CN212589679U - Fish and rice symbiosis intelligent control system - Google Patents

Abstract

The utility model discloses a fish and rice symbiosis intelligent control system, which comprises a rice field and fish culture areas distributed in the rice field; the head end of the fish culture area is communicated with an oxygenation pump through an air inlet pipe, the air inlet pipe is communicated with a fertilization channel with a fertilization valve, and the tail end of the fish culture area is sequentially connected with a separation net, a water retaining flashboard, a sewage collecting area, a sewage discharge pipeline with a sewage discharge valve, a fermentation tank, a purification tank, an underground pipeline and a rice field along the water flow direction of the fish culture area; a water pump of the fish culture area is arranged at the bottom end in the fish culture area; a paddy field area water pump communicated with the water inlet pipe is arranged in the paddy field and at the upper end of the fish culture area; a pressure pipeline is arranged on one side of the fish culture area, and a pressure valve is arranged on the pressure pipeline; the fish culture area is also provided with intelligent control equipment, and the inner wall of the fish culture area is provided with a liquid level meter; the rice field area suction pump, the fish culture area suction pump and the liquid level meter are electrically connected with the PLC electric cabinet. The utility model has the characteristics of with low costs, automatic intelligent control.

Description

Fish and rice symbiosis intelligent control system

Technical Field

The utility model relates to a fish rice intergrowth technical field, concretely relates to fish rice intergrowth intelligence control system.

Background

The symbiosis of rice and field fish is a self-balanced ecological system, which has an important protection effect on the surrounding ecological environment due to no chemical pesticide delivery, and is a traditional agricultural mode which is intensely stored by experts in various countries. Every spring transplanting, farmers can put fish fries and rice seedlings into the field together to grow the fish fries and the rice together. The rice and the field fish have a species interdependence relationship;

the traditional method for culturing the rice fishes deepens and widens cross-shaped and groined-shaped ditches, solidifies ridges and improves water level, has high requirements on rice field selection, occupies a large amount of land for excavation, is complex in facility reconstruction, is inconvenient to control water feeding and discharging, and has low yield, low comprehensive utilization rate and poor economic benefit and efficiency improvement; the breeding methods have the problems of high production cost, low rice and fish yield and inconvenient sewage treatment;

moreover, in recent years, with the annual increase in fish demand at home and abroad, the industrial fish culture is vigorously popularized; however, the industrial fish culture has a plurality of problems which are difficult to overcome, so that farmers are difficult to obtain high yield, even die a great amount of fish to cause loss, or the fish is small in size and low in fish yield, the key points of the fish culture technology are to control the water source quality, the pH value, the sterilization and disinfection and the oxygen supply control, and the key points of the rice culture are to control the soil humidity and the like.

In the prior art, the purification is realized mainly by a physical and chemical water quality purification method, and the purpose of high density is achieved, the cost of equipment facilities and operation is extremely high, the equipment facilities and the operation are difficult to be accepted by common farmers, and the problems of high culture cost and weak market competitiveness exist. In the past, the technologies are manually mastered, people without many years of fish culture experience cannot effectively control the technologies, even experienced farmers can only judge various factors through experience, and often, judgment omission and misjudgment cause major errors, so that economic loss is brought; therefore, it is urgently needed to provide an intelligent fish and rice symbiotic control system, which realizes automatic water quality purification, thereby achieving the purpose of high-density fish culture and reducing production cost, and the problem to be solved by technical personnel in the field is urgently needed.

SUMMERY OF THE UTILITY MODEL

In order to overcome the technical problem, the utility model provides a possess simultaneously with low costs, automatic intelligent control function's fish rice intergrowth intelligent control system, concrete scheme is as follows:

an intelligent fish and rice symbiosis control system comprises a rice field and fish culture areas distributed in the rice field, wherein the fish culture areas are positioned among rice seedlings; the head end of the fish culture area is communicated with an oxygenation pump through an air inlet pipe, the air inlet pipe is communicated with a fertilization channel with a fertilization valve, and the tail end of the fish culture area is sequentially connected with a separation net, a water retaining flashboard, a sewage collecting area, a sewage discharge pipeline with a sewage discharge valve, a fermentation tank, a purification tank, an underground pipeline and a rice field along the water flow direction of the fish culture area;

a water pump of the fish culture area is arranged at the bottom end in the fish culture area and is communicated with the sewage collection area through a connecting pipe; a paddy field area water pump communicated with a water inlet pipe is arranged in the paddy field and at the upper end of the fish culture area, and the water inlet pipe is communicated with the fish culture area through a filter box;

a pressure pipeline is arranged on one side of the fish culture area, a pressure valve is arranged on the pressure pipeline, and the depth of the pressure pipeline from the rice field is 1-2 m;

the fish culture area is also provided with intelligent control equipment, the intelligent control equipment comprises sensor equipment and a PLC (programmable logic controller) electric cabinet connected with the sensor equipment, and the sensor equipment comprises a methane sensor, an ammonia nitrogen sensor, a carbon dioxide concentration sensor, an oxygen concentration sensor, a pressure sensor and a pH measurement sensor; the oxygenation pump, the pressure valve, the application valve and the blowdown valve are electrically connected with the PLC electric cabinet;

a liquid level meter is arranged on the inner wall of the fish culture area; paddy field district suction pump and the district suction pump of breeding fish and level gauge all are connected with the PLC electric cabinet electricity, the level gauge is connected with the input electricity of PLC electric cabinet, breed fish district suction pump and paddy field district suction pump all are connected with the output electricity of PLC electric cabinet.

Preferably, the sensor equipment further comprises a soil humidity sensor, and the soil humidity sensor is electrically connected with the input end of the PLC electric cabinet.

Preferably, the top of the fish culture area is also provided with a waterproof breathable opening.

Preferably, a light source is further installed at the upper part in the fish culture area.

Preferably, the light source is an LED lamp tube.

Preferably, the light source is an ultraviolet disinfection lamp.

Preferably, the fish farming area comprises a bamboo tube type waterproof breathable belt.

Preferably, the separation net is a steel wire net, and the aperture of the net hole of the separation net is larger than the size of the outer contour of the fish manure or the bait and smaller than the size of the fish body in the fish culture area.

The utility model discloses relative prior art has substantive characteristics and progress, specifically speaking, the utility model has the following advantages:

1. the utility model discloses a set up oxygenation pump and make the district of breeding fish form the purpose that micro bubble reaches water oxygenation, be favorable to fish to survive more, increase its survival rate, when thereupon the oxygenation is intake, fish excrement and unnecessary bait can be along with rivers wash the dirty district of collection, and wash the dirty district of collection along with it in order to prevent the fish, install the separation net between dirty district of collection and the district of breeding fish additional, and the mesh aperture of separation net can let fish excrement, bait passes through the discrepancy that nevertheless can block the fish, and adopt the water purification of breeding fish district and the sewage of dirty district of collection of manger plate cutting apart, the sewage of dirty district of collection discharges to the paddy field after the fermentation purifies and increases the nutrient for the rice seedling, avoid because of the too much problem of fish mass propagation excrement and urine, the normal development of rice seedling has been guaranteed, need not to apply any liquid fertilizer or nutrition again, accomplish cyclic utilization, environmental protection and with low costs.

2. The utility model discloses a rose box returns the breed water of breeding the fish with the absorptive water of rice seedling purification to the district of breeding fish, and no any pollutant discharge accomplishes cyclic utilization again, reduces once more to breeding the fish district and intakes, energy saving, reduce cost.

3. The utility model discloses a set up the level gauge on the inner wall in the district of breeding fish, can find the water level degree in the district of breeding fish, in time to breeding fish district's intaking or drainage through paddy field district suction pump or the district suction pump of breeding fish, enable the better existence of fish.

4. The utility model discloses an intelligent control equipment, but indexes such as real-time detection raises the methane in fish district, ammonia nitrogen, carbon dioxide concentration, oxygen concentration, the pressure value, pH value, and indexes such as the soil moisture condition in paddy field, and control corresponding part action and open for fish oxygenation in the water as controller control oxygenation pump when carbon dioxide concentration is too high, oxygen content in the fish district has been reached, and soil moisture does not reach standard in the paddy field, in time diversion is irrigated, so that the rice seedling better draws moisture, thrive growth etc..

5. The utility model adopts the lamp source, the LED lamp tube can better provide photosynthesis for the fish culture area under the condition of insufficient illumination, and is more beneficial to the growth of fish; or the ultraviolet disinfection lamp can disinfect and sterilize to avoid the growth of bacteria to influence the growth of fishes.

6. The utility model has the advantages of reasonable design, adopt fish and rice intergrowth technique, utilize the ecological relation of the two to realize the sustainable dynamic development of circulated between the energy material, send out a natural ecological balance's system, both protected the environment, it is lower to compare again in traditional industrialization breed fish cost to reach water conservation and energy saving's effect.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic sectional view of the fish farming area of the present invention;

FIG. 3 is a schematic block diagram of the circuit of the intelligent control device of the present invention;

FIG. 4 is the overall structure diagram of the PLC electric cabinet of the utility model;

FIG. 5 is a circuit diagram of the connection between the intermediate frequency converter and the three-phase motor;

fig. 6 is a circuit diagram of a power supply system of the intelligent control device of the present invention;

FIG. 7 is a block diagram of the main control unit of the present invention;

FIG. 8 is a circuit diagram of the control circuit of the oxygen pump of the present invention;

fig. 9 and 10 are wiring circuit diagrams of the analog input/output module and the sensor device of the main control unit according to the present invention;

reference numbers in the figures: 1 breed fish district, 2 paddy fields, 3 rose boxes, 4 separate the net, 5 water retaining flashboards, 6 dirty districts of collection, 7 sewage pipes, 8 blowoff valves, 9 underground piping, 10 purifying ponds, 11 fermentation ponds, 12 pipeline under pressure, 13 waterproof ventilative openings, 14 inlet tubes, 15 paddy field district suction pumps, 16 oxygenation pumps, 17 passageway of giving fertilizer to students, 18 valve of giving fertilizer to students, 19 intake pipes, 20 breed fish district suction pumps, 21 drain pipes, 22 soil humidity inductor, 23 oxygen concentration inductor, 24 carbon dioxide concentration inductor, 25 methane inductor, 26 ammonia nitrogen inductor, 27 lamp sources, 28 pressure valves, 29PLC electric cabinet, 30 touch-sensitive screens.

Detailed Description

The technical solution of the present invention will be described in further detail through the following embodiments.

Example 1:

an intelligent fish and rice symbiosis control system is shown in figures 1 to 3 and comprises a rice field 2 and fish culture areas 1 distributed in the rice field 2, wherein the fish culture areas 1 are positioned among rice seedlings;

the head end of the fish culture area 1 is communicated with an oxygenation pump 16 through an air inlet pipe 19, the air inlet pipe 19 is communicated with a fertilization channel 17 with a fertilization valve 18, and the tail end of the fish culture area 1 is sequentially connected with a separation net 4, a water retaining flashboard 5, a sewage collecting area 6, a sewage discharge pipeline 7 with a sewage discharge valve 8, a fermentation tank 11, a purification tank 10, an underground pipeline 9 and a paddy field 2 along the water flow direction of the fish culture area 1;

a water pump 20 of the fish culture area is arranged at the bottom end in the fish culture area 1, and the water pump 20 of the fish culture area is communicated with the sewage collection area 6 through a connecting pipe; a paddy field area water pump 15 communicated with a water inlet pipe 14 is arranged in the paddy field 2 and at the upper end of the fish culture area 1, and the water inlet pipe 14 is communicated with the fish culture area 1 through a filter box 3;

the fish culture area 1 is also provided with intelligent control equipment, the intelligent control equipment comprises sensor equipment and a PLC (programmable logic controller) electric cabinet 29 connected with the sensor equipment, and the sensor equipment comprises a methane sensor 25, an ammonia nitrogen sensor 26, a carbon dioxide concentration sensor 24, an oxygen concentration sensor 23, a pressure sensor and a pH measuring sensor; the oxygenation pump 16, the pressure valve 28, the application valve 18 and the blowdown valve 8 are connected with a PLC electric cabinet 29;

when the methane sensor 25, the ammonia nitrogen sensor 26 and the pH measuring sensor sense that the contents of methane and ammonia nitrogen in the fish culture area 1 and the pH value are higher than a set value, the main controller controls the valve of the application channel 17 to be opened, and a certain repairing agent is added to adjust the water quality so as to achieve the water quality which is more suitable for the survival of fishes;

when the carbon dioxide concentration sensor 24 senses that the content of carbon dioxide in the fish culture area 1 is higher, the main controller controls the oxygenation pump 16 to be started to dissolve oxygen in the water body of the fish culture area 1, so that the fish can better live, and when the oxygen concentration sensor 23 senses that the oxygen in the fish culture area 1 reaches a preset value, the main controller controls the oxygenation pump 16 to stop working;

in order to keep the pressure intensity more suitable for the survival of fishes in the fish culture area 1, a pressure pipeline 12 is arranged on one side of the fish culture area 1, a pressure valve 28 is arranged on the pressure pipeline 12, and the depth of the pressure pipeline 12 from the paddy field 2 is 1-2 m; when the pressure sensor senses that the pressure in the fish culture area 1 is greater than a set value, the PLC electric cabinet 29 controls the pressure valve 28 to be opened, and the pressure balance between the coordination system and the outside air is realized;

a liquid level meter is arranged on the inner wall of the fish culture area 1; the rice field area water pump 15, the fish farming area water pump 20 and the liquid level meter are electrically connected with the PLC electric cabinet 29, the liquid level meter is electrically connected with the input end of the PLC electric cabinet 29, the fish farming area water pump 20 and the rice field area water pump 15 are electrically connected with the output end of the PLC electric cabinet 29, and when the water level detected by the liquid level meter is lower than a preset value, the controller controls the rice field area water pump 15 to pump water from the rice field 2 to enter the fish farming area 1; otherwise, water is pumped from the fish culture area 1 to the rice field 2, and the water is recycled through purification treatment, so that energy is saved, and cost is reduced.

The water suction pump 20 in the fish culture area, the water suction pump 15 in the rice field area and the oxygenation pump 16 are driven by motors, the motors are connected with frequency converters, the frequency converters are connected with the electric cabinet, and the main control unit of the electric cabinet controls the frequency converters to change the input power frequency of the motors so as to adjust the rotating speed of the motors.

Sensor equipment still includes soil moisture sensor 22, and soil moisture sensor 22 is connected with PLC electric cabinet 29's input electricity, and when soil moisture sensor 22 sensed the soil moisture in the paddy field 2 and reached the predetermined value, it irrigates to show that paddy field 2 need in time to draw water promptly, avoids rice seedling drought waterlogging and dies.

In order to ensure that the fish culture area 1 has a better ventilation function and better guarantee the normal living environment of the fish, a waterproof ventilation opening 13 is also arranged at the top of the fish culture area 1.

A light source 27 is also installed in the upper part of the fish farming area 1.

The lamp source 27 is an LED lamp tube, and can supply more illumination time for the fish culture area 1 in the time period of insufficient illumination, so that photosynthesis is improved, carbon dioxide in the fish culture area 1 is consumed, oxygen is generated, and the survival of fishes is facilitated.

The lamp source 27 is an ultraviolet disinfection lamp, excrement and bait in the fish culture area 1 is various and can not be discharged thoroughly to breed bacteria, the ultraviolet disinfection lamp can play a role in sterilization and disinfection, and water safety is guaranteed more effectively.

The fish culture area 1 comprises a bamboo tube type waterproof breathable belt, and the fish culture area 1 and the rice field 2 are separately cultured, so that the breathability of the fish culture area 1 is ensured, and the phenomenon that the dead fish bodies cause stink due to drought in the field in dry seasons can be avoided; in the rainy and waterlogging season, water in the rice field 2 can overflow, and the field fishes can swim away, so that certain loss is caused; and after the farmfish grows up, the farmfish can easily bite rice roots, so that the rice is withered due to root necrosis.

The separation net 4 is a steel wire net, the aperture of the net hole of the separation net 4 is larger than the size of the outer contour of fish dung or bait and smaller than the size of the fish body in the fish culture area, and the fishes are prevented from being flushed into the sewage collection area 6.

In the above embodiment, referring to fig. 4 to 10, the PLC electric cabinet 29 includes a main control unit and a touch screen, and the touch screen is electrically connected to the main control unit; the power supply system adopts an X2 incoming terminal of a three-phase alternating current motor to be connected with a sine VS5000 frequency converter, and when the power supply is carried out, the circuit breakers QF1 and QF2 are used for connecting three-phase power to supply power to the main controller, the touch screen and the internal instrument; the model of a main control unit of the PLC electric cabinet is SIMATIC S7-200, which comprises a CPU SR 20 module and two extended analog input and output modules EM AM 06; the CPU SR 20 module is used for controlling the oxygenation pump, and is specifically connected with an input terminal FWD of the frequency converter through a CPU output terminal Q0.0 to control the start of the oxygenation pump; the starting of the oxygenation pump can be manually and automatically controlled by pressing a button SA, a specific SA button is connected with an input terminal I0.0 of a CPU to realize switching control, a TC terminal of a frequency converter VS5000 is connected with an input terminal I0.1 of the CPU to feed back the running condition of the oxygenation pump, an OC1 terminal of the frequency converter VS5000 is connected with an input terminal I0.2 of the CPU to feed back whether the oxygenation pump fails or not; the X3 terminal of the analog input and output module EM AM06 is used for feeding back methane quantity, carbon dioxide quantity, oxygen content, ammonia nitrogen content and soil humidity, setting the motor rotating speed through terminals 0M and 0, is connected with DND and CC terminals of the frequency converter, and controls the motor rotating speed according to the set speed of the frequency converter.

The utility model discloses concrete working method does: firstly, rice is planted in a rice field 2, after the planted rice starts to grow, fish can be cultured in fish culture areas 1, and different varieties can be cultured in each fish culture area 1; when oxygen is added into the fish culture area 1 through the air inlet pipe 19, air can be pushed to flow to the other end of the channel, dissolved oxygen in water is supplemented constantly, oxygen is added to a water body, at the moment, fish excrement and redundant bait can flush to the sewage collection area 6 along with water flow, after the oxygen addition is finished, the water body does not flow any more, the water retaining flashboard 5 between the sewage collection area 6 and the separation net 4 is closed, and the situation that the survival of fishes is influenced by the mixing of purified water in the fish culture area 1 and sewage in the sewage collection area 6 is prevented; at the moment, a sewage valve 8 on a sewage pipeline 7 of the sewage collection area 6 is opened, and sewage is purified by a fermentation tank 11 and a purification tank 10 and then is discharged into the rice field 2 through an underground pipeline 9.

When the liquid level of the fish culture area 1 detected by the liquid level meter is lower than a set value, the intelligent control system transmits a signal to a main controller of a PLC (programmable logic controller) electric cabinet 29, the main controller controls a water suction pump 15 of the rice field area to be turned on, water in the rice field 2 is pumped through a water inlet pipe 14, and the water is filtered by a filter box 3 and then supplied to the fish culture area 1; on the contrary, when the water level of the fish culture area 1 detected by the liquid level meter is higher than the set value, the water pump 20 of the fish culture area is started to discharge the redundant water in the fish culture area 1 to the sewage collection area 6 through the drain pipe 21, the water in the sewage collection area 6 is supplied to the rice field 2 after being fermented and purified, and the steps are repeatedly circulated and reused in the way, and are not repeated;

when the pressure sensor detects that the pressure in the fish culture area 1 is greater than a set value, a signal is transmitted to a PLC (programmable logic controller) electric cabinet 29 main controller, the main controller controls a pressure valve 28 on the pressure pipeline 12 to be automatically opened, and the pressure balance between the system and the outside air is coordinated;

when the pH measuring sensor, the methane sensor 25 and the ammonia nitrogen sensor 26 sense that methane and ammonia nitrogen in the fish culture area 1 exceed the standard, signals are transmitted to the PLC electric cabinet 29 main controller, the main controller controls the opening of the application valve 18 on the application channel 17, and a repairing agent is added through the application channel 17 to adjust the water body;

when the carbon dioxide concentration sensor 24 senses that the concentration of carbon dioxide in the fish culture area 1 exceeds the standard, a signal is transmitted to the PLC electric cabinet 29 main controller, the main controller controls the oxygenation pump 16 to be started to dissolve oxygen in the water body of the fish culture area 1, and when the oxygen concentration sensor 23 senses that the oxygen in the fish culture area 1 is sufficient, the main controller controls the oxygenation pump 16 to be stopped;

when the soil humidity sensor 22 senses that the soil humidity in the rice field 2 is lower than a set value, water is introduced into the rice field 2 in time for irrigation, and a probe of the soil humidity sensor 22 is buried in the soil in the rice field 2 to a certain depth;

moreover, the intelligent control system can display and monitor various indexes in real time through the touch screen 30 on the PLC electric cabinet 29 according to signals detected by the sensor equipment, and a user can realize touch input, display output, parameter setting and other operations through the touch screen 30; the button and touch-sensitive screen are installed to the inboard door plant of PLC electric cabinet, and the door plant in the outside takes visual transparent window.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention and not to limit it; although the present invention has been described in detail with reference to preferred embodiments, it should be understood by those skilled in the art that: the invention can be modified or equivalent substituted for some technical features; without departing from the spirit of the present invention, it should be understood that the scope of the claims is intended to cover all such modifications and variations.

Claims (8)

1. The utility model provides a fish rice intergrowth intelligence control system which characterized in that: comprises a rice field (2) and fish culture areas (1) distributed in the rice field (2), wherein the fish culture areas (1) are positioned among rice seedlings;

the head end of the fish culture area (1) is communicated with an oxygenation pump (16) through an air inlet pipe (19), the air inlet pipe (19) is communicated with a fertilizing channel (17) with a fertilizing valve (18), and the tail end of the fish culture area (1) is sequentially connected with a separation net (4), a water retaining flashboard (5), a sewage collecting area (6), a sewage discharge pipeline (7) with a sewage discharge valve (8), a fermentation tank (11), a purification tank (10), an underground pipeline (9) and a rice field (2) along the water flow direction of the fish culture area (1);

a water suction pump (20) of the fish culture area is arranged at the bottom end in the fish culture area (1), and the water suction pump (20) of the fish culture area is communicated with the sewage collection area (6) through a connecting pipe; a paddy field area water pump (15) communicated with a water inlet pipe (14) is arranged in the paddy field (2) and at the upper end of the fish culture area (1), and the water inlet pipe (14) is communicated with the fish culture area (1) through a filter box (3);

a pressure pipeline (12) is arranged on one side of the fish culture area (1), a pressure valve (28) is arranged on the pressure pipeline (12), and the depth of the pressure pipeline (12) from the paddy field (2) is 1-2 m;

the fish culture area (1) is also provided with intelligent control equipment, the intelligent control equipment comprises sensor equipment and a PLC (programmable logic controller) electric cabinet (29) connected with the sensor equipment, and the sensor equipment comprises a methane sensor (25), an ammonia nitrogen sensor (26), a carbon dioxide concentration sensor (24), an oxygen concentration sensor (23), a pressure sensor and a pH measuring sensor; the oxygenation pump (16), the pressure valve (28), the application valve (18) and the blowdown valve (8) are electrically connected with a PLC (programmable logic controller) electric cabinet (29);

a liquid level meter is arranged on the inner wall of the fish culture area (1); paddy field district suction pump (15) and fish culture district suction pump (20) and level gauge all are connected with PLC electric cabinet (29) electricity, the level gauge is connected with the input electricity of PLC electric cabinet (29), fish culture district suction pump (20) and paddy field district suction pump (15) all are connected with the output electricity of PLC electric cabinet (29).

2. The fish-rice symbiotic intelligent control system according to claim 1, wherein: the sensor equipment further comprises a soil humidity sensor (22), wherein the soil humidity sensor (22) is electrically connected with the input end of the PLC electric cabinet (29).

3. The fish-rice symbiotic intelligent control system according to claim 1, wherein: the top of the fish culture area (1) is also provided with a waterproof and breathable opening (13).

4. The fish-rice symbiotic intelligent control system according to claim 1, wherein: and a lamp source (27) is also arranged at the upper part in the fish culture area (1).

5. The fish-rice symbiotic intelligent control system according to claim 4, wherein: the lamp source (27) is an LED lamp tube.

6. The fish-rice symbiotic intelligent control system according to claim 4, wherein: the lamp source (27) is an ultraviolet disinfection lamp.

7. The fish-rice symbiotic intelligent control system according to claim 1, wherein: the separation net (4) is a steel wire net, and the aperture of the net hole of the separation net (4) is larger than the external contour size of fish manure or bait and smaller than the size of a fish body in the fish culture area.

8. The fish-rice symbiotic intelligent control system according to claim 1, wherein: the fish culture area (1) comprises a bamboo tube type waterproof breathable belt.

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