CN218956184U - Water environmental protection monitoring sampler - Google Patents

Abstract

The utility model discloses a water environment-friendly monitoring sampler, which comprises a floating plate, a layered sampling mechanism and a driving mechanism, and is characterized in that: the layered sampling mechanism is arranged on the floating plate, the driving mechanism is arranged on the floating plate, the layered sampling mechanism comprises a shell, a rotating shaft, a conveying channel, an encoder, a waterproof motor, a winding roller, a pumping hose, a rotating joint, a pumping pump, a connecting pipe, an electromagnetic valve, a water outlet joint and a sample storage bottle, the conveying channel is arranged on the rotating shaft, the encoder is arranged on the shell, the waterproof motor is arranged on the encoder and connected with the rotating shaft, the rotating joint is arranged on the rotating shaft and communicated with the conveying channel, the water suction pump is arranged on the floating plate and arranged at the bottom in the shell, and the electromagnetic valve is arranged on the shell and connected with the water suction pump through a pipeline. The utility model belongs to the technical field of water body monitoring samplers, and particularly relates to a water body environment-friendly monitoring sampler which is convenient to operate and cost-saving.

Description

Water environmental protection monitoring sampler

Technical Field

The utility model belongs to the technical field of water body monitoring samplers, and particularly relates to a water body environment-friendly monitoring sampler.

Background

The water environment monitoring is a work of providing reliable basic data for water environment management and providing scientific basis for effect evaluation of treatment measures, in order to enable the data to be accurate, the data of the water monitoring are required to have accuracy and integrity, long-term and multidirectional water monitoring is required by workers, however, the traditional mode is to sample the water in a manual extraction mode, the water can only be sampled at the edge of the water close to a embankment, the sampling depth is lower, and the requirements of the water monitoring are not met, so that people can assist in sampling by adopting extensible equipment, most of the existing water environment monitoring samplers still need to be manually operated, sampling of samples of the water center is achieved by means of ships and the like, the manual pressure is increased, the sampling cost is increased, and particularly when the water environment monitoring samplers are used for classified sampling, repeated operation is required, the sampling efficiency is extremely low, and therefore, the water environment monitoring samplers are proposed to solve the problems.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the utility model provides the water body environment-friendly monitoring sampler, which effectively solves the problems that the existing water body environment-friendly monitoring sampler in the current market still needs a large amount of labor to participate in the sampling process, so that the working pressure is high, the sampling cost for different positions is high, and the operation is complex.

The technical scheme adopted by the utility model is as follows: the utility model provides a water environment-friendly monitoring sampler, which comprises a floating plate, a layered sampling mechanism and a driving mechanism, and is characterized in that: the device comprises a floating plate, a layered sampling mechanism, a driving mechanism, a winding roller, a water pumping hose, a rotating joint, a water pump, a connecting pipe, an electromagnetic valve, a water outlet joint and a sample storage bottle, wherein the layered sampling mechanism is arranged on the floating plate, the driving mechanism is arranged on the floating plate, the shell is arranged on the floating plate, the rotating shaft is rotationally connected to the shell and penetrates through the shell, the conveying passage is arranged on the rotating shaft, the encoder is arranged on the shell, the water pumping hose is arranged on the encoder and is connected with the rotating shaft, the winding roller is arranged on the rotating shaft and is arranged in the shell, one end of the water pumping hose is arranged on the rotating shaft and is communicated with the conveying passage, the other end of the water pumping hose is wound on the winding roller and penetrates through the shell and the floating plate, the rotating joint is arranged on the rotating shaft and is communicated with the conveying passage, the water pumping pump is arranged on the bottom of the floating plate and in the shell, one end of the connecting pipe is arranged on the rotating joint, the other end of the connecting pipe penetrates through the shell and is connected with the water pumping pump, the electromagnetic valve is arranged on the shell and is connected with the water pumping pump pipeline, the water outlet joint is arranged on the electromagnetic valve, and the water outlet joint is arranged on the electromagnetic valve and is in threaded connection with the sample storage joint.

Preferably, in order to realize the mobile function of sampler, actuating mechanism includes buckler, baffle, driving motor, drive shaft, bearing seal, impeller and buoyancy tank, the buckler is located on the kickboard and is located the both sides of kickboard, the baffle is located on the buckler and is located the top of kickboard, driving motor locates on the buckler and locates in the buckler, the drive shaft is located on the driving motor and is run through the buckler setting, the bearing seal is located on the buckler and is located on the drive shaft, the impeller is located on the drive shaft, the buoyancy tank is located on the kickboard and is located the bottom of kickboard.

Further, the bottom in the buoyancy tank is equipped with energy memory, the upper end of shell is equipped with signal transceiver, be equipped with data processing module on the energy memory, the one end that is in the kickboard below on the hose that draws water is equipped with the suction head, rotate on the shell inner wall and connect and be equipped with the pressure strip, the one end that the pressure strip is movable sets up with the hose laminating that draws water, the one end that the pressure strip is movable is equipped with hold-down spring, hold-down spring one end is located on the pressure strip, the top in the shell is located to the hold-down spring other end.

The water outlet connector is internally provided with threads, and the electromagnetic valve is arranged between the shell and the sample storage bottle.

Further, the shell is arranged perpendicular to the floating plate.

Further, the water pumping hose is arranged on the same plane after being wound on the winding roller.

Wherein, buoyancy tank is hollow quadrangular frustum pyramid setting, the buckler is hollow cylinder setting.

Preferably, the impeller is arranged in a central radial structure, the winding roller is arranged in an H shape, and the conveying channel is arranged in an L shape.

The waterproof covers are provided with two groups, the number of the baffles is consistent with that of the waterproof covers, the driving motor is provided with two groups, the number of the impellers is consistent with that of the driving motor, and the water outlet joint is provided with a plurality of groups.

The beneficial effects obtained by the utility model by adopting the structure are as follows: the water environmental protection monitoring sampler that this scheme provided, the effectual water environmental protection monitoring sampler that has solved present water environmental protection monitoring sampler in the present market still need artifical a large amount of participation to lead to working pressure big at the sample in-process to and to the problem that different position sample is with high costs, the operation is complicated, but realize that the sampler remote control realizes that automatic removal accomplishes different position sample in the water, can realize carrying out categorised sample to different degree of depth waters, overall structure is simple and practical, with low costs, specifically is a water environmental protection monitoring sampler of simple operation, cost-effective.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a first view angle of a water environmental protection monitoring sampler according to the present utility model;

FIG. 2 is a schematic diagram of the overall structure of a second view angle of the water environmental protection monitoring sampler according to the present utility model;

FIG. 3 is a first cross-sectional view of a water environmental monitoring sampler according to the present utility model;

fig. 4 is a second cross-sectional view of the water environmental protection monitoring sampler provided by the utility model.

Wherein 1, the kickboard, 2, layering sampling mechanism, 3, actuating mechanism, 4, the shell, 5, the pivot, 6, the conveying passageway, 7, the encoder, 8, waterproof motor, 9, the winding roller, 10, the water pumping hose, 11, the swivel joint, 12, the suction pump, 13, the connecting pipe, 14, the solenoid valve, 15, the water outlet joint, 16, the sample storage bottle, 17, the buckler, 18, the baffle, 19, actuating motor, 20, the drive shaft, 21, the shaft seal, 22, the impeller, 23, buoyancy tank, 24, energy storage device, 25, signal transceiver, 26, data processing module, 27, the suction head, 28, the pressure strip, 29, compression spring.

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model.

Detailed Description

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

As shown in fig. 1, fig. 2, fig. 3 and fig. 4, the utility model provides a water environmental protection monitoring sampler, which comprises a floating plate 1, a layered sampling mechanism 2 and a driving mechanism 3, and is characterized in that: the device is characterized in that the layered sampling mechanism 2 is arranged on the floating plate 1, the driving mechanism 3 is arranged on the floating plate 1, the layered sampling mechanism 2 comprises a shell 4, a rotating shaft 5, a conveying channel 6, an encoder 7, a waterproof motor 8, a winding roller 9, a water pumping hose 10, a rotating joint 11, a water pumping pump 12, a connecting pipe 13, an electromagnetic valve 14, a water outlet joint 15 and a sample storage bottle 16, the shell 4 is arranged on the floating plate 1, the rotating shaft 5 is rotationally connected to the bottom of the shell 4 and is arranged in a penetrating way, the conveying channel 6 is arranged on the rotating shaft 5, the encoder 7 is arranged on the shell 4, the waterproof motor 8 is arranged on the encoder 7 and is connected with the rotating shaft 5, the winding roller 9 is arranged on the rotating shaft 5 and is arranged in the shell 4, one end of the water pumping hose 10 is arranged on the rotating shaft 5 and is communicated with the conveying channel 6, the other end of the water pumping hose 10 is wound on the winding roller 9 and penetrates through the shell 4 and the floating plate 1, the rotating joint 11 is arranged on the rotating shaft 5 and is communicated with the conveying channel 6, the water pumping pump 12 is arranged on the bottom of the shell 1 and is arranged on the shell 4 and penetrates through the shell 4, the rotating joint 11 is connected with the electromagnetic valve 14 and is arranged on the other end of the connecting pipe 14, the water pumping joint 12 is connected with the water outlet joint 14 and the water outlet joint 14, the water outlet joint 12 is arranged on the connecting pipe 14 and the connecting pipe 4.

As shown in fig. 1, 2, 3 and 4, the driving mechanism 3 includes a waterproof cover 17, a baffle 18, a driving motor 19, a driving shaft 20, a shaft seal 21, a pulsator 22 and a buoyancy tank 23, wherein the waterproof cover 17 is arranged on the floating plate 1 and arranged on two sides of the floating plate 1, the baffle 18 is arranged on the waterproof cover 17 and above the floating plate 1, the driving motor 19 is arranged on the waterproof cover 17 and in the waterproof cover 17, the driving shaft 20 is arranged on the driving motor 19 and penetrates through the waterproof cover 17, the shaft seal 21 is arranged on the waterproof cover 17 and on the driving shaft 20, the pulsator 22 is arranged on the driving shaft 20, and the buoyancy tank 23 is arranged on the floating plate 1 and at the bottom of the floating plate 1.

As shown in fig. 1, fig. 2, fig. 3 and fig. 4, the bottom in the buoyancy tank 23 is provided with an energy storage device 24, the upper end of the housing 4 is provided with a signal transceiver 25, the energy storage device 24 is provided with a data processing module 26, one end of the pumping hose 10, which is positioned below the floating plate 1, is provided with a suction head 27, the inner wall of the housing 4 is rotationally connected with a compacting plate 28, one movable end of the compacting plate 28 is in fit with the pumping hose 10, one movable end of the compacting plate 28 is provided with a compacting spring 29, one end of the compacting spring 29 is arranged on the compacting plate 28, and the other end of the compacting spring 29 is arranged at the top in the housing 4.

Wherein, the water outlet joint 15 is internally provided with threads, and the electromagnetic valve 14 is arranged between the shell 4 and the sample storage bottle 16; the shell 4 is arranged vertically to the floating plate 1; the water pumping hose 10 is arranged on the same plane after being wound on the winding roller 9.

Preferably, the buoyancy tank 23 is a hollow quadrangular frustum, and the waterproof cover 17 is a hollow cylinder; the impeller 22 is arranged in a central radial structure, the winding roller 9 is arranged in an H shape, and the conveying channel 6 is arranged in an L shape.

The number of baffles 18 is consistent with that of the waterproof covers 17, the number of driving motors 19 is two, the number of impellers 22 is consistent with that of the driving motors 19, and the water outlet joint 15 is provided with a plurality of groups.

When the device is particularly used, the whole device is placed in a water body to be monitored, the movement of the whole device is realized by utilizing a remote controller through a signal transceiver 25, when the whole device is required to be moved, only the respective rotating speeds of two groups of driving motors 19 are required to be controlled, when the rotating speeds of the two groups of driving motors are the same, the impeller 22 on the driving shaft 20 can be driven to rotate, the whole device is enabled to move back and forth, when the speeds of the two groups of driving motors are different, the rotation in the direction can be realized, after the whole device is moved to a designated position, the waterproof motor 8 is opened by remote control, the waterproof motor 8 drives the rotating shaft 5 to rotate, along with the rotation of the winding roller 9, the water pumping hose 10 wound on the winding roller 9 is gradually taken out, one end provided with a suction head 27 is settled towards the bottom of the water body, at the moment, the number of turns of the rotation of the rotating shaft 5 is monitored by utilizing the encoder 7, the calculation of the taking-out length of the water pumping hose 10 wound on the winding roller 9 is realized through a data processing module 26, and the sampling depth is fed back, when the suction head 27 is positioned at different depths, the suction pump 12 is opened, so that water enters the suction hose 10 through the suction head 27 and sequentially passes through the conveying channel 6, the rotary joint 11 and the connecting pipe 13 to reach the electromagnetic valve 14, different valve positions are selected by controlling the electromagnetic valve 14, and the extracted water samples respectively enter the sample storage bottle 16 for storage, and the suction hose 10 is wound on the winding roller 9 or is taken off from the winding roller 9, so that the suction hose 10 can be ensured to be tightly attached all the time under the action of the compression plate 28 and the compression spring 29, the accuracy of depth control is improved, and the problem of uncertain depth caused by uneven winding of the suction hose 10 is avoided.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

The utility model and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the utility model as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims (9)

1. The utility model provides a water environmental protection monitoring sampler, includes kickboard, layering sampling mechanism and actuating mechanism, its characterized in that: the device comprises a floating plate, a layered sampling mechanism, a driving mechanism, a winding roller, a water pumping hose, a rotating joint, a water pump, a connecting pipe, an electromagnetic valve, a water outlet joint and a sample storage bottle, wherein the layered sampling mechanism is arranged on the floating plate, the driving mechanism is arranged on the floating plate, the shell is arranged on the floating plate, the rotating shaft is rotationally connected to the shell and penetrates through the shell, the conveying passage is arranged on the rotating shaft, the encoder is arranged on the shell, the water pumping hose is arranged on the encoder and is connected with the rotating shaft, the winding roller is arranged on the rotating shaft and is arranged in the shell, one end of the water pumping hose is arranged on the rotating shaft and is communicated with the conveying passage, the other end of the water pumping hose is wound on the winding roller and penetrates through the shell and the floating plate, the rotating joint is arranged on the rotating shaft and is communicated with the conveying passage, the water pumping pump is arranged on the bottom of the floating plate and in the shell, one end of the connecting pipe is arranged on the rotating joint, the other end of the connecting pipe penetrates through the shell and is connected with the water pumping pump, the electromagnetic valve is arranged on the shell and is connected with the water pumping pump pipeline, the water outlet joint is arranged on the electromagnetic valve, and the water outlet joint is arranged on the electromagnetic valve and is in threaded connection with the sample storage joint.

2. The water environmental monitoring sampler of claim 1, wherein: the driving mechanism comprises a waterproof cover, a baffle, a driving motor, a driving shaft, a shaft seal, a wave wheel and a buoyancy tank, wherein the waterproof cover is arranged on the floating plate and arranged on two sides of the floating plate, the baffle is arranged on the waterproof cover and above the floating plate, the driving motor is arranged on the waterproof cover and in the waterproof cover, the driving shaft is arranged on the driving motor and penetrates through the waterproof cover, the shaft seal is arranged on the waterproof cover and on the driving shaft, the wave wheel is arranged on the driving shaft, and the buoyancy tank is arranged on the floating plate and at the bottom of the floating plate.

3. The water environmental monitoring sampler of claim 2, wherein: the bottom in the buoyancy tank is equipped with energy memory, the upper end of shell is equipped with signal transceiver, be equipped with data processing module on the energy memory, the one end that is in the kickboard below on the pumping hose is equipped with the suction head, rotate on the shell inner wall and be connected and be equipped with the pressure strip, the one end of pressure strip activity and pumping hose laminating setting, the one end of pressure strip activity is equipped with the hold-down spring, on the hold-down spring one end was located the hold-down plate, the top in the shell is located to the hold-down spring other end.

4. A water environmental monitoring sampler according to claim 3 and characterized in that: the water outlet joint is internally provided with threads, and the electromagnetic valve is arranged between the shell and the sample storage bottle.

5. The water environmental monitoring sampler of claim 4 wherein: the shell is perpendicular to the floating plate.

6. The water environmental monitoring sampler of claim 5, wherein: the water pumping hose is arranged on the same plane after being wound on the winding roller.

7. The water environmental monitoring sampler of claim 6 wherein: the buoyancy tank is hollow quadrangular frustum pyramid setting, the buckler is hollow cylinder setting.

8. The water environmental monitoring sampler of claim 7 wherein: the impeller is arranged in a central radial structure, the winding roller is arranged in an H shape, and the conveying channel is arranged in an L shape.

9. The water environmental monitoring sampler of claim 8 wherein: the waterproof cover is provided with two groups, the number of baffles is consistent with that of the waterproof cover, the driving motor is provided with two groups, the number of the impellers is consistent with that of the driving motor, and the water outlet joint is provided with a plurality of groups.

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