WO2017020703A1

WO2017020703A1 - Intelligent marine oil contamination adsorption apparatus

Info

Publication number: WO2017020703A1
Application number: PCT/CN2016/090590
Authority: WO
Inventors: 郑景文
Original assignee: 郑景文
Priority date: 2015-07-31
Filing date: 2016-07-20
Publication date: 2017-02-09
Also published as: CN105089032A; CN105089032B

Abstract

An intelligent marine oil contamination adsorption apparatus comprises an oil slick absorption device (1), a transmission device (2), a wind-driven conveying device (3), a heat pump device (4), and a controller (5). The oil slick absorption device comprises an oil absorption conveyer belt (6), a floating body (7) and an oil absorption ball (8); the wind-driven conveying device comprises a fan (9), a cyclone separator (10), and a first rotary valve (11); the heat pump device comprises a refrigeration box (12) and an oil dissolving box (13). The oil absorption conveyer belt is installed on the floating body, the oil absorption ball is located on the oil absorption conveyer belt, and the floating body is connected to a hull (14). During use, the oil absorption ball is conveyed to perform circulating movement by using the oil slick absorption device, the transmission device and the wind-driven conveying device, the oil absorption ball is cooled by using the refrigeration box of the heat pump device, oil slick of the ocean or river is solidified and absorbed by using the cooled oil absorption ball, and the oil slick absorbed by the oil absorption ball is dissolved by using the oil dissolving box of the heat pump device. The heat pump device treats oil contamination by means of cooling and heating, and no oil absorption fiber material is used. An oil contamination removal process is energy-saving and environmentally-friendly, and no oil absorption material is consumed.

Description

Intelligent marine oil adsorption device

Technical field

The invention relates to an oil cleaning device, in particular to an intelligent marine oil adsorption device.

Background technique

At present, the cleaning of marine oil pollution includes the use of oil-absorbing fiber materials to absorb oil pollution. The use of oil-absorbing fiber materials to absorb oil pollution is not conducive to recycling. A smart marine oil pollution adsorption device that can be recycled and does not use oil-absorbing fiber materials has become a cleanup of ocean or river oil pollution. Need.

Summary of the invention

The object of the present invention is to overcome the deficiencies of the prior art and provide an intelligent marine oil pollution adsorption device, which utilizes an intelligent marine oil pollution adsorption device to recycle and clean up marine or river oil pollution.

The technical solution adopted by the invention is: an intelligent marine oil pollution adsorption device, comprising an oil absorbing device, a conveying device, a wind conveying device, a heat pump device and a controller, the conveying device, the wind conveying device, the heat pump device and the controller are installed on the hull The oil absorbing device comprises an oil suction conveyor belt, a floating body and an oil sucking ball, the wind power conveying device comprises a fan, a cyclone separator and a first rotary valve, the heat pump device comprises a refrigeration box and a dissolved oil tank; the oil suction conveyor belt is mounted on the floating body The oil sucking ball is located on the oil suction conveyor belt, the floating body is connected with the hull; the oil suction conveyor belt is connected with the conveying device, the conveying device is connected with the oil melting tank, the dissolved oil tank is connected with the fan, the fan is connected with the cyclone separator, the cyclone separator and the first rotary valve are connected. The first rotary valve is connected to the refrigeration box, and the refrigeration box is connected to the oil suction conveyor; the controller is connected to the oil absorption device, the transmission device, the wind power transmission device and the heat pump device through a control line.

When the intelligent marine oil adsorption device is used, the controller controls the refrigeration of the refrigeration unit of the heat pump device and the heating of the solution tank; the floating body is placed on the surface of the oily water, so that the oil suction ball is placed at the position of the oil surface of the water surface, and is driven by the oil suction conveyor belt. The oil absorbing ball moves at the position of the oil slick on the surface of the water, and absorbs the oil slick by the oil absorbing ball. The oil absorbing conveyor belt sends the oil absorbing ball to the conveying device, and the conveying device sends the oil absorbing ball to the solvating oil tank, and dissolves and solidifies the oil slick adsorbed to the oil absorbing ball by using the oil absorbing tank. The wind conveying device sends the oil sucking ball entering the dissolved oil tank to the refrigeration box, and uses the cooling box to cool the oil sucking ball, and the cooling box will be cooled. The oil sucker ball is sent back to the oil suction conveyor belt, so that it circulates continuously; the cooled oil absorbing ball is used to clean the oil surface of the water surface.

The invention has the beneficial effects that the intelligent marine oil adsorption device uses the oil absorbing device, the conveying device and the wind conveying device to transport the oil sucking ball to move, and uses the cooling box of the heat pump device to cool the oil sucking ball, and solidifies and absorbs the ocean by using the cooled oil sucking ball. Or the oil slick of the river, using the solvent tank of the heat pump device to dissolve the oil slick adsorbed by the oil absorbing ball, the heat pump device processes the oil stain by cooling and heating, and does not need the oil absorbing fiber material, the oil pollution process is energy-saving and environmentally friendly, and there is no loss of the oil absorbing material.

DRAWINGS

Figure 1 is a schematic view showing the structure of an intelligent marine oil adsorption device.

detailed description

The present invention will be further described below with reference to the accompanying drawings and specific embodiments:

FIG. 1 is a schematic view showing the structure of an intelligent marine oil pollution adsorbing device, comprising an oil absorbing device, a conveying device 2, a wind conveying device 3, a heat pump device 4, and a controller 5, a conveying device 2, and a wind conveying device. The device 3, the heat pump device 4 and the controller 5 are mounted on the hull 14; the oil absorbing device 1 comprises an oil suction conveyor 6, a floating body 7 and an oil absorbing ball 8, and the wind conveying device 2 comprises a fan 9, a cyclone 10 and a a rotary valve 11, the heat pump device 3 includes a refrigeration box 12 and a solution tank 13; the oil suction conveyor 6 is mounted on the floating body 7, the oil suction ball 8 is located on the oil suction conveyor 6, the floating body 7 is connected with the hull 14, and the oil suction conveyor 6 is The conveying device 2 is connected, the conveying device 2 is connected to the solution tank 13, the solvent tank 13 is connected to the fan 9, the fan 9 is connected to the cyclone 10, the cyclone 10 is connected to the first rotary valve 11, and the first rotary valve 11 is cooled. The tank 12 is connected, the refrigeration box 12 is connected to the oil suction conveyor 6, and the controller 5 is connected to the oil absorbing device 1, the conveyor 2, the wind power transmission device 3, and the heat pump device 4 via a control line.

The intelligent marine oil adsorption device is used in such a manner that, in use, the controller 4 controls the refrigeration of the refrigeration box 12 of the heat pump device 4 and the heating of the solution tank 13; the floating body 7 is placed on the surface of the oily water to place the oil suction ball 8 The position of the surface oil slick 15 is driven by the oil absorbing conveyor belt 6 to move the oil absorbing ball 8 at the position of the surface oil slick 15 , and the oil absorbing ball 8 is used to absorb the oil slick 15 , and the oil absorbing conveyor belt 6 sends the oil absorbing ball 8 to the conveying device 2 , the conveying device 2 The oil suction ball 8 is sent to the solution tank 13 to be dissolved. The oil tank 13 dissolves and solidifies the oil slick 15 adsorbed on the oil absorbing ball 8, and the wind power transmission device 2 sends the oil absorbing ball 8 that has entered the solvating tank 13 to the refrigeration box 12, and cools the oil absorbing ball 8 by the cooling box 12, and the cooling box 12 is cooled. The oil sucking ball 8 is sent back to the oil suction conveyor belt 6, and thus continuously circulates; after the cooled oil sucking ball 8 enters the position of the oil floating oil 15 in the water surface, the oil sucking ball 8 is used to cool the oil absorbing oil 15; the oil absorbing ball of the oil absorbing oil 15 is adsorbed. 8 is sent to the solution tank 13, and the oil floating 15 adsorbed to the oil sucker ball 8 is dissolved in the oil solution tank 13, and the oil slick 15 of the oil absorbing ball 8 is dissolved, and the oil absorbing ball 8 is sent to the refrigeration box 12 to be cooled. The tank 12 re-cools the oil absorbing ball 8, and the cooled oil absorbing ball 8 is returned to the position of the oil slick 15 on the water surface, so as to circulate continuously, the oil absorbing ball 8 is in the closed oil absorbing device 1, the conveying device 2, the wind conveying The device 3 and the heat pump device 4 are circulated and moved, and the oil slick 8 is used to clean the oil on the surface of the water.

In order to carry out the transfer of the oil absorbing ball 8 and the cooling box 12 is separated from the solvent tank 13, the refrigeration box 12 comprises a second rotary valve 16, the conveying device 2 comprising a third rotary valve 17 and a conveyor belt 19; the input of the first rotary valve 11 The port is connected to the discharge port 18 of the cyclone separator 10, the output port of the first rotary valve 11 is connected to the input port of the refrigeration box 12, the output port of the refrigeration box 12 is connected to the input port of the second rotary valve 16, and the output of the second rotary valve 16 is output. The port is connected to the oil suction conveyor 6, the oil suction conveyor 6 is connected to the conveyor belt 19, the conveyor belt 19 is connected to the input port of the third rotary valve 17, and the output port of the third rotary valve 17 is connected to the input port of the solvent tank 13, the oil tank 13 The output port is connected to the input port of the fan 9, and the fan 9 is provided with a conveying pipe 56. The output port of the fan 9 is connected to the conveying pipe 56, and the conveying pipe 56 is connected to the input port of the cyclone 10.

In order to carry out the feeding of the oil sucking ball 8 into the refrigeration box 12 while maintaining the closed state of the refrigeration box 12, the first rotary valve 11 is provided with a first sealed rotating blade 40, and the first sealed rotating blade 40 is provided with a plurality of each, first The sealing rotary vane 40 is sealingly connected to the inner cavity of the first rotary valve 11, and the input port of the first rotary valve 11 is separated from the output port by the first sealed rotary vane 40; the second rotary valve 16 is provided with a second sealed rotation. The blade 41 and the second sealing rotary blade 41 are provided in plurality, each of the second sealing rotary blades 41 is sealingly connected to the inner cavity of the second rotary valve 16, and the second rotary valve 16 is used to input the second rotary valve 16 through the second sealing rotary blade 41. Separated from the output.

When the oil sucker ball 8 is fed into the refrigerating case 12, the oil sucking ball 8 enters the input port of the first rotary valve 11 by the cyclone 10, and then enters the respective first rotating rotary vanes 40 by the input port of the first rotary valve 11. The oil sucking ball 8 entering each of the first sealed rotating blades 40 rotates in the cavity sealed by the first rotary valve 11 following the first sealed rotating blade 40, and the oil sucking ball 8 is rotated by the first rotating The input port of the rotary valve 11 is rotated to the output port of the first rotary valve 11, and then enters the refrigeration box 12 by the output port of the first rotary valve 11; when the oil suction ball 8 outputs the refrigeration box 12, the oil suction ball 8 enters the refrigeration box 12 The input port of the two rotary valve 16 enters each of the rotating second sealed rotating blades 41 by the input port of the second rotary valve 16, and the oil sucking ball 8 that enters each of the second sealed rotating blades 41 follows the second sealed rotating blade 41. The cavity of the second rotary valve 16 is rotated in the sealed cavity, and the oil sucking ball 8 is rotated from the input port of the second rotary valve 16 to the output port of the second rotary valve 16, and then enters the oil suction conveyor 6 through the output port of the second rotary valve 16. .

In order to separate the solution tank 13 from the conveying device 2, the third rotary valve 17 is provided with a third sealing rotary vane 42, and the third sealed rotary vane 42 is provided with a plurality, each of the third sealed rotary vane 42 and the third rotary valve The inner cavity sealing connection of 17 separates the input port of the third rotary valve 17 from the output port by the third sealing rotary vane 42; when the oil sucking ball 8 enters the third rotary valve 17, the oil sucking ball 8 enters the third by the conveying device 2 The input port of the rotary valve 17 is then entered into the respective rotating third sealed rotary vanes 42 by the input port of the third rotary valve 17, and the oil sucking balls 8 entering the respective third sealed rotary vanes 42 follow the third sealed rotary vanes 42. The cavity of the third rotary valve 17 is rotated in the sealed cavity, and the oil suction ball 8 is rotated from the input port of the third rotary valve 17 to the output port of the third rotary valve 17, and then enters the solution tank 13 through the output port of the third rotary valve 17.

When the intelligent marine oil adsorption device is used, the stern 14 is used to drive the oil absorbing device 1 to the polluted sea or river, and the floating body 7 is placed on the oily surface, so that the oil absorbing ball 8 on the oil suction conveyor 6 is placed on the water surface. Position of the oil 15 oil layer; controlling the oil absorbing device 1, the conveying device 2, the wind power conveying device 3, and the heat pump device 4 by the controller 4, the heat pump device 4 controls the refrigeration of the refrigeration box 12 and controls the heating of the oil sump 13; the wind conveying device 3, the oil suction ball 8 is sent to the refrigeration box 12, and the refrigeration box 12 sends the cooled oil absorption ball 8 to the oil absorption conveyor belt 6 through the second rotary valve 16; the oil suction conveyor belt 6 drives the oil suction ball 8 to move at the position of the surface oil slick 15 The cooled oil absorbing ball 8 is used to solidify and absorb the oil slick 15; after the oil absorbing ball 8 solidifies and absorbs the oil slick 15, the oil absorbing conveyor 6 sends the oil absorbing ball 8 to the conveying device 2, and the conveying device 2 passes the oil absorbing ball 8 through the third rotary valve 17. It is sent to the solvent tank 13, and the oil sump 13 is heated to dissolve and solidify the oil slick 15 adsorbed on the oil absorbing ball 8. After the oil slick 15 of the oil absorbing ball 8 is dissolved, the wind power transmission device 2 enters through the cyclone 10 and the first rotary valve 11 Solvent tank 1 The oil absorbing ball 8 in the 3 is sent back to the refrigeration box 12, and is continuously circulated; the oil absorbing ball 8 is used to circulate in the position of the refrigeration tank 12, the surface of the oil slick 15 and the oil sump 13 to clean the slick 15 of the ocean or river surface.

When the wind power transmission device 3 is in operation, the oil absorption ball 8 dissolves the adsorbed oil slick 15 in the solvating tank 13, and then is sent to the cyclone separator 10 through the conveying pipe 56 through the fan 9; after the airflow generated by the fan 9 draws the oil absorbing ball 8, The air flow and the oil absorbing ball 8 are sent to the cyclone 10 via the conveying pipe 56, and the air flow is separated from the oil absorbing ball 8 at the cyclone 10, and the air flow is discharged by the exhaust port 57 of the cyclone 10, and the oil absorbing ball 8 is composed of the cyclone 10 The discharge port 18 enters the first rotary valve 11.

In order to implement the use of the oil suction conveyor belt 6 to drive the oil absorbing ball 8 to move at the position of the surface oil slick 15, the oil absorbing conveyor belt 6 includes a first conveyor belt 20, a first bracket 21, a first motor 22, a first driving wheel 23 and a first passive The wheel 24, the base of the first motor 22 is fixedly connected to the first bracket 21, the rotating shaft of the first motor 22 is coupled to the axle of the first driving wheel 23, the axle of the first driving wheel 23 and the axle of the first driven wheel 24 are The bracket 21 is movably coupled, the first driving wheel 23 and the first moving wheel 24 are movably coupled with the first conveyor belt 20, and the bracket 21 is connected with the floating body 7; the first conveyor belt 20 is provided with a mesh hole for the oil slick 15 to pass through. The mesh is in contact with the oil absorbing ball 8 on the first conveyor belt 20; the oil slick 15 enters the upper surface of the first conveyor belt 20 and the cooled, continuously moving oil absorption on the first conveyor belt 20 through the mesh of the first conveyor belt 20. The ball 8 is in contact.

In order to carry out the movement of the first conveyor belt 20 of the oil sucking ball 8, the first conveyor belt 20 is provided with a plurality of barrier strips 25, and the oil sucking balls 8 are located between the adjacent barrier strips 25 so that the oil sucking balls 8 can be stuck on each of the barrier strips 25 Between the following, the first conveyor belt 20 is moved; the first telescopic tube 49 continuously enters the first conveyor belt 20 between the barrier bars 25, and the oil layer 8 follows the first conveyor belt 20, and the oil layer of the oil slick 15 continuously moves. The output interface 52 is located away from the position between the bars 25 of the first conveyor belt 20; when the first conveyor belt 20 is in operation, the oil sucking ball 8 enters the front input port 50 of the oil absorbing device 1 from the lower port of the first telescopic tube 49, The first motor 22 drives the first driving wheel 23 to rotate in a clockwise direction, and the first driving wheel 23 drives the first conveyor belt 20 to rotate through the first driven wheel 24, and the first conveyor belt 20 drives the oil absorption continuously entering the first conveyor belt 20. The ball 8 moves at the position of the oil layer 15 of the oil slick 15, and the first conveyor belt 20 feeds the oil absorbing ball 8 from the front input port 50 of the oil absorbing device 1 to the rear output port 52 of the oil absorbing device 1.

In order to carry out the oil absorbing ball 8 condensing and adsorbing the oil slick 15 on the oil absorbing conveyor belt 6, the conveying device 2 includes a second conveyor belt 43, a second bracket 44, a second motor 45, and a second driving wheel 46. And the second driven wheel 47, the base of the second motor 45 is fixedly connected to the second bracket 44, the rotating shaft of the second motor 45 is connected to the second driving wheel 46, the second bracket 44 is connected to the hull 14, and the second conveyor belt 43 is connected. Uniformly provided with a plurality of baffle strips 48 for holding the oil sucking ball 8 and lifting the oil sucking ball 8 To the third rotary valve 17; when the second conveyor belt 43 is in operation, the oil sucking ball 8 is fed from the second telescopic tube 51 to the feeding end 53 of the conveying device 2, and the second motor 45 drives the second driving wheel 46 in the clockwise direction. Rotating, the second driving wheel 46 drives the second conveyor belt 43 to rotate by the second driven wheel 47, and the second conveyor belt 43 conveys the oil absorbing ball 8 condensing and adsorbing the oil slick 15 from the feeding end 53 of the conveying device 2 to the conveying device. The discharge end 54 of 2 is then sent to the solution tank 13 via the third rotary valve 17.

In order to implement the movable connection of the second rotary valve 16 and the oil absorbing device 1, the floating performance of the oil absorbing device 1 on the water surface is maintained, and the first first telescopic tube is provided between the second rotary valve 16 and the oil absorbing device 1. 49. The upper port of the first telescopic tube 49 is connected to the output port of the second rotary valve 16, and the lower port of the first telescopic tube 49 is connected to the front input port 50 of the oil absorbing device 1. In order to carry out the movable connection of the oil absorbing device 1 and the conveying device 2, the floating performance of the oil absorbing device 1 on the water surface is maintained, and the elastic second telescopic tube 51 is provided between the oil absorbing device 1 and the conveying device 2, and the second The upper port of the telescopic tube 51 is connected to the rear output port 52 of the oil absorbing device 1, and the lower port of the second telescopic tube 51 is connected to the input port of the conveyor 2.

In order to reduce the loss of the cooling capacity, the refrigeration box 12, the first telescopic tube 49 and the second telescopic tube 51 are provided with a heat insulating layer; the conveying device 2 is provided with a heat insulating cover 59, and the second conveying belt 43 is located inside the heat insulating cover 59. In order to implement the connection of the floating body 7 with the hull 14, the floating body 7 is connected to the hull 14 by a chain or a rope, and the floating body 7 is pulled by the hull 14 through a chain or a rope to an oil-contaminated ocean or river, and the floating body 7 is constituted by an air cushion;

In order to condense and absorb the oil slick 15 to increase the capacity of the oil absorbing ball 8 to store the cooling capacity, the oil absorbing ball 8 is provided with an inner cavity, and the inner cavity of the oil absorbing ball 8 is provided with a cold storage material, and the inner cavity of the oil absorbing ball 8 The cold storage material includes ice crystals, and the ice crystals are sealed in the inner cavity of the oil sucking ball 8.

In order to carry out the lifting control of the floating body 7 of the oil absorbing apparatus 1, the oil absorbing ball 8 is placed in contact with the surface oil slick 15, and the floating body 7 includes a lifting tank 26, an oil absorbing groove 27, and a traction joint 28, a lifting tank 26 and an oil absorbing groove. 27 is integrally connected, the pool opening 29 of the lifting tank 26 is upward, the notch 30 of the oil suction groove 27 is downward, and the oil suction groove 27 is provided with an oil guiding passage 31, so that the surface oil can enter the oil suction groove 27 in the oil guiding passage 31; The conveyor belt 6 is disposed in the oil absorption groove 27, and the first bracket 21 is fixedly connected with the oil suction groove 27, and the oil suction ball 8 is located on the first driving wheel 23 and the upper half of the first conveyor belt 20 on the first driven wheel 24, and the oil sucking ball 8 is located at the oil layer position of the surface oil slick 15; the controller 5 is provided with a first sensor 32 and a second sensor 33, the first sensor 32 and the second sensor 33 are disposed in the oil absorbing groove 27; the lifting pool 26 is provided with the first water pump 34 And a second water pump 35, The first water pumping port 36 of the water pump 34 is disposed in the water surface of the ocean or river, and the first water outlet 37 of the first water pump 34 is located in the lifting pool 26 for pumping water from the ocean or river into the lifting pool 26, so that The weight of the floating body 7 is increased; the second water pumping port 38 of the second water pump 35 is disposed in the lifting pool 26, and the second water outlet 39 of the second water pump 35 is located outside the lifting pool 26 for pumping water out of the lifting pool 26 The weight of the floating body 7 is reduced; the controller 5 is connected to the first water pump 34 and the second water pump 35 via a water pump control line, and the controller 5 controls the first water pump 34 and the second water pump 35 to operate by the first sensor 32 and the second sensor 33.

In order to control the oil slick 15 within the detection range of the first sensor 32 and the second sensor 33, the initial state of the oil absorbing apparatus 1 is that the first sensor 32 is located on the upper surface of the oil layer of the oil slick 15 and the second sensor 33 is located on the floating surface. Above the upper surface of the oil 15 oil layer; the first sensor 32 is located below the second sensor 33, the distance between the first sensor 32 and the second sensor 33 is equal to or less than the thickness of the oil layer of the oil slick 15 , and the thickness of the oil layer of the oil slick 15 is greater than zero The probe of the first sensor 32 is located on the upper surface of the oil layer of the oil slick 15, or the probe of the first sensor 32 is located 2 to 3 cm above the upper surface of the oil layer of the oil slick 15; the probe of the second sensor 33 is located at the oil slick 15 The upper surface of the oil layer, or the probe of the second sensor 33 is located 2 to 3 cm above the upper surface of the oil layer of the oil slick 15; the probe of the first sensor 32 to the second sensor 33 has a probe distance equal to or smaller than the oil layer of the oil slick 15 The thickness of the oil slick 15 is located within the detection range of the first sensor 32 and the second sensor 33.

The oil absorbing device 1 is used by adjusting the distance between the first sensor 32 and the second sensor 33 according to the thickness of the oil layer of the oil slick 15, so that the distance between the first sensor 32 and the second sensor 33 is equal to or smaller than the oil layer of the oil slick 15 The thickness of the oil slick 15 is within the detection range of the first sensor 32 and the second sensor 33, so that the oil absorbing ball 8 is located at the oil layer of the oil slick 15; when the weight of the floating body 7 on the water surface is reduced, the floating body 7 is raised. The oil absorbing ball 8 on the first conveyor belt 20 and the first sensor 32 rise up following the rise of the floating body 7, so that the oil absorbing ball 8 is at a position away from the oil layer of the oil slick 15; when the oil absorbing ball 8 is raised away from the oil layer of the oil slick 15 When the first sensor 32 leaves the oil level of the oil layer of the oil slick 15, the first sensor 32 transmits its signal to the controller 5, and the controller 5 controls the operation of the first water pump 34, and the first water pump 34 continuously draws water from the ocean or the river. Into the lifting pool 26, the weight of the floating body 7 is continuously increased, and the floating body 7 is continuously decreased as the water of the lifting tank 26 is continuously increased. The oil sucking ball 8 on the first conveyor belt 20 of the oil suction groove 27 and the first sensor 32 follow the floating body 7. Falling down 8, when the ball drops back suction position within the oil slick 15, a first sensor When the device 32 contacts the oil level of the oil slick 15 or enters the oil level of the oil slick 15, the first sensor 32 transmits its signal to the controller 5, and the controller 5 controls the first water pump 34 to stop working; due to the influx of water from the ocean or river The lifting tank 26, the floating body 7 continuously decreases as its weight increases, the second sensor 33 descends following the falling of the floating body 7, when the oil sucking ball 8 descends away from the oil layer 15 of the oil slick, when the second sensor 33 contacts the oil surface of the oil slick 15 or When entering the oil level of the oil slick 15, the second sensor 33 transmits its signal to the controller 5, the controller 5 controls the operation of the second water pump 35, and the second water pump 35 pumps the water in the lifting pool 26 to make the weight of the floating body 7 constant. As a result, the floating body 7 continuously rises as the water of the lifting tank 26 decreases, the oil sucking ball 8 on the first conveyor belt 20 of the oil suction groove 27 and the floating body 7 following the second sensor 33 continuously rise; the second sensor 33 leaves the oil slick 15 At the oil level, the second sensor 33 transmits its signal to the controller 5, and the controller 5 controls the second water pump 35 to stop, and controls the oil absorbing ball 8 to the position of the oil layer of the oil slick 15.

When the oil absorbing device 1 is in operation, when the probe of the first sensor 32 is separated from the liquid surface of the oil layer 15 by more than 2 to 3 cm, the first sensor 32 transmits its signal to the controller 5, and the controller 5 controls the first The water pump 34 pumps water into the lift tank 26; when the probe of the first sensor 32 enters the upper surface of the oil layer of the oil sump 15 2 to 3 cm, the first sensor 32 transmits its signal to the control 5, and the controller 5 controls the first water pump. 34 stops pumping into the lift tank 26; when the probe of the second sensor 33 enters the liquid level of the oil layer 15 2 to 3 cm, the second sensor 33 transmits its signal to the controller 5, and the controller 5 controls the second water pump 35 The water of the lifting tank 26 is pumped away; when the probe of the second sensor 33 leaves the liquid level of the oil layer 15 of the oil slick 2 to 3 cm, the second sensor 33 transmits its signal to the controller 5, and the controller 5 controls the second water pump 35. The water of the lift 26 is stopped.

In order to enable the oil slick 15 on the water surface to enter the oil absorbing groove 27, a plurality of oil guiding passages 31 of the oil absorbing groove 27 are provided, and each oil guiding passage 31 communicates with the oil absorbing groove 27, and the oil guiding passage 31 is located at the oil layer of the oil slick 15 The position is to ensure that the oil slick 15 enters the oil sump 27.

In order to position the oil absorbing ball 8 entering the first conveyor belt 20 at the position of the oil layer of the oil slick 15, the center lines of the first driving wheel 23 and the first driven wheel 24 are located below the oil layer, and the first conveyor belt 20 and the first active belt The wheel 23 and the first driven wheel 24 are circumferentially connected, and the upper portion of the first conveyor belt 20 is located at the position of the oil layer of the oil slick 15; the oil absorbing ball 8 on the surface of the first conveyor belt 20 is positioned at the oil layer of the oil slick 15 .

When the first conveyor belt 20 is in operation, when the first driving wheel 23 and the first driving wheel 24 rotate in the clockwise direction, the first conveyor belt 20 follows the first driving wheel 23 and the first driven wheel 24 in a clockwise direction. In the direction of rotation, the first conveyor belt 20 continuously feeds the oil sucking ball 8 continuously dropped by the first telescopic tube 49 from the side of the first driven wheel 24 to the side of the driving wheel 23, and the oil sucking ball 8 follows the first conveyor belt 20 to be moved from the left side. To the right, then enters the conveyor 2 via the second telescopic tube 51; when the first drive wheel 23 and the first driven wheel 24 rotate in the clockwise direction, the axis of the first drive wheel 23 and the first driven wheel 24 and the oil slick 15 The distance remains unchanged, so that the position of the first conveyor belt 20 with the oil absorbing ball 8 dropped is maintained at the position of the oil layer of the oil slick 15, so that the oil absorbing ball 8 that continuously enters the first conveyor belt 20 remains before leaving the first conveyor belt 20. The oil slick 15 is in contact.

In order to keep the floating body 7 in an unsinkable state, the buoyancy of the floating body 7 is greater than its gravity; in order to prevent the floating body 7 from remaining in an unsinkable state, the water level of the lifting pool 26 is controlled, and the lifting pool 26 is provided with a plurality of drainage holes 55, each of which is provided The height of 55 is the same; for controlling the highest water level of the lift tank 26, the drain hole 55 is disposed at a distance of 10 cm from the upper side of the lift tank 26; when the water level of the lift tank 26 rises to the position of the drain hole 55, the inside of the lift tank 26 The water is drained back to the ocean or river by the drain hole 55.

When the first conveyor belt 20 is in operation, the first telescopic tube 49 continuously enters the oil absorbing ball 8 between the barrier strips 25 of the first conveyor belt 20, and the oil layer of the oil slick 15 is continuously moved following the first conveyor belt 20, and the output interface 52 is thereafter outputted. Positioned away from the position between the bars 25 of the first conveyor belt 20; the oil slick 15 enters the upper surface of the first conveyor belt 20 and the cooled, continuously moving oil absorption on the first conveyor belt 20 through the mesh of the first conveyor belt 20. The ball 8 contacts; as the oil slick 15 in the oil suction groove 27 is continuously condensed and adsorbed by the oil absorbing ball 8, the oil slick 15 in the oil absorbing groove 27 is continuously reduced, and the oil slick 15 outside the oil absorbing groove 27 continuously enters the oil absorption through the oil guiding passage 31. Slot 27, so as to achieve the purpose of cleaning up the ocean or river oil.

Claims

The intelligent marine oil pollution adsorption device is characterized in that: the intelligent marine oil pollution adsorption device comprises an oil absorbing device (1), a conveying device (2), a wind conveying device (3), a heat pump device (4) and a controller. (5) The conveying device (2), the wind conveying device (3), the heat pump device (4), and the controller (5) are mounted on the hull (14); the oil absorbing device (1) includes an oil suction conveyor belt (6) , the floating body (7) and the oil sucking ball (8), the wind conveying device (2) comprises a fan (9), a cyclone (10) and a first rotary valve (11), and the heat pump device (3) comprises a refrigeration box (12) and the dissolved oil tank (13); the oil suction conveyor belt (6) is mounted on the floating body (7), the oil sucking ball (8) is located on the oil suction conveyor belt (6), and the floating body (7) is connected with the hull (14); The conveyor belt (6) is connected to the conveyor (2), the conveyor (2) is connected to the solution tank (13), the solvent tank (13) is connected to the fan (9), and the fan (9) is connected to the cyclone (10). The cyclone separator (10) is connected to the first rotary valve (11), the first rotary valve (11) is connected to the refrigeration box (12), the refrigeration box (12) is connected to the oil suction conveyor belt (6), and the controller (5) ) through the control line and oil absorption device (1), pass Means (2), pneumatic conveying means (3) and a heat pump means (4) is connected.
The intelligent marine oil adsorption device according to claim 1, characterized in that: said refrigeration box (12) comprises a second rotary valve (16), and said transfer device (2) comprises a third rotary valve (17) And a conveyor belt (19); the input port of the first rotary valve (11) is connected to the discharge port (18) of the cyclone (10), and the output port of the first rotary valve (11) is connected to the input port of the refrigeration box (12) The output port of the refrigeration box (12) is connected to the input port of the second rotary valve (16), the output port of the second rotary valve (16) is connected to the oil suction conveyor belt (6), and the oil suction conveyor belt (6) and the conveyor belt (19) Connected, the conveyor belt (19) is connected to the input port of the third rotary valve (17), the output port of the third rotary valve (17) is connected to the input port of the solution tank (13), and the output port of the dissolved oil tank (13) and the fan (9) The input port is connected, the fan (9) is provided with a conveying pipe (56), the output port of the fan (9) is connected with the conveying pipe (56), and the conveying pipe (56) is connected with the input port of the cyclone (10) .
The intelligent marine oil pollution adsorbing device according to claim 2, wherein the first rotary valve (11) is provided with a first sealed rotating blade (40), and the first sealed rotating blade (40) is provided with a plurality of Each first sealing rotary vane (40) is sealingly connected to the inner cavity of the first rotary valve (11), and the first rotary rotary vane (40) is used to separate the input port of the first rotary valve (11) from the output port. The second rotary valve (16) is provided with a second sealing rotary vane (41), and the second sealed rotary vane (41) is provided with a plurality of each of the second sealed rotary vane (41) and the second rotary valve (16). The inner cavity is sealed, and the second rotary valve (16) is used to transfer the second rotary valve (16) The inlet is separated from the outlet.
The intelligent marine oil pollution adsorbing device according to claim 2, wherein the third rotary valve (17) is provided with a third sealed rotating blade (42), and the third sealed rotating blade (42) is provided with a plurality of Each third sealing rotary vane (42) is sealingly connected to the inner cavity of the third rotary valve (17), and the third rotary rotary vane (42) is used to separate the third rotary valve (17) input port from the output port. .
The intelligent marine oil pollution adsorption device according to claim 1, wherein the oil absorption conveyor belt (6) comprises a first conveyor belt (20), a first bracket (21), a first motor (22), The first driving wheel (23) and the first driving wheel (24), the base of the first motor (22) is fixedly connected with the first bracket (21), the rotating shaft of the first motor (22) and the first driving wheel (23) The axle connection, the axle of the first driving wheel (23) and the axle of the first driven wheel (24) are movably coupled with the bracket (21), the first driving wheel (23) and the first moving wheel (24) and the first A conveyor belt (20) is movably coupled, and the bracket (21) is connected to the floating body (7); the first conveyor belt (20) is provided with a mesh hole, so that the oil slick (15) can pass through the mesh and the first conveyor belt (20) The upper oil absorbing ball (8) is in contact; the first conveyor belt (20) is provided with a plurality of barrier strips (25), and the oil absorbing ball (8) is located between the adjacent barrier strips (25) to make the oil absorbing ball (8) Can be stuck between each barrier strip (25), following the movement of the first conveyor belt (20).
The intelligent marine oil pollution adsorbing device according to claim 1, wherein said conveying device (2) comprises a second conveyor belt (43), a second bracket (44), a second motor (45), and a The second driving wheel (46) and the second passive wheel (47), the base of the second motor (45) is fixedly connected with the second bracket (44), and the rotating shaft of the second motor (45) and the second driving wheel (46) The second bracket (44) is connected to the hull (14); the second conveyor belt (43) is provided with a plurality of baffle strips (48).
The intelligent marine oil pollution adsorbing device according to claim 2, wherein a flexible first telescopic tube (49) is disposed between the second rotary valve (16) and the oil absorbing device (1), The upper port of a telescopic tube (49) is connected to the output port of the second rotary valve (16), and the lower port of the first telescopic tube (49) is connected to the front input port (50) of the oil absorbing device (1).
The intelligent marine oil pollution adsorbing device according to claim 71, wherein a flexible second telescopic tube (51) is disposed between the oil absorbing device (1) and the conveying device (2), and the second telescopic tube The upper port of the tube (51) is connected to the rear output port (52) of the oil absorbing device (1), and the lower port of the second telescopic tube (51) is connected to the input port of the transfer device (2).
The intelligent marine oil pollution adsorbing device according to claim 8, wherein the refrigeration box (12), the first telescopic tube (49) and the second telescopic tube (51) are provided with a heat insulating layer; and the conveying device (2) A heat shield (59) is provided, and a second conveyor belt (43) of the conveyor (2) is located in the heat shield (59).
The intelligent marine oil pollution adsorbing device according to claim 1, characterized in that: the oil sucking ball (8) is provided with an inner cavity, and the inner cavity of the oil sucking ball (8) is provided with a cold storage material and an oil sucking ball (8). The cold storage material of the inner cavity includes ice crystals, and the ice crystals are sealed in the inner cavity of the oil sucking ball (8).