CN209958311U

CN209958311U - Marine quick soil pick-up device, soil pick-up rail and soil pick-up rail system

Info

Publication number: CN209958311U
Application number: CN201920314007.9U
Authority: CN
Inventors: 陈大海
Original assignee: Shenzhen Ocean Guard Environmental Protection Technology Co Ltd
Current assignee: Shenzhen Ocean Guard Environmental Protection Technology Co Ltd
Priority date: 2019-03-12
Filing date: 2019-03-12
Publication date: 2020-01-17
Anticipated expiration: 2029-03-12

Abstract

The utility model relates to a marine quick soil pick-up device, soil pick-up rail and soil pick-up rail system. A marine quick sewage suction device comprises a breather pipe, an air bag arranged on the periphery of the breather pipe, and a sewage suction material arranged on the periphery of the air bag; the vent pipe is used for introducing high-pressure gas or vacuum; the breather pipe is respectively communicated with the air bag and the sewage absorbing material through the connecting structure arranged on the breather pipe, so that the breather pipe can inflate the air bag and can recycle pollutants from the sewage absorbing material. The device has the advantages of good recovery effect, high efficiency, simple structure and high automation degree. The sewage suction fence formed by the sewage suction device can be used in a large-area pollution area, intercepts and recovers a pollution source, and effectively controls the pollution source. The system formed by the sewage suction fence, the winding machine and the pump station has the advantages of small volume, convenient transportation and storage, convenient use and high automation degree.

Description

Marine quick soil pick-up device, soil pick-up rail and soil pick-up rail system

Technical Field

The utility model relates to a cleaning equipment on water, more specifically say and indicate a marine quick soil pick-up device, soil pick-up rail and soil pick-up rail system.

Background

Due to the frequent human activities, the pollution of oceans, rivers, lakes, etc. is getting more and more serious, and secondary pollution is derived from the pollution. The oceans, rivers, lakes and the like are polluted, most of the pollutants are floating objects on the water surface, and therefore, the problem of how to intercept and recover the floating objects becomes a worldwide problem.

Because the pollutants (such as oil spill) float on the water surface, the uncertainty is strong, the diffusion is fast, the pollution area is large, and the collection is difficult. Once contaminated, untimely interception can have even greater consequences.

Chinese patent discloses a surface garbage collection device (CN201811290999.2), including: the garbage absorption device comprises a buoy unit, and a vortex generator and a garbage absorption unit which are respectively connected with the buoy unit; the floating barrel unit comprises a barrel body with a garbage accommodating cavity and a floating barrel arranged on the peripheral side wall of the barrel body so that the barrel body can float on the surface of a water area. The top end of the cylinder body is detachably provided with a cylinder cover, and the side wall of the cylinder cover is uniformly provided with at least two garbage suction ports. The garbage suction inlet is communicated with the garbage accommodating cavity. The vortex generator is arranged at the bottom of the floating barrel; and the garbage absorption unit comprises a water pump which is arranged at the bottom of the barrel and is suitable for pumping water in the garbage accommodating cavity. The above patent has no interception function, cannot carry out interception and collection in a large scale, and has weak applicability to large-scale occasions such as oceans, rivers, lakes and the like; and the degree of automation is not high. Also, recovery through mechanical properties is low, structural components are complex, bulky, and costly.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's defect, provide a marine quick soil pick-up device, soil pick-up rail and soil pick-up rail system.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a marine quick sewage suction device comprises a breather pipe, an air bag arranged on the periphery of the breather pipe, and a sewage suction material arranged on the periphery of the air bag; the vent pipe is used for introducing high-pressure gas or vacuum; the breather pipe is respectively communicated with the air bag and the sewage absorbing material through the connecting structure arranged on the breather pipe, so that the breather pipe can inflate the air bag and can recycle pollutants from the sewage absorbing material.

The further technical scheme is as follows: the dirt absorbing material is one or more of oil absorbing cotton, hydrophobic oil absorbing felt and hydrophobic three-dimensional fabric.

The further technical scheme is as follows: the periphery of the sewage absorbing material is wrapped with a fixed net; and a cable is arranged in the ventilating pipe.

The further technical scheme is as follows: a sleeve is arranged between the vent pipe and the air bag; the periphery of the sleeve is fixedly connected with the air bag.

The further technical scheme is as follows: the connecting structure comprises a mounting shell, a forward one-way valve and a reverse one-way valve, wherein the mounting shell is rotationally connected to the outer side of the vent pipe; an inner cavity is formed in the mounting shell, and is communicated with the air bag through a first channel and communicated with the dirt absorbing material through a second channel; the positive one-way valve is arranged in the first channel, and the negative one-way valve is arranged in the second channel, so that the air bag is inflated by the vent pipe, and the sewage absorbing material is discharged.

The further technical scheme is as follows: two ends of the mounting shell are rotatably connected with the vent pipe through sealing bearings; a plurality of sealing rings are arranged between the mounting shell and the vent pipe.

The further technical scheme is as follows: two ends of the mounting shell are rotatably connected with the vent pipe through sealing bearings; a rotary joint is arranged between the mounting shell and the vent pipe; the air inlet end of the rotary joint is communicated with the vent pipe, and the air outlet end of the rotary joint is communicated with the inner cavity of the mounting shell.

The further technical scheme is as follows: the output end of the second channel extends to form a plurality of collecting pipes which are uniformly distributed on the inner side of the sewage absorbing material; and a plurality of collecting holes are uniformly distributed on the periphery of the collecting pipe so as to be communicated with the sewage absorbing material.

The further technical scheme is as follows: the periphery of the collecting pipe is wrapped with a filter membrane for water isolation.

The further technical scheme is as follows: the second channel is at least two to make the area of contact of increase and soil pick-up material, improve soil pick-up efficiency.

The further technical scheme is as follows: the air bag is provided with an air release opening. The vent pipe is a hose, and two ends of the hose are sealed; the hose is internally provided with a cable (a steel cable), and two ends of the cable extend out from the closed end of the vent pipe.

The further technical scheme is as follows: the air pipe is rotatably connected with the air pipe; the middle part of the baffle frame is rotationally connected with the vent pipe, and two ends of the baffle frame extend to the upper side and the lower side of the air bag.

A sewage suction fence comprises a plurality of sewage suction devices; the sewage suction devices are sequentially connected to form a fence structure; the breather pipe is communicated with the pump station. The both ends of breather pipe and power ship fixed connection, at the during operation, the power ship drags from the both ends of rail, and the rail moves on the surface of water, and under the resistance effect of the surface of water, soil pick-up material, gasbag can be rotatory around the breather pipe, because soil pick-up material has hydrophobic characteristic, constantly absorb the pollutant of surface of water. When the pollutant absorption material is saturated to the pollutant, the vent pipe is communicated with vacuum, the first channel is closed and the second channel is opened under the action of the forward one-way valve and the reverse valve, and the pollutant is recovered by the vent pipe to the pollutant absorption material.

A sewage suction fence system comprises the sewage suction fence, a winding machine for winding and unwinding the sewage suction fence, and a pump station for providing an air source for the sewage suction fence; one end of the cable is fixedly connected with the winch, and the other end of the cable is fixedly connected with the power boat so as to discharge the enclosure. The winding machine and the pump station are arranged on the shore or on the ship.

Compared with the prior art, the utility model beneficial effect be: the utility model uses the vent pipe to supply air to the air bag to control the buoyancy, thereby adapting to different polluted environments; the pollutant absorption material can absorb pollutants in an absorption mode, and after the adsorption is full, the vent pipe is communicated with vacuum to absorb and recover the pollutants. The device has the advantages of good recovery effect, high efficiency, simple structure and high automation degree. The sewage suction fence formed by the sewage suction device can be used in a large-area pollution area, intercepts and recovers a pollution source, and effectively controls the pollution source. The system formed by the sewage suction fence, the winding machine and the pump station has the advantages of small volume, convenient transportation and storage, convenient use and high automation degree.

The invention is further described with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a three-dimensional structure diagram of the marine rapid sewage suction device of the present invention;

FIG. 2 is a middle sectional view of the marine rapid sewage suction device of the present invention;

fig. 3 is a middle sectional view of another embodiment of the marine rapid sewage suction device of the present invention;

FIG. 4 is a collecting pipe structure view of the marine rapid sewage suction device of the present invention;

FIG. 5 is a schematic side view of a circular connection structure of the marine rapid sewage suction device of the present invention;

FIG. 6 is the utility model discloses a square connection structure side-looking sketch of marine quick soil pick-up device

FIG. 7 is a three-dimensional structure view of the marine rapid sewage suction device with a baffle frame;

fig. 8 is a schematic view of a dirt suction fence according to the present invention;

fig. 9 is a schematic view of a soil pick-up fence system according to the present invention.

Detailed Description

In order to more fully understand the technical content of the present invention, the technical solution of the present invention will be further described and illustrated with reference to the following specific embodiments, but not limited thereto.

Fig. 1 to 9 show drawings according to embodiments of the present invention.

A marine quick soil pick-up device Q, as shown in fig. 1 to 2, comprises a vent pipe 10, an air bag 11 arranged on the periphery of the vent pipe 10, and a soil pick-up material 12 arranged on the periphery of the air bag 11. The vent tube 10 is used for introducing high pressure gas or vacuum. The vent pipe 10 is respectively communicated with the air bag 11 and the sewage absorbing material 12 through a connecting structure 13, so that the vent pipe 10 inflates the air bag 11 and recovers pollutants from the sewage absorbing material 12. The air bag 11 can increase buoyancy, and simultaneously control the air inflow of the air bag 11, and can control the buoyancy to adapt to different polluted environments.

Preferably, the dirt absorbing material 12 is one or more of oil absorbent cotton, hydrophobic oil absorbent felt and hydrophobic three-dimensional fabric, and besides, the dirt absorbing material 12 can also be a series of products such as super-hydrophobic net material, oleophilic hydrophobic sponge obtained by dip coating method by utilizing the characteristics of nano-cellulose and graphene, high-performance oil fence material, underwater organic matter adsorbing material and the like.

The dirt-absorbing material 12 is wrapped with a fixing net 14 for fixing the dirt-absorbing material 12 and also for allowing contaminants to enter the dirt-absorbing material 12 from the gap of the fixing net 14.

Wherein, in order to increase flexibility and strength, the inside of the snorkel 10 is provided with a cable 15. The vent pipe 10 is a hose, and both ends of the hose are closed. The cable 15 (preferably a steel cable, which is covered with a corrosion-resistant, stretch-resistant, or other polymer material) extends from the closed end of the vent tube 10 at both ends and is secured to another object while the device is being towed.

A sleeve 16 is arranged between the vent pipe 10 and the air bag 11. The sleeve 16 is fixedly connected with the air bag 11 at the periphery, and when the sleeve 16 rotates, a gap is formed between the sleeve 16 and the air bag 11, so that the sleeve 16 rotates around the vent pipe 10, and the air bag 11 and the vent pipe 10 are prevented from being worn mutually.

As shown in fig. 2, the connection structure 13 includes a mounting case 131 rotatably coupled to the outside of the snorkel 10, a forward check valve 132 and a reverse check valve 133. An inner cavity 134 is arranged inside the mounting shell 131, and the inner cavity 134 is communicated with the air bag 11 through a first passage 135 and is communicated with the dirt absorbing material 12 through a second passage 136. The forward check valve 132 is disposed in the first passage 135 and the reverse check valve 133 is disposed in the second passage 136 so that the vent tube 10 inflates the bladder 11 and discharges the blotting material 12. When the pollutant absorption material 12 is full of pollutants, the vent pipe 10 is vacuumized, the forward check valve 132 is closed under the action of the pressure of the air bag 11, the reverse check valve 133 is opened under the action of the air pressure, and simultaneously, the pollutants in the pollutant absorption material 12 are absorbed and discharged from the vent pipe 10 under the action of the vacuum.

Preferably, the connecting structure 13 is entirely buried inside the dirt absorbing material 12, so that damage to the connecting structure 13 can be avoided and the service life can be prolonged.

The two ends of the mounting case 131 are rotatably coupled to the snorkel 10 by means of sealing bearings 137. Wherein the sealed bearing 137 is a non-metallic wear resistant, corrosion resistant bearing. A plurality of sealing rings 138 are disposed between the mounting housing 131 and the ventilation pipe 10 for sealing between the ventilation pipe 10 and the connection structure 13. The seal ring 138 is made of a corrosion-resistant, wear-resistant material.

In another embodiment, as shown in fig. 3, both ends of the mounting case 131 are rotatably coupled with the snorkel 10 by providing sealing bearings 137. A rotary joint 139 is provided between the mounting case 131 and the breather pipe 10. The air inlet end of the rotary joint 139 is communicated with the air pipe 10, and the air outlet end is communicated with the inner cavity 134 of the mounting shell 131. The rotary joint 139 is sealingly embedded inside the mounting case 131.

Preferably, as shown in fig. 2, 4 and 5, the output end of the second channel 136 extends with a plurality of collecting pipes 17 which are uniformly distributed inside the dirt absorbing material 12. A plurality of collecting holes 171 are uniformly distributed on the outer periphery of the collecting pipe 17 so as to communicate with the soil adsorbing material 12. The collecting pipe 17 is wrapped with a filter membrane 172 for water-stop. The second channel 136 is at least two to increase the contact area with the soil pick-up material 12 and improve the soil pick-up efficiency. The collecting pipe 17 is arranged in the pollutant absorption material 12 like a human neural network, after the pollutant absorption material 12 absorbs pollutants, the collecting pipe 17 is communicated with the ventilating pipe 10, vacuum is introduced, and the pollutants enter the collecting pipe 17 through the collecting hole 171 and then are collected in the ventilating pipe 10.

As shown in fig. 6, the connecting structure 13 is a flat block or a cylinder to facilitate the rolling.

Preferably, as shown in fig. 1, the air bag 11 is provided with a vent 111 and extends to the outside of the soil pick-up material 12, so that when the whole device is recovered, the air in the air bag 11 can be vented for better storage and transportation.

As shown in fig. 7, in order to prevent the spreading of the wave or pollutant under the water surface when the whole sewage suction device is in operation, a blocking frame 18 rotatably coupled to the ventilation pipe 10 is further included. The middle part of the baffle frame 18 is rotatably connected with the vent pipe 10, and the two ends extend to the upper side and the lower side of the air bag 11. The part of the baffle frame 18 positioned at the upper side of the sewage suction device can prevent the diffusion of the wave to the pollutants; the portion of the frame 18 on the underside of the device blocks contaminants from diffusing below the water surface. Preferably, the center of gravity of the baffle frame 18 is concentrated at the lower end or a weight 181 is provided at the lower end so that the baffle frame 18 is in an upright or inclined state in operation.

A soil pick-up fence Q3, as shown in fig. 8, comprises a plurality of soil pick-up devices Q as described above. The sewage suction devices Q are sequentially connected to form a fence structure. The vent pipe 10 is in communication with a pump station Q1. The two ends of the vent pipe 10 are fixedly connected with a power boat Q2 (a pump station Q1 is arranged on a power boat Q2), when the air-conditioning ventilating device works, the power boat Q2 is dragged from the two ends of the fence, the fence moves on the water surface, under the resistance action of the water surface, the dirt absorbing material 12 and the air bag 11 can rotate around the vent pipe 10, and because the dirt absorbing material 12 has the hydrophobic characteristic, the pollutant on the water surface is continuously absorbed. When the contaminant absorption of the contaminant-absorbing material 12 is saturated, the vacuum is applied to the vent tube 10, and the first passage 135 is closed and the second passage 136 is opened under the action of the forward check valve 132 and the reverse check valve, so that the contaminant is recovered by the vent tube 10 from the contaminant-absorbing material 12.

The soil pick-up material 12 can be used for respectively and efficiently adsorbing and recovering crude oil, heavy oil, light oil, diesel oil and gasoline, organic chemical liquid, underwater organic chemical liquid and the like on water. The soil adsorbing material 12 may be an oleophobic and hydrophilic emulsified oil separating material for emulsified oil dispersed in water. The contamination of algae is not negligible, and when the optimal stage for eliminating algae is cell division, the algae is adsorbed by the soil adsorbing material while the cells are still in the cell stage.

In a dense place of the marine aquaculture industry, the pollution is serious due to feeding, the diffusion is quick, serious secondary pollution can be caused, and the fence is arranged outside the culture area, so that the diffusion of feeding residues can be effectively restrained, and the secondary pollution is reduced.

A dirt pick-up pen system, as shown in fig. 9, includes the dirt pick-up pen Q3 described above, a winder Q4 for retrieving and releasing the dirt pick-up pen Q3, and a pump station Q1 for supplying air to the dirt pick-up pen Q3. The cable 15 is fixedly connected at one end to a hoist Q4 and at the other end to a powered boat Q2 for paying out the pen. The winder Q4 and the pump station Q1 are arranged on the shore or on the ship.

Due to the requirements of transportation and storage, the fence system is required to be small in size, light in weight and convenient to use, so that the sewage absorbing fence Q3 is wound on the winch, and the winch can be placed on the shore or a ship; the pump station Q1 can be operated simultaneously when discharging the dirt pick-up pen Q3.

In summary, the utility model uses the vent pipe to supply air to the air bag to control the buoyancy, thereby adapting to different polluted environments; the pollutant absorption material can absorb pollutants in an absorption mode, and after the adsorption is full, the vent pipe is communicated with vacuum to recover the pollutants. The device has the advantages of good recovery effect, high efficiency, simple structure and high automation degree. The sewage suction fence formed by the sewage suction device can be used in a large-area pollution area, intercepts and recovers a pollution source, and effectively controls the pollution source. The system formed by the sewage suction fence, the winding machine and the pump station has the advantages of small volume, convenient transportation and storage, convenient use and high automation degree.

The technical content of the present invention is further described by the embodiments only, so that the reader can understand it more easily, but the embodiments of the present invention are not limited thereto, and any technical extension or re-creation according to the present invention is protected by the present invention. The protection scope of the present invention is subject to the claims.

Claims

1. A marine quick sewage suction device is characterized by comprising a breather pipe, an air bag arranged on the periphery of the breather pipe, and a sewage suction material arranged on the periphery of the air bag; the vent pipe is used for introducing high-pressure gas or vacuum; the breather pipe is respectively communicated with the air bag and the sewage absorbing material through the connecting structure arranged on the breather pipe, so that the breather pipe can inflate the air bag and can recycle pollutants from the sewage absorbing material.

2. The marine rapid soil pick-up device of claim 1, wherein the soil pick-up material is one or more of oil absorbent cotton, hydrophobic oil absorbent felt and hydrophobic three-dimensional fabric.

3. The marine rapid sewage suction device according to claim 1, wherein the periphery of the sewage suction material is wrapped with a fixing net; and a cable is arranged in the ventilating pipe.

4. The marine quick soil pick-up device of claim 1, wherein a sleeve is provided between the vent pipe and the air bag; the periphery of the sleeve is fixedly connected with the air bag.

5. The marine quick soil pick-up device of claim 1, wherein the connection structure comprises a mounting housing rotatably coupled to an outside of the vent pipe, a forward check valve and a reverse check valve; an inner cavity is formed in the mounting shell, and is communicated with the air bag through a first channel and communicated with the dirt absorbing material through a second channel; the positive one-way valve is arranged in the first channel, and the negative one-way valve is arranged in the second channel, so that the air bag is inflated by the vent pipe, and the sewage absorbing material is discharged.

6. The marine quick sewage suction device of claim 5, wherein the two ends of the installation shell are rotatably connected with the vent pipe through the arranged sealing bearings; a plurality of sealing rings are arranged between the mounting shell and the vent pipe;

or the two ends of the mounting shell are rotationally connected with the vent pipe through the arranged sealing bearings; a rotary joint is arranged between the mounting shell and the vent pipe; the air inlet end of the rotary joint is communicated with the vent pipe, and the air outlet end of the rotary joint is communicated with the inner cavity of the mounting shell.

7. A marine rapid sewage suction device according to any one of claims 5 or 6, wherein the output end of the second channel extends with a plurality of collecting pipes which are uniformly distributed at the inner side of the sewage suction material; and a plurality of collecting holes are uniformly distributed on the periphery of the collecting pipe so as to be communicated with the sewage absorbing material.

8. The marine quick soil pick-up device of claim 1, further comprising a baffle frame rotatably coupled to the vent pipe; the middle part of the baffle frame is rotationally connected with the vent pipe, and two ends of the baffle frame extend to the upper side and the lower side of the air bag.

9. A soil pick-up pen comprising a plurality of soil pick-up devices as claimed in any one of claims 1 to 8; the sewage suction devices are sequentially connected to form a fence structure; the breather pipe is communicated with the pump station.

10. A soil pick-up fence system comprising the soil pick-up fence of claim 9, a winder for winding and unwinding the soil pick-up fence, and a pump station for providing a source of air to the soil pick-up fence; one end of the cable is fixedly connected with the winch, and the other end of the cable is fixedly connected with the power boat so as to discharge the enclosure; the winding machine and the pump station are arranged on the shore or on the ship.