the water in the second receiving space 1012 into the second receiving cavity 102 through the first water pump 13.

One end of the conveying pipe 131 is communicated with the output port of the first water pump 13, one end of the spraying pipe 132 is communicated with the other end of the conveying pipe 131, and the other end of the spraying pipe 132 is located above the first processing space 1021, so that water in the second accommodating space 1012 enters the second accommodating cavity 102 from the first processing space 1021.

Preferably, a plurality of injection holes are provided at intervals in the other end of the spray pipe 132. It should be appreciated that the spray tube 132 is open at the top of the boss 103 such that water within the spray tube 132 is sprayed downwardly from a plurality of spray holes, which allows the water to be in a greater contact with the air, thereby incorporating oxygen and increasing the activity of the water.

In the present embodiment, the second partition 21, the third partition 22, the fourth partition 23, the fifth partition 24, the sixth partition 25, the seventh partition 26, and the eighth partition 27 are provided in the second housing chamber 102 to divide the second housing chamber 102 into the first processing space 1021, the second processing space 1022, the third processing space 1023, the fourth processing space 1024, the fifth processing space 1025, the sixth processing space 1026, the seventh processing space 1027, and the eighth processing space 1028.

Preferably, the second, third, fourth, fifth, sixth, seventh and

eighth partitions

21, 22, 23, 24, 25, 26 and 27 are sequentially disposed at intervals in the horizontal direction within the second accommodation chamber 102.

In this embodiment, the aerobic primary filter module 14 is disposed at the bottom of the first processing space 1021 (i.e., the aerobic primary filter module 14 is disposed at the output port of the bottom of the first processing space 1021), the aerobic secondary filter module 15 is disposed at the bottom of the third processing space 1023 (i.e., the aerobic secondary filter module 15 is disposed at the output port of the bottom of the third processing space 1023), the ozone mixer 16 is disposed in the fifth processing space 1025 (i.e., the output port of the fourth processing space 1024 is communicated with the input port of the ozone mixer 16 such that the water output from the output port of the fourth processing space 1024 enters the ozone mixer 16), the ultraviolet sterilizer 17 is disposed in the seventh processing space 1027, and the second water pumps 18 are all disposed in the eighth processing space 1028. It should be understood that the ultraviolet sterilizer 17 serves to ultraviolet sterilize the water within the seventh processing space 1027.

It should be understood that the water in the first processing space 1021 is filtered by the aerobic primary filtering module 14, then flows through the second processing space 1022 and flows into the third processing space 1023, while the water in the third processing space 1023 is filtered by the aerobic secondary filtering module 15, then flows through the fourth processing space 1024 and flows into the fifth processing space 1025, the water in the fifth processing space 1025 is processed by the ozone mixer 16, then flows through the sixth processing space 1026, is sterilized by the ultraviolet sterilizer 17 in the seventh processing space 1027 and flows into the eighth processing space 1028, and the second water pump 18 pumps the water in the eighth processing space 1028 into the culture pond through the return pipe.

In this embodiment, the second partition 21 is disposed at the top of the second receiving chamber 102, wherein the height of the second partition 21 is smaller than the depth of the second receiving chamber 102, i.e. the bottom of the second partition 21 and the bottom wall of the second receiving chamber 102 form a communication port, so that the water in the first processing space 1021 flows from the bottom thereof into the second processing space 1022.

Preferably, the third partition 22 is disposed at the bottom of the second receiving chamber 102, wherein the height of the third partition 22 is smaller than the depth of the second receiving chamber 102, i.e. the top of the third partition 22 and the top wall of the second receiving chamber 102 form a communication port, so that the water in the second treatment space 1022 flows from the top thereof into the third treatment space 1023.

Preferably, the fourth partition 23 is disposed at the top of the second receiving chamber 102, wherein the height of the fourth partition 23 is smaller than the depth of the second receiving chamber 102, i.e. the bottom of the fourth partition 23 forms a communication port with the bottom wall of the second receiving chamber 102, so that the water in the third processing space 1023 flows from the bottom thereof into the fourth processing space 1024.

Preferably, the fifth partition 24 is disposed at the bottom of the second receiving chamber 102, wherein the height of the fifth partition 24 is smaller than the depth of the second receiving chamber 102, i.e. the top of the fifth partition 24 and the top wall of the second receiving chamber 102 form a communication port, so that the water in the fourth processing space 1024 flows from the top thereof into the fifth processing space 1025.

Preferably, the sixth partition 25 is disposed at the top of the second receiving chamber 102, wherein the height of the sixth partition 25 is smaller than the depth of the second receiving chamber 102, i.e., the bottom of the sixth partition 25 forms a communication port with the bottom wall of the second receiving chamber 102, so that the water in the fifth processing space 1025 flows from the bottom thereof into the sixth processing space 1026.

Preferably, the seventh partition 26 is disposed at the bottom of the second receiving cavity 102, wherein the height of the seventh partition 26 is smaller than the depth of the second receiving cavity 102, i.e. the top of the seventh partition 26 and the top wall of the second receiving cavity 102 form a communication port, so that the water in the sixth processing space 1026 flows from the top thereof into the seventh processing space 1027.

Preferably, the eighth partition 27 is disposed at the top of the second receiving chamber 102, wherein the height of the eighth partition 27 is smaller than the depth of the second receiving chamber 102, i.e., the bottom of the eighth partition 27 forms a communication port with the bottom wall of the second receiving chamber 102, so that the water in the seventh processing space 1027 flows from the bottom thereof into the eighth processing space 1028.

It should be understood that the flow direction of the water of this embodiment is: tail water output from the culture pond is input into the first accommodating space 1011 from the top of the first accommodating space 101, then flows from the bottom of the first accommodating space 1011 to the second accommodating space 1012, flows from the second accommodating space 1012 to the top of the first processing space 1021, flows from the bottom of the first processing space 1021 to the second processing space 1022, flows from the top of the second processing space 1022 to the third processing space 1023, flows from the bottom of the third processing space 1023 to the fourth processing space 1024, flows from the top of the fourth processing space 1024 to the fifth processing space 1025, flows from the bottom of the fifth processing space 1025 to the sixth processing space 1026, flows from the top of the sixth processing space 1026 to the seventh processing space 1027, flows from the bottom of the seventh processing space 1027 to the eighth processing space 1028, and is re-conveyed to the culture pond.

It should be noted that the particle filter 11, the anaerobic filter module 12, the first water pump 13, the aerobic primary filter module 14, the aerobic secondary filter module 15, the ozone mixer 16, the ultraviolet sterilizer 17 and the second water pump 18 of the present embodiment may be implemented by products in the prior art, and the principle and the structure thereof will not be described in detail herein.

It should be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a tail water treatment all-in-one, includes particle filter, anaerobism filtration module, first water pump, good oxygen one-level filtration module, good oxygen two-level filtration module, ozone mixer, ultraviolet sterilizer and second water pump, its characterized in that includes:

the treatment tank body is provided with a first accommodating cavity and a second accommodating cavity which is not communicated with the first accommodating cavity, wherein the first accommodating cavity is internally provided with a first partition plate so as to divide the first accommodating cavity into a first accommodating space and a second accommodating space for accommodating tail water output from the culture tank through the first partition plate, the second accommodating cavity is internally provided with a second partition plate, a third partition plate, a fourth partition plate, a fifth partition plate, a sixth partition plate, a seventh partition plate and an eighth partition plate so as to divide the second accommodating cavity into a first treatment space, a second treatment space, a third treatment space, a fourth treatment space, a fifth treatment space, a sixth treatment space, a seventh treatment space and an eighth treatment space, the particle filter is arranged in the first accommodating space so as to carry out particle filtration treatment on the tail water output from the culture tank, the anaerobic filtration module is arranged at the bottom of the first accommodating space, and the particle filter is arranged at the bottom of the second water pump after passing through the anaerobic filtration module and being conveyed to the second accommodating space;

one end of the conveying pipe is communicated with the output port of the first water pump;

a spray pipe, one end of which is communicated with the other end of the conveying pipe, and the other end of which is positioned above the first treatment space, wherein a plurality of spray holes are arranged in the other end of the spray pipe at intervals;

the first water pump filters the first water in the first treatment space, then flows into the third treatment space through the second treatment space, and then flows into the fifth treatment space through the fourth treatment space after being filtered by the second filtering module, and then flows into the fifth treatment space through the sixth treatment space after being treated by the ozone mixer, and then flows into the eighth treatment space after being sterilized by the ultraviolet sterilizer in the seventh treatment space, and then flows into the culture pond through the return pipe.

2. The tail water treatment integrated machine according to claim 1, wherein the first partition plate is disposed at the top of the first accommodating cavity, and the height of the first partition plate is smaller than the depth of the first accommodating cavity, so that water in the first accommodating space flows into the second accommodating space from the bottom thereof.

3. The tail water treatment integrated machine according to claim 1, wherein the second separator, the third separator, the fourth separator, the fifth separator, the sixth separator, the seventh separator, and the eighth separator are disposed in the second housing chamber at intervals in the horizontal direction in order.

4. A tailwater treatment all-in-one machine as defined in claim 3, wherein the second partition is disposed at a top of the second housing cavity, and a height of the second partition is smaller than a depth of the second housing cavity, such that water in the first treatment space flows into the second treatment space from a bottom thereof.

5. The tail water treatment integrated machine according to claim 4, wherein the third partition is disposed at the bottom of the second housing cavity, and the height of the third partition is smaller than the depth of the second housing cavity, so that water in the second treatment space flows from the top thereof into the third treatment space.

6. The tail water treatment integrated machine according to claim 5, wherein the fourth partition is disposed at a top of the second housing cavity, and a height of the fourth partition is smaller than a depth of the second housing cavity, so that water in the third treatment space flows from a bottom thereof into the fourth treatment space.

7. The tail water treatment integrated machine according to claim 6, wherein the fifth partition is disposed at a bottom of the second housing cavity, and a height of the fifth partition is smaller than a depth of the second housing cavity, so that water in the fourth treatment space flows from a top thereof into the fifth treatment space.

8. The tail water treatment integrated machine according to claim 6, wherein the sixth partition is disposed at a top of the second housing chamber, and a height of the sixth partition is smaller than a depth of the second housing chamber, so that water in the fifth treatment space flows from a bottom thereof into the sixth treatment space.

9. The tail water treatment integrated machine according to claim 8, wherein the seventh partition is disposed at the bottom of the second housing cavity, and the seventh partition has a height smaller than the depth of the second housing cavity, so that water in the sixth treatment space flows from the top thereof into the seventh treatment space;

the eighth partition plate is arranged at the top of the second accommodating cavity, and the height of the eighth partition plate is smaller than the depth of the second accommodating cavity, so that water in the seventh processing space flows into the eighth processing space from the bottom of the eighth partition plate.