JP6748832B1 - Marine environment monitoring equipment in the estuary - Google Patents

Abstract

PROBLEM TO BE SOLVED: To disclose a marine environment monitoring facility in an estuary. SOLUTION: A river channel open upward is installed in the river channel including a coast, water in the river channel flows forward, and a sampling device can move and rotate in the river channel. Installed so that the sampling device can take a sample of water from the river channel and inspect and measure the weight of the debris, and the sampling device can separate the debris from the water and load the top edge of the shore. The base is fixedly connected, the gantry is fixedly connected to the upper end of the load base, the present invention is installed at the mouth of a river, and the weight of suspended matter dust in a certain volume of water in the river. Can be inspected and measured, when the weight of the trash is too heavy, it is necessary for humans to control the discharge of trash upstream, and the trash can be treated from the river to avoid the large amount of trash being discharged into the sea. [Selection diagram] Fig. 1

Description

The present invention relates to the field of environmental protection, and more specifically to a marine environment monitoring facility in an estuary.

Many environmental pollutants in the ocean are brought by humans, who discharge waste into rivers, rivers discharge waste into the sea, and some water-soluble wastes discharged into the sea It is automatically cleaned by the marine ecosystem, but large amounts of suspended solids cannot be decomposed after being discharged into the sea, and suspended solids are harmful to marine life and are now commonplace. The floating debris floating on the sea surface is pulled up by a steamer to be treated, the treatment efficiency is low, resources are wasted, and it is impossible to prevent the garbage from being continuously discharged from the river to the sea. And the amount of garbage discharged into the sea is different depending on different rivers, the present invention discloses a marine environment monitoring facility in the estuary area, and can solve the above problems. The weight of suspended solids in a volume of water can be inspected and measured, and when the weight of waste is too large, it is necessary for a person to control the discharge of waste on the river. Avoid dumping garbage into the sea.

Chinese Patent Application Publication No. 102313662

Technical issues:
Since the debris of suspended solids in the ocean is generally discharged from the stream, existing technologies cannot effectively control the debris discharged from the stream to the ocean.

In order to solve the above problems, the present invention designed a marine environment monitoring equipment in an estuary area, and the marine environment monitoring equipment in the estuary area described in the present invention includes a coast, and an opening is opened in the coast. A channel is installed, water in the channel flows forward, a sampling device is installed in the channel so that the sampling device can move and rotate, and the sampling device samples water from the channel. The weight of waste can be inspected and measured, and the sampling device can separate the waste from water. A load base is fixedly connected to the upper end of the shore, and a pedestal is fixed to the upper end of the load base. Are connected to each other, and the holes are installed in the load base so as to penetrate vertically, the holes are facing the river channel, and the sampling device is located in the holes. A rotary lifting device is connected between the load base and the gantry, the rotary lifting device is rotatably connected to the sampling device, and the sampling device is driven to rotate the sampling device in conjunction. Or it can be raised and lowered, the rotation range of the sampling device is ninety degrees, which makes the sampling device convenient to take water sample, and the auxiliary device can be rotated at the upper end of the rotary lifting device. The auxiliary device can be connected to the rotary lifting device to assist the lifting and lowering of the sampling device, stabilize the lifting and lowering of the sampling device, and the position limit switch is symmetrically fixed to the lower end of the frame. And the position limiting switch is operably connected to the rotary lifting device, and the position limiting switch can control start and stop of the rotary lifting device.

Advantageously, the rotary lifting device includes symmetrically installed gear chambers in the left and right inner walls of the hole, and the driving gear is rotatably installed in the gear chamber. A long rotation shaft is fixedly installed in the inside, the upper end of the long rotation shaft is connected to the auxiliary device, and a hoisting motor is fixedly installed in the lower inner wall of the gear chamber. The hoisting motors are connected to the position limiting switches on both sides so as to be energized, and the lower end of the long rotating shaft is connected to transmit power to the hoisting motors. A driven gear is installed at one end of the driven gear so as to mesh with each other, and a vertical screw is fixedly connected to the driven gear, and an upper end of the vertical screw is rotatably connected to the gantry. A slidable screw thread block is connected to the peripheral surface by a screw thread, and a vertical connecting rod is fixedly connected to one end of the screw thread block close to the center of symmetry so that the vertical connecting rod can rotate to the sampling device. The sampling device can be moved up and down by moving the vertical connecting rod up and down, and when the upper end of the vertical connecting rod contacts the position limiting switch, the hoisting motor is stopped.

Preferably, a fixed block is fixedly connected to one end of the vertical connecting rod away from the center of symmetry, the fixed block is located below the thread block, and the fixed block is symmetrical in the fixed block. A communication chamber opened in the direction of the center is installed, the communication chamber extends into the vertical connecting rod, and a driving pulley is installed in the communication chamber so that the driving pulley can rotate. A driven pulley is rotatably installed on one side close to the belt conveyor, a belt conveyor is connected between the driving pulley and the driven pulley, and a spline shaft is connected to the driving pulley by a spline. A spline shaft is rotatably connected to the fixed block, the spline shaft is fixedly connected to a circumferential surface of the vertical screw, and the vertical shaft is fixedly connected to the driven pulley. A deceleration chamber is installed in the lower inner wall of the chamber, the lower end of the vertical shaft extends into the deceleration chamber, and a small bevel gear is fixedly connected to the lower end of the vertical shaft. A large bevel gear is installed so as to mesh with one end of the bevel gear that is close to the center of symmetry, and a slow rotation shaft is fixedly connected to one end of the large bevel gear that is close to the center of symmetry. One end of the symmetry center may be fixedly connected to the sampling device, and the slow rotation shaft may rotate the sampling device.

Beneficially, the sampling device includes a water tub rotatably and slidably installed in the channel and the vent, with the vertical connecting rods on both sides rotating to the left and right ends of the water tub. , The slow rotation shafts on both sides are fixedly connected to the left and right ends of the water tank, and a water storage chamber having an upward opening is installed in the water tank to store a sample of water in the water storage tank. A slide plate is slidably installed in the water storage chamber, a fixed slider is fixedly connected to a lower end of the slide plate, and a fixed slider is installed in the fixed slider. A closed chamber opened to the bottom is installed, a fixed piston is fixedly connected to the lower end of the water storage chamber, an upper end of the fixed piston extends into the sealed chamber, and a pressure is applied to the upper end of the fixed piston. The probe is fixedly connected, the pressure probe can inspect and measure the air pressure value in the sealed chamber, and the change in the air pressure of the sealed chamber inspected and measured by the pressure probe before or after treating the dust. The value indicates the weight of dust.

Preferably, a transmission chamber is symmetrically installed on the lower inner wall of the water storage chamber, and meshing gears are symmetrically and longitudinally installed in the transmission chamber so that the meshing gears on the front and rear sides can be rotated. The gears mesh with each other, and a belt winding wheel is fixedly connected to one end of the meshing gears on the left and right sides apart from the center of symmetry, and an electric shaft is fixed between the belt winding wheels on the left and right sides. A motor is fixedly installed in the left inner wall of the transmission chamber on the left side, and the left end of the electric shaft on the front side is connected to the motor so that power can be transmitted to the motor. A tension belt is wound around the peripheral surface, and a belt groove is formed in the upper inner wall of the transmission chamber so as to be symmetrical in the front-rear direction and communicate with each other. The storage chamber opened to the communication chamber is installed so as to communicate with each other. One inner wall of the storage chamber, which is close to the center of symmetry, communicates with the water storage chamber, and a torsion shaft can rotate between the left and right inner walls of the storage chamber. And a torsion ring is fixedly connected to the circumferential surface of the torsion shaft in a symmetrically fixed manner, the upper end of the tension belt extends into the storage chamber, and the circumference of the torsion ring is It is wound around the surface, a filter is connected between the twisted shafts on both sides so as to be wound, a sealing block is fixedly installed in the belt groove, and the tension belt is slidable on the sealing block. , The sealing block prevents water from flowing into the belt groove.

Preferably, a torsion spring is fixedly connected between one end of each of the twisted wheels on both the left and right sides, which is separated from the center of symmetry, and the left and right inner walls of the storage chamber.

Advantageously, the auxiliary device includes turning chambers symmetrically installed in the pedestal, wherein the upper ends of the long rotation shafts on both sides extend into the turning chambers on both sides, respectively. A turning drive gear is fixedly connected to the upper end of the long rotation shaft, a turning driven gear is installed on the front side of the turning drive gear so as to mesh, and a connecting shaft is fixed to the front end of the turning driven gear. A chain winding is fixedly connected to the circumferential surface of the connecting shaft, and a downward direction opening guide chamber is installed in the inner wall of one side of the turning chamber that is close to the center of symmetry. A fixed shaft is rotatably connected between front and rear inner walls of the direction guide chamber, and a direction guide wheel is fixedly connected to a circumferential surface of the fixed shaft, and the direction guide wheel and the chain winding wheel are connected to each other. A chain is connected between the two, and the lower end of the chain is fixedly connected to the water tub.

Preferably, a directional guide groove is formed in the directional guide wheel, the directional guide groove opening in a direction in which the back is turned to the fixed shaft, the chain slides along the directional guide groove, and the directional guide groove is Avoid slipping back and forth as the chain slides.

The beneficial effects of the present invention are: The present invention is installed at the mouth of a river and can measure the weight of suspended solids in a certain volume of water in a river. It is necessary to control the discharge of trash on the river, the trash can be treated from the river, and a large amount of trash is not discharged to the sea.

In order to explain the present invention in detail in conjunction with FIGS. 1 to 8 below and to explain it conveniently, the following directions are defined as follows: FIG. 1 is a front view of the device of the present invention, and The left, right, front, and rear directions are the same as the top, bottom, left, right, front, and rear directions of the self-projection relationship in FIG.

FIG. 1 is a schematic diagram of the entire structure of the marine environment monitoring equipment in the estuary of the present invention. FIG. 2 is an enlarged schematic view of “A” in FIG. FIG. 3 is an enlarged schematic view of “B” in FIG. FIG. 4 is an enlarged schematic view of “C” in FIG. FIG. 5 is an enlarged schematic view of “D” in FIG. FIG. 6 is a schematic structural view of the “EE” direction in FIG. FIG. 7 is a structural schematic diagram of the “FF” direction in FIG. FIG. 8 is a structural diagram of the “GG” direction of FIG. 7.

INDUSTRIAL APPLICABILITY The present invention relates to a marine environment monitoring facility in an estuary, and is mainly applied to inspect and measure the weight of suspended solids in an estuary, and further explains the present invention with reference to the attached drawings of the present invention below. :

The marine environment monitoring equipment in the estuary described in the present invention includes a coast 11, a channel 13 having an opening upward is installed in the coast 11, and water in the channel 13 flows forward, A sampling device 100 is movably and rotatably installed in the sampling device 13, so that the sampling device can take a sample of water from the river channel 13 to inspect and measure the weight of the dust. Can separate dust from water, a load base 37 is fixedly connected to the upper end of the shore 11, and a pedestal 15 is fixedly connected to the upper end of the load base 37. A vent hole 46 is installed so as to vertically penetrate therethrough, the vent hole 46 faces the river channel 13, the sampling device 100 is located in the vent hole 46, and the load base A rotary lifting device 101 is connected between the 37 and the gantry 15, the rotary lifting device 101 is rotatably connected to the sampling device 100, and the sampling device 101 is driven to interlock the sampling device 100. The sampling device 100 has a rotation range of 90 degrees, which makes it convenient for the sampling device 100 to take a sample of water, and the upper end of the rotation lifting device 101 has an auxiliary function. The device 102 is rotatably connected, and the auxiliary device 102 can assist the rotary lifting device 101 to move the sampling device 100 up and down, and stabilize the up and down movement of the sampling device 100. The position limiting switch 20 is symmetrically and fixedly connected, and the position limiting switch 20 is connected so that the rotary lifting device 101 can be energized. The position limiting switch 20 activates the rotary lifting device 101. And you can control the stop.

Hereinafter, the rotary lifting device 101 will be described in detail with reference to embodiments. The rotary lifting device 101 includes gear chambers 39 symmetrically installed in the inner walls of the left and right sides of the hole 46. A driving gear 38 is rotatably installed in the driving gear 38, a long rotation shaft 28 is fixedly installed in the driving gear 38, and an upper end of the long rotation shaft 28 is connected to the auxiliary device 102. A hoisting motor 40 is fixedly installed in the inner wall of the lower side of 39, and the hoisting motors 40 on both sides are connected so that the position limiting switches 20 on both sides can be energized. The lower end is connected to the hoisting electric motor 40 so that power can be transmitted, and a driven gear 41 is installed at one end of the main driving gear 38 close to the center of symmetry so that the driven gear 41 meshes vertically. A screw 27 is fixedly connected, an upper end of the vertical screw 27 is rotatably connected to the pedestal 15, and a slidable thread block 26 is connected to a circumferential surface of the vertical screw 27 by a screw thread. A vertical connecting rod 25 is fixedly connected to one end of the thread block 26 close to the center of symmetry, the vertical connecting rod 25 is rotatably connected to the sampling device 100, and the vertical connecting rod 25 moves up and down. The sampling device 100 can be interlocked with the rising device, and when the upper end of the vertical connecting rod 25 comes into contact with the position limiting switch 20, the hoisting motor 40 is stopped.

Beneficially, a fixing block 29 is fixedly connected to one end of the vertical connecting rod 25 away from the center of symmetry, and the fixing block 29 is located below the thread block 26, A communication chamber 35, which opens in the direction of the center of symmetry, is installed in the block 29, the communication chamber 35 extends into the vertical connecting rod 25, and the driving pulley 30 can rotate in the communication chamber 35. The driven pulley 30 is installed rotatably on one side of the driving pulley 30 close to the center of symmetry, and the belt conveyor 32 is connected between the driving pulley 30 and the driven pulley 34. A spline shaft 31 is connected to the driving pulley 30 by a spline, the spline shaft 31 is rotatably connected to the fixed block 29, and the spline shaft 31 is fixed to a circumferential surface of the vertical screw 27. A vertical shaft 33 is fixedly connected to the driven pulley 34, a deceleration chamber 45 is installed in a lower inner wall of the communication chamber 35, and a lower end of the vertical shaft 33 is connected to the vertical shaft 33. A small bevel gear 36 is fixedly connected to the lower end of the vertical shaft 33 so as to extend into the deceleration chamber 45, and a large bevel gear 43 meshes with one end of the small bevel gear 36 close to the center of symmetry. A slow rotation shaft 44 is fixedly connected to one end of the large bevel gear 43 near the center of symmetry, and one end of the slow rotation shaft 44 near the center of symmetry is fixed to the sampling device 100. And the slow rotation shaft 44 can rotate the sampling device 100.

Hereinafter, the sampling device 100 will be described in detail according to an embodiment, and the sampling device 100 includes a water tub 12 rotatably and slidably installed in the river channel 13 and the drain hole 46. The vertical connecting rods 25 on both sides are rotatably connected to the left and right ends of the water tub 12, and the slow rotation shafts 44 on both sides are fixedly connected to the left and right ends of the water tub 12, respectively. A water storage chamber 56 having an upper opening is installed therein so that a water sample can be placed in the water storage chamber 56, and a slide plate 58 is installed in the water storage chamber 56 so as to be slidable. A fixed slider 55 is fixedly connected to the lower end of the slide plate 58, a sealing chamber 57 that opens downward is installed in the fixed slider 55, and a fixed piston 53 is fixed to the lower end of the water storage chamber 56. And an upper end of the fixed piston 53 extends into the sealed chamber 57, and a fixed pressure probe 54 is fixedly connected to the upper end of the fixed piston 53, and the pressure probe 54 is connected to the sealed chamber 57. The atmospheric pressure value in the can be inspected and measured, and the weight of the dust is indicated by the change value of the atmospheric pressure of the sealed chamber 57 which is inspected and measured by the pressure probe 54 before or after the dust is processed.

Advantageously, a transmission chamber 47 is symmetrically installed on the lower inner wall of the water storage chamber 56, and a meshing gear 51 is symmetrically installed in the transmission chamber 47 so as to be rotatable. , The front and rear meshing gears 51 mesh with each other, and one end of the meshing gears 51 on the left and right sides away from the center of symmetry is fixedly connected to the belt winding wheel 50. An electric shaft 52 is fixedly connected between 50, a motor 49 is fixedly installed in the left inner wall of the left transmission chamber 47, and the left end of the front electric shaft 52 is connected to the motor 49. A tension belt 48 is wound around the circumferential surface of the belt winding wheel 50 so as to be able to transmit power, and a belt groove 61 is longitudinally and symmetrically communicated with the upper inner wall of the transmission chamber 47. The storage chamber 63 opened upward is communicated with the upper inner wall of the belt groove 61, and one inner wall of the storage chamber 63 close to the center of symmetry is the water storage chamber. A torsion shaft 64 is rotatably connected between the left and right inner walls of the storage chamber 63 and communicates with the chamber 56, and a torsion ring 65 is symmetrically fixed to the circumferential surface of the torsion shaft 64. The upper end of the tension belt 48 extends into the storage chamber 63 and is wound around the circumferential surface of the twist ring 65, and the filter 14 is wound between the twist shafts 64 on both sides. A sealing block 62 is fixedly installed in the belt groove 61, and the tension belt 48 is slidably connected to the sealing block 62. It is possible to avoid flowing into the groove 61.

As a benefit, a torsion spring 66 is fixedly connected between one end of the twisting ring 65 on the left and right sides away from the center of symmetry and the inner wall on both the left and right sides of the storage chamber 63.

Hereinafter, the auxiliary device 102 will be described in detail with reference to an embodiment. The auxiliary device 102 includes turning chambers 17 symmetrically installed in the pedestal 15, and the upper ends of the long rotation shafts 28 on both sides are respectively arranged. A turning drive gear 60 is fixedly connected to the upper ends of the long rotating shafts 28 on both sides, and extends in the turning chambers 17 on both sides. A turning driven gear 59 is provided on the front side of the turning drive gear 60. The connecting shaft 16 is fixedly connected to the front end of the turning driven gear 59, and the chain winding 18 is fixedly connected to the circumferential surface of the connecting shaft 16 so that the turning chamber 17 is engaged with the turning chamber 17. A directional guide chamber 21 having a downward opening is installed in an inner wall of one side of the symmetric center, and a fixed shaft 23 is rotatably connected between the front and rear inner walls of the directional guide chamber 21. A direction guide wheel 22 is fixedly connected to the circumferential surface of the shaft 23, a chain 19 is connected between the direction guide wheel 22 and the chain winding wheel 18, and a lower end of the chain 19 is the water tank. 12 is fixedly connected.

Advantageously, a directional guide groove 24 is formed in the directional guide wheel 22 and opens in a direction in which the fixed shaft 23 is turned away from the fixed shaft 23. The chain 19 slides along the directional guide groove 24. The direction guide groove 24 prevents the front-back misalignment from occurring when the chain 19 slides.

Hereinafter, the steps of using the marine environment monitoring equipment in the estuary of the present application will be described in detail with reference to FIGS.

In the initial state, the filter 14 is in a loose state, the torsion spring 66 is in a normal state at this time, the vertical connecting rod 25 is in contact with the position limiting switch 20, the thread block 26 is in the upper limit position, and the water storage The tub 12 maintains the vertical state and is in the upper limit position.

The hoisting electric motor 40 is started, the main gear 38 is further rotationally interlocked by the long rotation shaft 28, the driven gear 41 is further rotationally interlocked, the spline shaft 31 is further rotationally interlocked by the vertical screw 27, and the main driving pulley 30 is further rotated. Further, the belt conveyor 32 rotates the driven pulley 34, the vertical shaft 33 rotates the small bevel gear 36, the large bevel gear 43 rotates, and the slow rotation shaft 44 causes the water tank 12 to rotate. The vertical screw 27 interlocks the thread block 26 downwardly, the vertical connecting rod 25 interlocks downwardly, the water tub 12 interlocks downwardly, and the main drive pulley 30 and the spline shaft 31 are connected all the time. When the screw block 26 contacts the fixed block 29 while maintaining the state, the water tub 12 descends to the lower limit position and extends into the river, at which time the hoisting motor 40 is stopped and the water tub 12 is Rotate 90 degrees to start the sampling with the opening of the water storage chamber 56 facing backward, and the filter 14 is interlocked with the water flow to extend into the water storage chamber 56, and the filter 14 collects the debris of the suspended matter in the water. After that, the hoisting motor 40 is rotated in the opposite direction after the water is filled in the water storage chamber 56, and the volume of the sampled water is the same as the volume of the water storage chamber 56. Rotate in a reverse direction in conjunction with each other and raise it, stop the hoisting motor 40 when the vertical connecting rod 25 comes into contact with the position limiting switch 20, and interlock the turning drive gear 60 when the long rotation shaft 28 rotates. In addition, the turning driven gear 59 is rotatably linked, the chain winding wheel 18 is rotatably linked by the connecting shaft 16, the water tub 12 is held by the chain 19, and the water tub 12 can be further elevated and lowered. The water storage tub 12 slides along the direction guide groove 24 due to 19, so that the direction guide groove 24 can be prevented from being displaced in the front and back of the chain 19, and the water storage tub 12 can be further stably moved up and down.

The slide plate 58 is interlocked with the water pressure in the water storage chamber 56, the fixed slider 55 is further slid, the gas in the sealed chamber 57 is further compressed, and the air pressure in the sealed chamber 57 is increased. Monitors and measures the atmospheric pressure in the sealed chamber 57 in real time, at this time, the motor 49 is started, and further, the two electric gears 52 on the front side are rotatably interlocked with each other, so that the front engagement gear 51 moves rearward. , The meshing gears 51 on the front and rear sides rotate in opposite directions. The meshing gears 51 rotate the belt winding wheel 50, and the tension belt 48 rotates the twisting wheel 65. Further, the torsion shaft 66 is twisted by rotating the torsion shaft 64, the filter 14 is further wound, and the filter 14 further takes out the dust from the water storage chamber 56 and separates it from the water. At this time, the dust can be treated, and the sealing block 62 is Water is prevented from entering the belt groove 61, and after the dust is separated from the water at this time, the pressure received by the slide plate 58 becomes small, and the pressure of the gas in the sealed chamber 57 at this time causes the slide plate to move. 58 and the fixed slider 55 are moved up and down, the atmospheric pressure in the sealed chamber 57 is further lowered, and the weight of marine debris having the same volume as the volume of the water storage chamber 56 is shown by the change value of the atmospheric pressure in the sealed chamber 57. When the weight of garbage is too heavy, it is necessary to control the discharge of garbage on the river manually.

The beneficial effects of the present invention are: The present invention is installed at the mouth of a river and can measure the weight of suspended solids in a certain volume of water in a river. It is necessary to control the discharge of trash on the river, the trash can be treated from the river, and a large amount of trash is not discharged to the sea.

The above scheme allows one skilled in the art to make various changes based on the operating mode within the scope of the present invention.

Claims (8)

In front view, including the coast,
A channel that opens upward is installed in the coast, water in the channel flows forward, and a sampling device is installed in the channel so that the sampling device can move and rotate. The device is capable of inspecting and measuring the weight of waste by taking a sample of water from the channel, and the sampling device is capable of separating the waste from the water,
A load base is fixedly connected to an upper end of the shore, a pedestal is fixedly connected to an upper end of the load base, and a vent hole is installed in the load base so as to vertically pass therethrough. A vent hole faces the channel, the sampling device is located in the vent hole,
A rotary lifting device is connected between the load base and the gantry, the rotary lifting device is rotatably connected to the sampling device, and the sampling device is driven to rotate the sampling device in conjunction with each other. It can be lifted and lowered, the sampling device has a rotation range of 90 degrees, which makes the sampling device convenient for taking water samples, and an auxiliary device is rotatably connected to the upper end of the rotary lifting device. The auxiliary device can assist the rotary lifting device to move the sampling device up and down, and stabilize the lifting of the sampling device.
A position limiting switch is symmetrically and fixedly connected to the lower end of the gantry, and the position limiting switch is connected so that the rotary lifting device can be energized, and the position limiting switch activates the rotary lifting device. Marine environment monitoring equipment in the estuary, characterized by the ability to control stop and stop. The rotary lifting device includes gear chambers symmetrically installed in the inner walls on both left and right sides of the hole, and a driving gear is rotatably installed in the gear chamber. A rotating shaft is fixedly installed, an upper end of the long rotating shaft is connected to the auxiliary device, a hoisting motor is fixedly installed in a lower inner wall of the gear chamber, and the hoisting motors on both sides are installed. The position limiting switches on both sides are connected to each other so that they can be energized, and the lower end of the long rotation shaft is connected to transmit power to the hoisting motor.
A driven gear is installed so as to mesh with one end of the main driving gear close to the center of symmetry, and a vertical screw is fixedly connected to the driven gear so that the upper end of the vertical screw can rotate on the gantry. And a slidable thread block is connected to the circumferential surface of the vertical screw by a screw thread, and a vertical connecting rod is fixedly connected to one end of the screw thread block near the center of symmetry. The marine environment monitoring facility in the estuary according to claim 1, wherein a connecting rod is rotatably connected to the sampling device. A fixed block is fixedly connected to one end of the vertical connecting rod away from the center of symmetry, and the fixed block is located below the thread block. A communication chamber having an opening is installed, the communication chamber extends into the vertical connecting rod, and a driving pulley is rotatably installed in the communication chamber and is close to the center of symmetry of the driving pulley. A driven pulley is rotatably installed on one side, a belt conveyor is connected between the main driving pulley and the driven pulley, and a spline shaft is connected by a spline in the main driving pulley. Rotatably connected to the fixed block, the spline shaft is fixedly connected to the circumferential surface of the vertical screw,
A vertical shaft is fixedly connected to the driven pulley, a deceleration chamber is installed in a lower inner wall of the communication chamber, and a lower end of the vertical shaft extends into the deceleration chamber. A small bevel gear is fixedly connected to the lower end of the vertical shaft, and a large bevel gear is installed so as to mesh with one end of the small bevel gear that is close to the center of symmetry. 3. The estuary region according to claim 2, wherein the slow rotation shaft is fixedly connected, and one end of the slow rotation shaft near the center of symmetry is fixedly connected to the sampling device. Environment monitoring equipment in Japan. The sampling device includes a water tub rotatably and slidably installed in the river channel and the drainage hole, and the vertical connecting rods on both sides are rotatably connected to left and right ends of the water tub. , The slow rotation shafts on both sides are fixedly connected to the left and right ends of the water tank,
A water storage chamber having an upper opening is installed in the water storage tub, a water sample can be placed in the water storage chamber, and a slide plate is slidably installed in the water storage chamber. A fixed slider is fixedly connected to the lower end of the slide plate, a sealing chamber opening downward is installed in the fixed slider, and a fixed piston is fixedly connected to the lower end of the water storage chamber. the upper end of the piston extends into the sealing chamber and the upper end of the fixed piston pressure probe is fixedly connected, characterized in that the pressure probes may test measures the pressure value in the sealed chamber The marine environment monitoring equipment in the estuary according to claim 2 . Transmission chambers are installed symmetrically on the lower inner wall of the water storage chamber, and meshing gears are installed in the transmission chambers so as to be symmetrical in the front-rear direction and rotatable, and between the front and rear meshing gears. The belt winding wheel is fixedly connected to one end of the meshing gears on the left and right sides apart from the center of symmetry, and the electric shaft is fixedly connected between the belt winding wheels on the left and right sides. A motor is fixedly installed in the left inner wall of the transmission chamber on the left side, and a left end of the electric shaft on the front side is connected to the motor so that power can be transmitted to the motor. The tension belt is wrapped around,
A belt groove is formed in the upper inner wall of the transmission chamber so as to be symmetrical with respect to the front-rear direction and is connected to the upper inner wall of the belt groove. One inner wall of the storage chamber, which is close to the center of symmetry, communicates with the water storage chamber, and a torsion shaft is rotatably connected between the left and right inner walls of the storage chamber. A twist ring is fixedly connected to the surface in a symmetrically fixed manner, the upper end of the tension belt extends into the storage chamber, and is wound around the circumferential surface of the twist ring. A filter is wound around the space, a sealing block is fixedly installed in the belt groove, and the tension belt is slidably connected to the sealing block. The marine environment monitoring facility in the estuary according to claim 4. The estuary region according to claim 5, wherein a torsion spring is fixedly connected between one end of each of the twisted rings on the left and right sides apart from the center of symmetry and the inner wall on both the left and right sides of the storage chamber. Environment monitoring equipment in Japan. The auxiliary device includes turning chambers symmetrically installed in the mount, the upper ends of the long rotation shafts on both sides extend into the turning chambers on both sides, and the long rotation shafts on both sides. A turning drive gear is fixedly connected to an upper end of the turning drive gear, a turning driven gear is installed to mesh with the front side of the turning drive gear, and a connecting shaft is fixedly connected to a front end of the turning drive gear. A chain winding is fixedly connected to the circumferential surface of the connecting shaft, and a direction guide chamber that opens downward is installed in the inner wall of one side of the turning chamber that is close to the center of symmetry. A fixed shaft is rotatably connected between the front and rear inner walls, and a directional guide wheel is fixedly connected to a circumferential surface of the fixed shaft, and a chain is provided between the directional guide wheel and the chain winding wheel. The marine environment monitoring equipment in the estuary area according to claim 4 , wherein the lower end of the chain is fixedly connected to the water tank. The marine environment monitoring equipment in the estuary area according to claim 7, wherein a directional guide groove is formed in the directional guide wheel, the directional guide groove being opened in a direction in which the back is turned to the fixed shaft.

Images