JP2021028463A - Water quality monitoring pre-processing device for river and lake - Google Patents

Abstract

To provide a quality monitoring pre-processing device for rivers and lakes in accordance with the present invention.SOLUTION: A quality monitoring pre-processing device for rivers and lakes includes a buoyancy tank, in the buoyancy tank being arranged a filtering space opening upward, in the filtering space being arranged a turnoverable filter component. The filter component includes centrosymmetric four fixed pins arranged in the filtering space, filter plates slidably connected in the filtering space and symmetrically arranged in a vertical direction, and slide grooves symmetrically formed in a front-rear direction in the filtering plates and slidably connected to the fixed pins. The filtering plates are able to rotate along the fixed pines as rotation centers the fixed pins and the filtering plates are not on the same horizontal line.SELECTED DRAWING: Figure 1

Description

The present invention takes up the field of pretreatment technology for water quality monitoring, and specifically is a water quality monitoring pretreatment facility for rivers and lakes.

Recently, water quality inspection has become more important as awareness of environmental protection has increased. In order to know the water quality of rivers in a timely manner, China has set up more and more water quality inspection stations in each river and lake. The water quality inspection station inspects changes in the quality of the water environment and pollution status, and provides important information for the protection and management of the water environment and the prevention and maintenance of water pollution.
However, since each water quality inspection station is far from each other and the distance between each place where samples are taken is also long, a considerable amount of monitoring equipment is installed on the buoy. In addition, because the speed of the water flow in the river is high, the water flow moves from mud and aquatic plants in the river to garbage. Therefore, it is necessary to pretreat before taking a sample of the water source. With the conventional filter processing method, the filter may be blocked by impurities and dust after a long period of time. The present invention can solve the above problems.

Publication of Chinese Patent Application No. 108426836

Technical problem: Conventional water quality sampling pretreatment equipment generally uses a filter, and after a long period of time, the filter is blocked with impurities and dust, which affects the purpose of sampling and monitoring.

To solve the above problems, the present invention employs the following technical plan: the water quality monitoring pretreatment facility for rivers and lakes includes a float, which contains an upwardly open filtration space. A reversible filter component is provided in the filtration space so that the filter component can slide into the filtration space with four fixing pins provided centrally symmetrically in the filtration space. A filter plate connected to and vertically symmetrically provided, and a slide groove formed symmetrically in the filter plate and connected so as to be slidable with the fixing pin, and rotation of the fixing pin and the filter plate. Since the centers are not the same horizontal line, the filter plate can be rotated along the fixing pin, a drive device for controlling the filter component is fixed to the right end surface of the filter space, and the drive device is the filter space. A drive box installed on the right end surface of the drive box, a transmission space installed in the drive box, a slide passage installed so as to communicate with the transmission space and vertically symmetrically provided, and the slide passage. A synchronous slidable connection can be achieved by a slide rod connected so as to slide into the inside, and a isolation pipe is fixedly provided on the inner wall of the apex of the filtration space, and the isolation pipe is contained in the isolation pipe. An elevating space connected so as to communicate with the filtration space is provided, and the elevating device is connected so as to be slidable in the elevating space, and the pulling device is connected to the left side so as to be slidable in the filtration space. A water sample can be taken by a pull-up pipe opened to, a rope system for controlling the pull-up device is provided at the outer end of the isolation pipe, and the rope system is a support installed on the left end surface of the elevating space. Power can be transmitted by the frame, the guide roll fixedly connected to the support frame, and the wire rope connected so as to slide to the guide roll, and the water quality is simply analyzed on the right inner wall of the elevating space. An analysis module that can be used is fitted.

As an excellent technical plan, an anchor is fixedly provided on the lower end surface of the filtration space.

As an excellent technical plan, the filtration plate has a double filter structure.

As a technical plan of choice, the filter component includes four moving grooves formed centrally symmetrically on the inner wall of the filtration space, and a pull rod fixedly connected to the slide rod is provided on the right inner wall of the moving groove. It is slidably connected and the pull rod is connected to the filter plate by a hinge.

As a technical plan of choice, the drive device includes a sealed space provided at the left end of the transmission space, and the slide rod and a screw rod connected by a thread are connected so as to be rotatable in the transmission space. , The left end of the screw rod is connected so that the motor can be transmitted.

As a preferred technical plan, the motor is located in the sealed space.

As a preferred technical plan, the pulling device includes a rotatably connected transmission shaft to the upper end of the pulling pipe, the transmission shaft is rotatably connected to the connecting box, and the connecting box is contained therein. A rotation space is provided, and the transmission shaft is provided with a rotation rod located in the rotation space and fixedly connected to the wire rope, and is provided between the rotation rod and the inner wall at the bottom end of the rotation space. A torsion spring is connected to the shaft, a spiral groove is formed in the rotating space so as to slide with the rotating rod, and a track board located at the lower end of the connecting box can rotate on the transmission shaft. The transmission shaft is provided with a return board located at the lower end of the track board, and the return board is connected to the return board so that the hook rod in contact with the track board can slide, and is connected to the hook rod. A resistance spring is connected to the upper end surface of the return plate.

As a technical plan of choice, an annular groove having a serrated shape is formed at the bottom on the upper end surface of the pull-up pipe, and the annular groove can be connected so as to be in contact with the hooking rod.

As a preferred technical plan, the rope system includes a support rod fixedly connected to the right end face of the elevating space so that the support rod can rotate a reel fixedly connected to the right end of the wire rope. The support rod is provided with a gear located at the rear end of the reel, and the gear is connected so as to mesh with the pull rod on the upper side.

The present invention encloses the sample by a sleeve type, guarantees that the sample is filtered and pretreated water by rotating the opening left and right, guarantees the science of information processing and reception, and is contaminated with impurities and debris. Preventing the effect, the difference in height between the turning point and the pulling point causes the filter to turn and slide at the turning point, and the dust on the filter can be removed, and the dust blocks the filter after a long time. While preventing the problem and realizing a sustainable work method, the regular processing of human power has been reduced.

In order to explain the invention of the present application in detail with reference to FIGS. 1 to 4 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 is described above and below. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic diagram of the overall configuration of the present invention. FIG. 2 is a schematic configuration diagram in the AA direction of FIG. FIG. 3 is a schematic configuration diagram in the BB direction of FIG. FIG. 4 is a schematic configuration of the slide rod of FIG.

The present invention is mainly applied to water quality monitoring pretreatment work in a fluid water area, and the present invention will be described in detail below with reference to the accompanying drawings of the present invention.

The water quality monitoring pretreatment facility for rivers and lakes includes a floating box 11, and a filtration space 12 open upward is provided in the floating box 11, and a filter that can be turned around is provided in the filtration space 12. A component 901 is provided, and the filter component 901 is vertically symmetrically connected to four fixing pins 15 provided centrally symmetrically in the filtration space 12 so as to be slidable in the filtration space 12. The filter plate 13 and the slide groove 14 formed symmetrically in the filter plate 13 and connected to the fixing pin 15 so as to be slidable are included, and the rotation center of the fixing pin 15 and the filtration plate 13 is included. Is not the same horizontal line, so that the filtration plate 13 can be rotated along the fixing pin 15, and a drive device 902 that controls the filter component 901 is fixed to the right end surface of the filtration space 12, and the drive device 902 is fixed. The 902 is installed so as to communicate with the drive box 25 installed on the right end surface of the filtration space 12, the transmission space 24 installed in the drive box 25, and the transmission space 24, and is vertically symmetrical. A synchronous slideable connection can be realized by the slide passage 23 provided and the slide rod 26 connected so as to be slidable in the slide passage 23, and the isolation pipe 35 is provided on the inner wall of the apex of the filtration space 12. Is fixedly provided, and an elevating space 34 connected so as to communicate with the filtration space 12 is provided in the isolation pipe 35 so that the elevating device 903 can slide in the elevating space 34. The pulling device 903 is connected, and the water sample can be taken by the pulling pipe 18 opened to the left connected so as to slide into the filtration space 12, and the pulling device is attached to the outer end of the isolation pipe 35. A rope system 904 for controlling the 903 is provided, and the rope system 904 includes a support frame 38 installed on the left end surface of the elevating space 34, a guide roll 37 fixedly connected to the support frame 38, and the guide. An analysis module 31 that can transmit power by a wire rope 36 that is slidably connected to the roll 37 and that can easily analyze the water quality is fitted on the inner wall on the right side of the elevating space 34.

Beneficially, an anchor 17 is fixedly provided on the lower end surface of the filtration space 12, and the invention is fixed in one place by the anchor 17.

Advantageously, the filter plate 13 has a double filter structure, so that impurities in the water sample can be completely removed.

The filter component 901 includes four moving grooves 16 formed symmetrically on the inner wall of the filtration space 12, and a pull rod 19 fixedly connected to the slide rod 26 is provided on the right inner wall of the moving groove 16. It is slidably connected, and the pull rod 19 is connected to the filter plate 13 by a hinge.

The drive device 902 includes a sealed space 21 provided at the left end of the transmission space 24, and a screw rod 22 connected to the slide rod 26 by a screw thread is rotatably connected in the transmission space 24. , The motor 20 is connected to the left terminal end of the screw rod 22 so as to be able to transmit.

Beneficially, the motor 20 is located in the sealed space 21 and is protected by the independently sealed sealed space 21 without the motor 20 getting wet.

The pulling device 903 includes a transmission shaft 42 rotatably connected to the upper end of the pulling pipe 18, and the connecting box 33 is rotatably connected to the transmission shaft 42, and the connecting box 33 is contained in the connecting box 33. A rotation space 32 is provided, and the transmission shaft 42 is provided with a rotation rod 40 located in the rotation space 32 and fixedly connected to the wire rope 36, and the rotation rod 40 and the rotation space 32 are provided. A torsion spring 41 is connected to the inner wall at the bottom end of the shaft, and a spiral groove 39 connected to the rotating rod 40 so as to be slidable is formed in the rotating space 32. The track board 43 located at the lower end of the connecting box 33 is connected so as to be rotatable, the transmission shaft 42 is provided with a return board 45 located at the lower end of the track board 43, and the return board 45 is provided with the track board 45. The hooking rod 46 in contact with the 43 is connected so as to be slidable, and the resistance spring 44 is connected between the hooking rod 46 and the upper end surface of the return plate 45.

Beneficially, an annular groove 27 having a serrated shape is formed on the upper end surface of the pulling pipe 18, and the annular groove 27 can be connected so as to be in contact with the hook rod 46, and the hook rod 46 and the annular groove can be connected. The pull-up pipe 18 is rotated by the contact relationship between 27, and one end of the opening is brought into contact with the wall surface.

The rope system 904 includes a support rod 28 fixedly connected to the right end surface of the elevating space 34 so that the support rod 28 can rotate a reel 29 fixedly connected to the right end of the wire rope 36. The support rod 28 is provided with a gear 30 located at the rear end of the reel 29, and the gear 30 is connected so as to mesh with the pull rod 19 on the upper side, and the synchronous operation of the present invention is performed. To realize.

The procedure for using the present invention will be described in detail below with reference to FIGS.
In the initial state, the pull-up pipe 18 is located in the filtration space 12, the rotary rod 40 is located at the lowermost end of the spiral groove 39, the slide rod 26 is located at the leftmost end of the slide passage 23, and the pull rod 19 The hinge point between the filter plate 13 and the filter plate 13 is located on the same vertical line as the fixing pin 15, and the filter plate 13 closes the opening of the filtration space 12.
When both water and impurities in the water enter the inside of the filtration space 12 from left to right, the filter plate 13 filters and samples the water, the motor 20 is activated, and the screw rod 22 drives the slide rod 26 to the right. The power is moved to the right through the slide rod 26 and the pull rod 19 in order to pull the filter plate 13, and the filter plate 13 is rotated along the fixing pin 15 by the slide of the slide groove 14 and the fixing pin 15 to the right. It slides, and at this time, the dust on the filter plate 13 comes into contact with the inner walls of the upper and lower ends of the floating box 11 to be scraped off and washed away by water, preventing the filter from being blocked, and in this process, the upper pull rod. 19 rotates the gear 30 by meshing, thereby rotating the reel 29 with the support rod 28, pulling the wire rope 36, changing the direction in which the force is applied by the guide roll 37, and moving the rotary rod 40 in the spiral groove 39. The torsion spring 41 is rotated to store elastic position energy, and the rotating rod 40 rotates the return plate 45 by the transmission shaft 42. At this time, the hooking rod 46 is located in the annular groove 27 and the pulling pipe 18 is pushed and moved. Then, the return plate 45 rotates half a circumference, the catching rod 46 is separated from the contact state with the annular groove 27 by the elastic recovery of the resistance spring 44, and the pull-up pipe 18 stops rotating. When the rotary rod 40 slides to the top end of the spiral groove 39, the connecting box 33 is moved upward by the limitation of the inner wall of the spiral groove 39, the pulling pipe 18 is moved upward by the transmission shaft 42, and the water sample is analyzed by the analysis module. Contact 31 and analyze the data.

According to the above method, those skilled in the art can make various changes depending on the working method within the scope of the present invention.

Claims (9)

A floating box is included, a filtration space open upward is provided in the floating box, a filter component that can be turned over is provided in the filtration space, and the filter component is centered in the filtration space. Four fixing pins provided symmetrically, a filtration plate connected so as to be slidable in the filtration space and vertically symmetrically provided, and a filtration plate formed symmetrically in the filtration plate and slidable with the fixing pin. Since the fixing pin and the center of rotation of the filter plate are not on the same horizontal line, the filter plate can be rotated along the fixing pin, and the right end surface of the filtration space includes the slide groove connected in the above manner. A drive device that controls the filter component is fixed, and the drive device communicates with a drive box installed on the right end surface of the filtration space, a transmission space installed in the drive box, and the transmission space. A synchronous slidable connection can be realized by the slide passages installed so as to be slid and vertically symmetrically provided and the slide rods connected so as to be slidable in the slide passages, and the inner wall at the apex of the filtration space. Is provided with a fixed isolation pipe, an elevating space connected to the filtration space is provided in the isolation pipe, and the elevating space is connected so that the lifting device can slide. A rope system that controls the pulling device at the outer end of the isolation tube, where the pulling device can take a water sample by a pulling tube that opens to the left and is connected to slide into the filtration space. Is provided, and the rope system includes a support frame installed on the left end surface of the elevating space, a guide roll fixedly connected to the support frame, and a wire rope connected so as to slide on the guide roll. A water quality monitoring pretreatment facility for rivers and lakes, characterized in that an analysis module capable of transmitting power and simply analyzing water quality is fitted on the inner wall on the right side of the elevating space. The water quality monitoring pretreatment facility for rivers and lakes according to claim 1, wherein an anchor is fixedly provided on the lower end surface of the filtration space. The water quality monitoring pretreatment facility for rivers and lakes according to claim 1, wherein the filter plate has a double filter structure. The filter component includes four moving grooves formed centrally symmetrically on the inner wall of the filtration space, and a pull rod fixedly connected to the slide rod is connected to the inner wall on the right side of the moving groove so as to slide. The water quality monitoring pretreatment facility for rivers and lakes according to claim 1, wherein the pull rod is connected to the filter plate by a hinge. The drive device includes a sealed space provided at the left end of the transmission space, and a screw rod connected to the slide rod by a screw thread is rotatably connected in the transmission space, and the left end of the screw rod is connected. The water quality monitoring pretreatment facility for rivers and lakes according to claim 1, wherein a motor is connected to the end so that the motor can be transmitted. The water quality monitoring pretreatment facility for rivers and lakes according to claim 5, wherein the motor is located in the sealed space. The pulling device includes a transmission shaft rotatably connected to the upper end of the pulling pipe, and the connecting box is rotatably connected to the transmission shaft, and a rotating space is provided in the connecting box. The transmission shaft is provided with a rotating rod located in the rotating space and fixedly connected to the wire rope, and a torsion spring is connected between the rotating rod and the inner wall at the bottom end of the rotating space. A spiral groove is formed in the rotating space so as to be slidable with the rotating rod, and a track board located at the lower end of the connecting box is connected to the transmission shaft so as to be rotatable. A return board located at the lower end of the track board is provided on the transmission shaft, and the hook rod in contact with the track board is connected to the return board so as to slide, and the hook rod and the upper end surface of the return board are connected. The water quality monitoring pretreatment facility for rivers and lakes according to claim 1, wherein a resistance spring is connected between the two. The water quality for rivers and lakes according to claim 7, wherein an annular groove having a serrated shape is formed at the bottom on the upper end surface of the pulling pipe, and the annular groove can be connected so as to be in contact with the hook rod. Monitoring pretreatment equipment. The rope system includes a support rod fixedly connected to the right end face of the elevating space, and the support rod is connected to the support rod so that a reel fixedly connected to the right end of the wire rope can rotate. The water quality for rivers and lakes according to claim 4, wherein the rod is provided with a gear located at the rear end of the reel, and the gear is connected so as to mesh with the pull rod on the upper side. Monitoring pretreatment equipment.

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