CN117074097B - Treatment device for water distribution of rotating arm - Google Patents

Abstract

The invention relates to the technical field of detection equipment, in particular to a rotary arm water distribution treatment device which comprises a sampling platform, a water distribution barrel and a water supply unit, wherein the sampling platform is placed at a sampling position when a water source is sampled and detected, the sampling platform can float on the water surface, a plurality of sample reserving bottles are placed in a sampling box of the sampling platform, each sample reserving bottle is used as a detection sample, and the detection accuracy can be improved by detecting sample water samples in the sample reserving bottles. When water is distributed to the inside of the sample reserving bottle, the water supply unit is firstly used for supplying water to the water distribution barrel, the water distribution barrel can rotate in the sampling box, the suction pipe in the water distribution barrel is used for supplying water in the water distribution barrel to the water distribution pipe, the water distribution pipe is prevented from being bent when the water distribution barrel rotates, and stable water distribution in the sample reserving bottle is ensured.

Description

Treatment device for water distribution of rotating arm

Technical Field

The invention relates to the technical field of detection equipment, in particular to a treatment device for rotating arm water distribution.

Background

When the water source is detected, water with different depths in the water source is sampled by means of sampling equipment, so that the detection accuracy is ensured. The conventional sampling equipment generally uses the equal proportion water distribution equipment, the water distribution equipment must have the bottle separation and sample reserving function, the conventional water distribution equipment has 24 sample reserving bottles, the sample reserving bottles enclose a circle, a rocker arm rod is placed on a central shaft, a bottle number is selected through rotating the rocker arm rod, a suction pipe is generally adopted to bind the rocker arm rod at present, after the rocker arm rod reaches a designated bottle position, suction pipe drainage enters the sample reserving bottle, the rocker arm can only rotate 180 degrees in one direction in this way, and bending and knotting of the suction pipe are easily caused to influence the water distribution equipment to distribute water in excess of 180 degrees. Meanwhile, when water with different layer depths is obtained, flowing water can influence water distribution equipment, so that water collected by the water distribution equipment is not a water source with the same layer depth, and an obtained water source sample is impure, and therefore the detection result of the water source is influenced.

Disclosure of Invention

The invention provides a treatment device for rotating arm water distribution, which aims to solve the problem that the existing water distribution equipment is unstable in water distribution into a sample reserving bottle.

The invention relates to a treatment device for rotating arm water distribution, which adopts the following technical scheme:

a processing device for rotating arm water distribution comprises a sampling platform, a water distribution barrel and a water supply unit.

The sampling platform can float on the water surface, the sampling platform is provided with a sampling box, the inside of the sampling box is hollow, a plurality of sample reserving bottles are placed in the sampling box, and the plurality of sample reserving bottles are uniformly distributed around the circumference of the inside of the sampling box; the sampling platform is provided with a plurality of leveling cylinders which are uniformly distributed around the circumference of the sampling box, and when any one sample reserving bottle is used for water inflow, the corresponding leveling cylinders are always used for water inflow; the water distribution barrel is coaxially arranged in the sampling box in a rotating way, the water distribution barrel is hollow, a water distribution pipe is fixedly arranged on the water distribution barrel, a suction pipe is arranged in the water distribution barrel and can be inserted into the water distribution pipe, a water suction pump is arranged on the suction pipe, and the water suction pump can suck water in the water distribution barrel into the suction pipe; the water supply unit is used for supplying water to the inside of the water distribution barrel.

Further, the water supply unit includes a guide bar, a supply block, and a supply pipe; the guide rod is vertically arranged below the sampling platform; the feeding block is arranged in a sliding way up and down along the guide rod, the inside of the feeding block is hollow, the feeding block is provided with a water supply pump, and when the feeding block and the flowing water flow are relatively static, the water supply pump on the feeding block is started; the supply pipe can stretch out and draw back the setting, and the one end intercommunication of supply pipe is joined in marriage the cask, and the other end intercommunication of supply pipe is supplied the piece.

Further, the water supply unit further comprises a supply disc and a driving ring, the supply disc is arranged in a sliding mode up and down along the guide rod, and the supply disc is arranged in parallel with the sampling platform; the driving ring is rotatably arranged on the feeding disc, and the feeding block is arranged on the driving ring; the first driving unit is arranged on the supply disc and is used for driving the driving ring to rotate.

Further, the supply pipe is divided into a main pipe and a branch pipe, the main pipe is vertically arranged in a telescopic manner, the upper end of the main pipe is communicated with the water distribution barrel, the lower end of the main pipe is provided with a rotating sleeve, the interior of the rotating sleeve is hollow, and the interior of the rotating sleeve is communicated with the main pipe; the branch pipe can stretch out and draw back the setting, and the one end intercommunication that is branched the pipe rotates the cover, and the other end intercommunication that is branched the pipe supplies with the piece.

Further, a plurality of supply blocks are arranged on the driving ring, the supply blocks are uniformly distributed around the circumference of the driving ring, a water supply pump is arranged on each supply block, and a branch pipe is connected between each supply block and the rotating sleeve.

Further, set up the traction block between supply disc and the sampling platform, the traction block can slide the setting from top to bottom along the guide bar, and the traction block is used for connecting boats and ships.

Further, a guide disc is arranged in the sampling box, a plurality of positioning holes penetrating up and down are formed in the guide disc, the positioning holes are uniformly distributed around the circumference of the guide disc, and each sample reserving bottle passes through one positioning hole to be arranged; the middle part of the guide disc is provided with a first through hole, and the water distribution pipe passes through the first through hole.

Further, the upper end face of the guide disc is raised in the middle, the side wall of the sampling box is provided with a drain hole penetrating inside and outside, and the drain hole and the edge of the upper end face of the guide disc are located on the same plane.

Further, an inclination sensor is arranged on the sampling platform and is used for detecting an included angle between the sampling platform and the horizontal plane; be provided with first control panel on the sampling platform, first control panel can receive inclination sensor's detection data, and first control panel can control the position of traction block on the guide bar according to inclination sensor's detection data.

Further, a flow rate detector is arranged on the supply disc, and the flow rate detector is used for detecting the flow rate of water; the supply disc is provided with a second control board, the second control board can receive detection data of the flow rate detector, and the second control board can control the speed at which the first driving unit drives the driving ring to rotate according to the detection data of the flow rate detector.

The beneficial effects of the invention are as follows: the invention relates to a processing device for rotating arm water distribution, which comprises a sampling platform, a water distribution barrel and a water supply unit, wherein the sampling platform is placed at a sampling position when a water source is sampled and detected, the sampling platform can float on the water surface, a plurality of sample reserving bottles are placed in a sampling box of the sampling platform, each sample reserving bottle is used as a detection sample, and the detection accuracy can be improved by detecting sample water samples in the sample reserving bottles. When water is distributed to the inside of the sample reserving bottle, the water supply unit is firstly used for supplying water to the water distribution barrel, the water distribution barrel can rotate in the sampling box, the suction pipe in the water distribution barrel is used for supplying water in the water distribution barrel to the water distribution pipe, the water distribution pipe is prevented from being bent when the water distribution barrel rotates, and stable water distribution in the sample reserving bottle is ensured.

Further, the water supply unit is used for obtaining water with different layer depths, meanwhile, when the supply block and flowing water flow are relatively static, the water supply pump on the supply block is started, the water can be pumped into the water distribution barrel only when the water supply pump is started, the water entering the water supply pump is relatively pure due to the fact that the water flow and the water supply block are relatively static, and the accuracy of water source detection is improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a rotary arm water distribution treatment device according to an embodiment of the present invention;

fig. 2 is a cross-sectional view of a rotary arm water distribution treatment device according to an embodiment of the present invention;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is a partial enlarged view at B in FIG. 2;

FIG. 5 is a cross-sectional view of a sampling platform, a sampling box, a water distribution barrel, etc. in a rotary arm water distribution treatment device according to an embodiment of the present invention;

fig. 6 is a cross-sectional view of a traction block in a rotary arm water distribution treatment device according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a supply tray, a supply block, etc. in a rotary arm water distribution treatment device according to an embodiment of the present invention;

FIG. 8 is a cross-sectional view of the structure of FIG. 7;

fig. 9 is a schematic structural view of a feeding block in a rotary arm water distribution treatment device according to an embodiment of the present invention;

fig. 10 is a cross-sectional view of a sampling platform, a sampling box, a leveling cylinder, a guide disc, etc. in a rotary arm water distribution treatment device according to an embodiment of the present invention.

In the figure: 110. a sampling platform; 120. sampling box; 121. a sampling cavity; 130. reserving a sample bottle; 140. leveling cylinder; 141. a water pump; 150. a water distribution barrel; 160. a water distribution pipe; 170. a suction pipe; 171. a water suction pump; 180. a first motor; 190. a first gear; 210. a guide rod; 220. a supply tray; 230. a drive ring; 240. a supply block; 250. a water supply pump; 260. a fourth motor; 280. a first drive sleeve; 290. a second motor; 310. a supply pipe; 311. a main pipe; 312. a branch pipe; 320. a traction block; 330. a second drive sleeve; 340. a third motor; 410. a guide plate; 420. and a drain hole.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The numbering of components herein, such as "first," "second," etc., is used merely to distinguish between the described objects and does not have any sequential or technical meaning. The terms "coupled" and "connected," as used herein, are intended to encompass both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the present invention, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature "above," "over" and "on" a second feature may be a first feature directly above or obliquely above the second feature, or simply indicate that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

As shown in fig. 1 to 10, the rotary arm water distribution treatment device provided by the embodiment of the invention comprises a sampling platform 110, a water distribution barrel 150 and a water supply unit.

The sampling platform 110 can float on the surface of water, and sampling platform 110 has upper surface and lower surface, is provided with sampling box 120 on the upper surface of sampling platform 110, and sampling box 120 is cylindric, and sampling box 120 inside cavity, sampling box 120 inside middle part's cavity are sampling cavity 121, and sampling box 120's inside wall is cylindric. The sampling box 120 is internally provided with a plurality of sample reserving bottles 130, the sample reserving bottles 130 are uniformly distributed in the inner circumference of the sampling cavity 121, the opening of each sample reserving bottle 130 faces upwards, the sample reserving bottles 130 encircle the sampling cavity 121 to form a ring, and the ring formed by encircling the sample reserving bottles 130 is coaxial with the sampling cavity 121. The upper end face of the sampling platform 110 is provided with a plurality of leveling cylinders 140, the leveling cylinders 140 are uniformly distributed around the circumference of the sampling box 120, the leveling cylinders 140 encircle the sampling platform 110 to form a ring, the ring formed by encircling the leveling cylinders 140 is coaxial with the ring formed by encircling the sample reserving bottles 130, and when any one sample reserving bottle 130 is filled with water, the corresponding leveling cylinder 140 is always filled with water, so that the sampling platform 110 can stably float on the water surface. Specifically, a water inlet penetrating through the inside and the outside is formed in the leveling cylinder 140, a water pump 141 is arranged at the water inlet, the water pump 141 can pump water into the leveling cylinder 140, the water in the leveling cylinder 140 can be pumped out by the water pump 141, when water enters any one sample reserving bottle 130, the water always enters the leveling cylinder 140 at the same time, the sample reserving bottle 130 entering the water and the leveling cylinder 140 entering the water are in the same straight line, and the connecting line between the sample reserving bottle 130 entering the water and the leveling cylinder 140 entering the water is over-sampled on the axis of the sampling box 120.

The water distribution barrel 150 is coaxially and rotatably arranged inside the sampling box 120, the water distribution barrel 150 is hollow, a hollow cavity inside the water distribution barrel 150 is a water distribution cavity, a water distribution pipe 160 is fixedly arranged at the upper end of the water distribution barrel 150, the water distribution pipe 160 is communicated with the water distribution cavity, a suction pipe 170 is arranged in the water distribution cavity, one end of the suction pipe 170 is positioned at the lower end of the water distribution cavity, the other end of the suction pipe 170 is inserted into the water distribution pipe 160, a water suction pump 171 is arranged on the suction pipe 170, and the water suction pump 171 can pump water in the water distribution barrel 150 into the water distribution pipe 160 through the suction pipe 170. The sampling cavity 121 is internally provided with a first motor 180, the outer side of the water distribution barrel 150 is coaxially and fixedly sleeved with a first gear 190, a power output shaft of the first motor 180 is fixedly provided with a second gear, the second gear is meshed with the first gear 190, when the first motor 180 is started, the water distribution barrel 150 rotates, and when water is distributed in the sample retention bottle 130, the first motor 180 is intermittently started.

The water supply unit serves to supply water to the inside of the water tub 150. Specifically, the water supply unit includes a guide bar 210, a supply block 240, a supply pipe 310, a supply tray 220, and a driving ring 230; the guide rods 210 are vertically arranged below the sampling platform 110, two guide rods 210 are arranged, and two guide rods 210 are arranged at intervals. The feeding tray 220 is horizontally disposed below the sampling platform 110, and the feeding tray 220 is disposed along the guide rod 210 in a sliding manner, and an upper end surface of the feeding tray 220 is provided with an upward opening ring groove. The driving ring 230 is installed in the ring groove, and the driving ring 230 can rotate in the ring groove. The supply block 240 is fixedly mounted on the driving ring 230, the inside of the supply block 240 is hollow, the side wall of the supply block 240 is provided with a mounting hole penetrating inside and outside, a water supply pump 250 is arranged in the mounting hole, and the water supply pump 250 can supply water to the inside of the supply block 240. The supply pipe 310 is a bellows, the supply pipe 310 can be telescopically arranged, the supply pipe 310 is arranged between the supply block 240 and the water distribution barrel 150, water entering the supply block 240 can be conveyed to the water distribution barrel 150 through the supply pipe 310, a one-way valve is arranged at a communication position of the supply pipe 310 and the water distribution barrel 150, and the one-way valve can prevent water entering the water distribution barrel 150 from flowing back into the supply pipe 310 again. The supply plate 220 is provided with a first driving unit for driving the driving ring 230 to rotate, the supply block 240 rotates synchronously when the driving ring 230 rotates, and the water supply pump 250 on the supply block 240 is started when the supply block 240 is stationary relative to the flowing water stream.

Further, the first driving unit includes a fourth motor 260 and a fifth gear, the fourth motor 260 is fixedly disposed on the supply tray 220, and the fifth gear is fixedly connected to a power output shaft of the fourth motor 260. The driving ring 230 is provided with a plurality of tooth blocks, the plurality of tooth blocks are uniformly distributed around the circumference of the driving tooth ring, the fifth gear can be meshed with the tooth blocks on the driving ring 230, and when the fourth motor 260 is started, the fifth gear rotates, so that the driving ring 230 starts to rotate.

In this embodiment, at least one guide rod 210 is provided with a thread groove on its outer peripheral wall, a first driving sleeve 280 is sleeved on the outer side of the guide rod 210, a thread groove is provided on the inner peripheral sidewall of the first driving sleeve 280, the first driving sleeve 280 is in threaded driving engagement with the guide rod 210, and the first driving sleeve 280 is rotatably connected with the feeding tray 220. The second motor 290 is fixedly arranged on the supply disc 220, a third gear is fixedly arranged on a power output shaft of the second motor 290, a tooth groove is formed in the peripheral wall of the first driving sleeve 280, the third gear is meshed with the first driving sleeve 280 in transmission fit, and when the second motor 290 is started, the first driving sleeve 280 rotates, so that the supply disc 220 slides along the guide rod 210.

In this embodiment, the supply pipe 310 is divided into a main pipe 311 and a branch pipe 312, the main pipe 311 is vertically arranged, the main pipe 311 can be telescopically arranged, a connecting sleeve is fixedly arranged at the upper end of the main pipe 311, the connecting sleeve penetrates through the sampling platform 110 and the water distribution barrel 150, the connecting sleeve is fixedly connected with the sampling platform 110, the connecting sleeve is rotationally connected with the water distribution barrel 150, a rotating sleeve is coaxially rotationally arranged at the lower end of the main pipe 311, the rotating sleeve is hollow, and the rotating sleeve is rotationally connected with the supply disc 220. One end of the branch pipe 312 is communicated with the inside of the rotating sleeve, the other end of the branch pipe 312 is communicated with the supply block 240, and when the drive disc drives the supply block 240 to move, the supply block 240 drives the rotating sleeve to rotate through the branch pipe 312.

In this embodiment, the feeding block 240 has a first end with a large diameter and a second end with a small diameter, the peripheral side wall of the feeding block 240 is smoothly disposed, the second end of the feeding block 240 is provided with a placement hole communicating with the inside of the feeding block 240, the water supply pump 250 is disposed in the placement hole, and the second end of the feeding block 240 is located in front of the feeding block 240 in the rotation direction, and when the feeding block 240 rotates, the feeding block 240 is shaped to reduce the resistance of water to the rotation of the feeding block 240.

In this embodiment, the driving ring 230 is provided with a plurality of supply blocks 240, the plurality of supply blocks 240 are uniformly distributed around the circumference of the driving ring 230, each supply block 240 is provided with a water supply pump 250, and a branch pipe 312 is connected between each supply block 240 and the rotating sleeve, and the plurality of supply blocks 240 can increase the efficiency of supplying water into the water distribution barrel 150.

In this embodiment, a traction block 320 is disposed between the feeding tray 220 and the sampling platform 110, two through holes are disposed on the traction block 320, each through hole on the traction block 320 passes through one guide rod 210, and the traction block 320 can slide up and down along the guide rod 210. The traction block 320 is provided with at least two traction rings, each traction ring is connected with a traction rope, the traction ropes can be connected to ships, when sampling is carried out on different water areas, sampling water areas are changed by using ships, when the sampling depth is changed, the depth of the traction block 320 is changed simultaneously, and the level of the sampling platform 110 on the water surface can be ensured when the ship is towed. Further, a second driving sleeve 330 is sleeved on the outer side of the guide rod 210 provided with a thread groove, the thread groove is formed in the inner peripheral side wall of the second driving sleeve 330, the second driving sleeve 330 is in threaded transmission fit with the guide rod 210, and the second driving sleeve 330 is rotatably connected with the traction block 320. The third motor 340 is fixedly arranged on the traction block 320, the fourth gear is fixedly arranged on the power output shaft of the third motor 340, the tooth groove is arranged on the peripheral wall of the second driving sleeve 330, the fourth gear is meshed with the second driving sleeve 330 for transmission, and when the third motor 340 is started, the second driving sleeve 330 rotates, so that the traction block 320 slides along the guide rod 210.

In the present embodiment, the inside of the sampling tank 120 is provided with a guide plate 410, and the guide plate 410 is detachably provided inside the sampling tank 120. The guide disc 410 is provided with a plurality of locating holes penetrating up and down, the locating holes are evenly distributed around the circumference of the guide disc 410, each sample reserving bottle 130 penetrates through one locating hole, and when the sample reserving bottle 130 penetrates through the locating hole, stability in water distribution in the sample reserving bottle 130 can be improved. The guide disc 410 is provided at a central portion thereof with a first through hole through which the water distribution pipe 160 passes. Further, the upper end surface of the guide plate 410 is raised at the middle so that the guide plate 410 forms a horizontal height in a direction close to the axis greater than a horizontal height in a direction away from the axis. The sidewall of the sampling case 120 is provided with a drain hole 420 penetrating from the inside to the outside, the drain hole 420 is in the same plane with the edge of the upper end surface of the guide plate 410, and when the water distribution pipe 160 distributes water to the sample reserving bottle 130, the water sprayed on the guide plate 410 by the water distribution pipe 160 can flow along the upper end surface of the guide plate 410 and drain the sampling cavity 121 through the drain hole 420.

In this embodiment, the sampling platform 110 is provided with an inclination sensor, and the inclination sensor is used for detecting an included angle between the sampling platform 110 and a horizontal plane; the sampling platform 110 is provided with a first control board, the first control board can receive detection data of the inclination sensor, and the first control board can control the position of the traction block 320 on the guide rod 210 according to the detection data of the inclination sensor, specifically, the first control board controls the rotation direction of the third motor 340 and the rotation duration of the third motor 340.

In the present embodiment, a flow rate detector for detecting the flow rate of water is provided on the supply tray 220; the supply tray 220 is provided with a second control board, which can receive detection data of the flow rate detector, and can control the speed at which the first driving unit drives the driving ring 230 to rotate according to the detection data of the flow rate detector. Specifically, the second control board controls the rotational speed of the fourth motor 260 to ensure that the feed block 240 remains relatively stationary with the water flow at a certain position.

In combination with the above embodiments, the working process of the treatment device for rotating arm water distribution provided by the embodiment of the present invention is as follows:

during operation, the sample reserving bottle 130 is placed in the sample box 120, the sample platform 110 is placed in a sample water area, the second motor 290 is controlled to start for a certain period of time according to the sample requirement, when the second motor 290 is started, the second motor 290 drives the third gear to rotate, the third gear synchronously rotates under the meshing state of the first driving sleeve 280, and the first driving sleeve 280 is in threaded fit with the guide rod 210, so that the supply disc 220 moves up and down along the guide rod 210, and when the supply disc 220 reaches the preset layer depth, the second motor 290 is closed.

In a water area with a preset depth, the water body is not completely static, a flow rate detector arranged on the supply disc 220 detects the flow rate of the water body, a signal detected by the flow rate detector is transmitted to a second control board, the second control board controls the rotation speed of a fourth motor 260 according to data detected by the flow rate detector, the rotation of the fourth motor 260 is transmitted through a fifth gear and a tooth block on the driving ring 230, the driving ring 230 starts to slide in a ring groove of the supply disc 220, a supply block 240 fixedly connected to the driving ring 230 moves, the supply block 240 is kept relatively static with water flow at a certain position under the control of the detection data of the flow rate detector, a water supply pump 250 is started when the supply block 240 is kept relatively static with water flow, the water supply pump 250 pumps water into the supply block 240, the water entering the supply block 240 enters a rotating sleeve through a branch pipe 312, the water entering the rotating sleeve enters the water distribution barrel 150 through a main pipe 311, and the water distribution barrel 150 cannot flow back into the main pipe 311 again due to the fact that a one-way valve is arranged at the communication position of the water distribution barrel 150 and the main pipe 311. By providing the feed block 240 with a first end having a large diameter and a second end having a small diameter, and the second end having a small diameter is provided at the front side in the rotational direction of the feed block 240, resistance generated by water during movement of the feed block 240 is reduced, and simultaneously the flow of water can push the feed block 240, reducing the load of the fourth motor 260.

As water enters the water distribution tub 150, the water suction pump 171 is activated, and the water suction pump 171 delivers the water in the water distribution tub 150 to the water distribution pipe 160 through the suction pipe 170. At this time, the first motor 180 is intermittently started, and the first motor 180 is driven by the first gear 190 and the second gear, so that the water distribution barrel 150 rotates, and the water distribution barrel 150 rotates to drive the water distribution pipe 160 to synchronously rotate. Meanwhile, when the water distribution pipe 160 distributes water to the sample reserving bottle 130, the water pump 141 on the leveling barrel 140 works simultaneously, at the moment, the water pump 141 pumps water in the leveling barrel 140 simultaneously, and at the moment, the connecting line between the leveling barrel 140 and the sample reserving bottle 130, which is fed with water simultaneously, passes through the axis of the sampling box 120, so that the sampling platform 110 is ensured to keep in a horizontal state.

When changing the sample waters, the boats and ships drive the traction piece 320 through the haulage rope and remove, and inclination sensor on the sampling platform 110 detects the inclination of sampling platform 110 this moment, and the signal transmission that inclination sensor detected is on the first control panel, and first control panel is according to the data control third motor 340's that inclination sensor detected rotation direction and the rotation duration of third motor 340, adjusts the position of traction piece 320 on guide bar 210, ensures that the boats and ships keep steady state when driving sampling platform 110.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (8)

1. The utility model provides a processing apparatus of swinging boom water distribution which characterized in that: comprising the following steps:

the sampling platform can float on the water surface, the sampling platform is provided with a sampling box, the inside of the sampling box is hollow, a plurality of sample reserving bottles are placed in the sampling box, and the plurality of sample reserving bottles are uniformly distributed around the circumference of the inside of the sampling box; the sampling platform is provided with a plurality of leveling cylinders which are uniformly distributed around the circumference of the sampling box, and when any one sample reserving bottle is used for water inflow, the corresponding leveling cylinders are always used for water inflow;

the water distribution barrel is coaxially and rotatably arranged in the sampling box, the water distribution barrel is hollow, a water distribution pipe is fixedly arranged on the water distribution barrel, a suction pipe is arranged in the water distribution barrel and can be inserted into the water distribution pipe, and a water suction pump is arranged on the suction pipe and can suck water in the water distribution barrel into the suction pipe;

the water supply unit is used for supplying water to the inside of the water distribution barrel;

the water supply unit comprises a guide rod, a supply block and a supply pipe; the guide rod is vertically arranged below the sampling platform; the feeding block is arranged in a sliding way up and down along the guide rod, the inside of the feeding block is hollow, the feeding block is provided with a water supply pump, and when the feeding block and the flowing water flow are relatively static, the water supply pump on the feeding block is started; the supply pipe can be arranged in a telescopic way, one end of the supply pipe is communicated with the water distribution barrel, and the other end of the supply pipe is communicated with the supply block;

the water supply unit also comprises a supply disc and a driving ring, the supply disc is arranged in a sliding way up and down along the guide rod, and the supply disc is arranged in parallel with the sampling platform; the driving ring is rotatably arranged on the feeding disc, and the feeding block is arranged on the driving ring; the first driving unit is arranged on the supply disc and is used for driving the driving ring to rotate.

2. The rotary arm water distribution treatment device according to claim 1, wherein: the feeding pipe is divided into a main pipe and a branch pipe, the main pipe is vertically arranged in a telescopic manner, the upper end of the main pipe is communicated with the water distribution barrel, the lower end of the main pipe is provided with a rotating sleeve, the interior of the rotating sleeve is hollow, and the interior of the rotating sleeve is communicated with the main pipe; the branch pipe can stretch out and draw back the setting, and the one end intercommunication that is branched the pipe rotates the cover, and the other end intercommunication that is branched the pipe supplies with the piece.

3. A rotary arm water distribution treatment device according to claim 2, characterized in that: the driving ring is provided with a plurality of feeding blocks, the feeding blocks are uniformly distributed around the circumference of the driving ring, each feeding block is provided with a water supply pump, and a branched pipe is connected between each feeding block and the rotating sleeve.

4. The rotary arm water distribution treatment device according to claim 1, wherein: a traction block is arranged between the supply disc and the sampling platform, the traction block can be arranged along the guide rod in a vertical sliding mode, and the traction block is used for connecting a ship.

5. The rotary arm water distribution treatment device according to claim 1, wherein: the inside of the sampling box is provided with a guide disc, the guide disc is provided with a plurality of positioning holes penetrating up and down, the positioning holes are uniformly distributed around the circumference of the guide disc, and each sample reserving bottle passes through one positioning hole; the middle part of the guide disc is provided with a first through hole, and the water distribution pipe passes through the first through hole.

6. The rotary arm water distribution treatment device according to claim 5, wherein: the upper end face of the guide disc is raised in the middle, the side wall of the sampling box is provided with a drain hole penetrating inside and outside, and the drain hole and the edge of the upper end face of the guide disc are positioned on the same plane.

7. The rotary arm water distribution treatment device according to claim 4, wherein: the sampling platform is provided with an inclination sensor which is used for detecting an included angle between the sampling platform and the horizontal plane; be provided with first control panel on the sampling platform, first control panel can receive inclination sensor's detection data, and first control panel can control the position of traction block on the guide bar according to inclination sensor's detection data.

8. The rotary arm water distribution treatment device according to claim 1, wherein: the supply disc is provided with a flow velocity detector for detecting the flow velocity of water; the supply disc is provided with a second control board, the second control board can receive detection data of the flow rate detector, and the second control board can control the speed at which the first driving unit drives the driving ring to rotate according to the detection data of the flow rate detector.