CN218035837U - A water sample and save set for water quality monitoring - Google Patents

Abstract

The utility model discloses a water sample and save set for water quality monitoring, it includes that base and water intaking pipeline, water intaking mechanism, guiding mechanism, actuating mechanism, test tube deposit the subassembly. The water sampling pipeline comprises at least four first water absorption pipes and at least four second water absorption pipes. The water taking mechanism comprises a water pump, a drain pipe and a faucet. The guide mechanism comprises a first support frame and a first guide roller which is rotatably connected to the inner side of the first support frame and is in transmission connection with the outer circumferential wall of the first water suction pipe. The driving mechanism comprises an electric push rod, a second supporting frame, a second guide roller and a motor. The utility model discloses a water sampling and preserving device for water quality monitoring, when it samples water quality in a certain depth of water area, the continuity and stability of water quality sampling are higher, further also improve the sampling efficiency of different order end water depth; the device is simple to operate, and the sample precision controllability is high, easily uses widely.

Description

A water sample and save set for water quality monitoring

Technical Field

The utility model relates to a water quality testing technical field especially relates to a water sample and save set for water quality monitoring.

Background

At present, the water quality monitoring technology of the water environment in China is developed at a higher speed, and the water quality monitoring technology in China mainly takes physicochemical monitoring technology as the main technology, and comprises a chemical method, an electrochemical method, an atomic absorption spectrophotometry method, an ion selective electrode method, an ion chromatography method, a gas chromatography method, a plasma emission spectroscopy (ICP-AES) method and the like.

At present, when water quality sampling is carried out on a water area with a certain depth, a water pump and a water pipe linkage mode is often adopted for sampling the water body, and in order to carry out contrast sampling on water with different depths, the water pump often needs to be frequently stopped and operated due to combing of the water pipe, so that the operation is troublesome, and the sampling efficiency is low; meanwhile, the water pipe extends to water with different depths, and the depth controllability is low, so that the water quality cannot be comprehensively and accurately detected.

SUMMERY OF THE UTILITY MODEL

Based on this, when water quality sampling is performed on a water area with a certain depth, the water body is sampled by adopting a water pump and water pipe linkage mode, and when water with different depths is sampled by contrast, the water pump needs frequent shutdown operation due to combing of the water pipes, so that the operation is troublesome and the sampling efficiency is low; simultaneously, the water pipe extends to the aquatic of the different degree of depth, and the degree of depth controllability is low, leads to can not carrying out comprehensive accurate detection problem to quality of water, provides a water sample and save set for water quality monitoring.

In order to solve the technical problem, the utility model discloses a technical scheme is:

a water sample sampling and save set for water quality monitoring, includes the base:

the water sample sampling and storing device comprises:

the water taking pipeline vertically penetrates through one side of the upper surface of the base; the water sampling pipeline comprises at least four first water suction pipes which are vertically disassembled and overlapped and a second water suction pipe which is detachably connected to the upper end face of the first water suction pipe at the head end;

the hose is communicated with the water outlet port of the second water suction pipe and is fixedly arranged on the water taking mechanism on the base; the water faucet comprises a water pump, a water discharge pipe fixedly arranged at a water outlet port of the water pump and a water faucet which penetrates through the outer circumferential wall of the water discharge pipe;

the guide mechanism is fixedly arranged on the upper surface of the base and corresponds to one side of the outer circumferential wall of the first water suction pipe; the guide mechanism comprises a first support frame and a first guide roller which is rotatably connected to the inner side of the first support frame and is in transmission connection with the outer circumferential wall of the first water suction pipe; and

the parallel corresponds guiding mechanism one side and fixed mounting are in actuating mechanism on the base, actuating mechanism includes that the mount is established electric putter, the fixed mounting of base upper surface are in the electric putter output towards the second support frame, the rotation of first suction pipe outer circumferential wall position are connected the inboard second deflector roll of second support frame links firmly with coaxial second deflector roll one end and fixed mounting be in the motor of second support frame side surface.

According to the water sample sampling and storing device for water quality monitoring, the continuity and the stability of water quality sampling are high, and the sampling efficiency of water depths of different orders is further improved; the device is simple to operate, and the sampling precision controllability is high.

In one embodiment, a first connecting head and a connecting groove are arranged between the head end and the tail end of each two adjacent first water suction pipes; the one end that the second absorbed water and managed is provided with the second connector, the second absorbed water and managed to pass through the second connector with first absorbed water pipe screw thread is dismantled and is connected.

In one embodiment, the second barrel presents a tortuous path.

In one embodiment, when a first water suction pipe is arranged between the first guide roller and the second guide roller, the first water suction pipe is vertically driven.

In one embodiment, a guide groove matched with the first water suction pipe is vertically formed in the upper surface of the base in a penetrating mode.

In one embodiment, a water depth sensor is fixedly mounted on the inner circumferential wall of the first water suction pipe at the tail end, a display screen is mounted on the base, and the output end of the water depth sensor is wirelessly connected with the input end of the display screen.

In one embodiment, the water sampling and storing device further comprises at least four test tube storage assemblies fixedly mounted on one side of the base, and each test tube storage assembly comprises a fixed block and a pipe sleeve fixedly mounted on one side of the fixed block, which faces away from the side face of the base.

Compared with the prior art, the utility model has the following advantage:

1. the utility model discloses, under the synergistic effect of water intaking pipeline, guiding mechanism and actuating mechanism three, adjust the position of second deflector roll, make the first suction pipe effectively spacing between second deflector roll and first deflector roll, utilize the guide way on the base to provide the vertical direction of first suction pipe spacing, the second deflector roll drives the rotation, make water intaking pipeline can stable vertical lift in the water, reach the effective access of the different degree of depth of water, stability is high; meanwhile, the water pump pumps water under negative pressure without stopping, the depths of the first water suction pipe at different stages at the bottom are continuously pumped, water samples of water depths at different stages of the first water suction pipe can be conveniently collected at the water faucet, and the sampling efficiency is high.

2. The utility model discloses, through a plurality of first water absorption pipes and the water intake pipeline that second water absorption pipe screw thread dismantles the constitution, it has made things convenient for the nimble dismouting of pipeline for the water sampling; meanwhile, the number of the connection lengths of the first water absorption pipes can be increased or decreased in applicability according to the deep requirements of different water bodies, and the application range is wide.

3. The utility model discloses, under the effect in coordination through depth of water sensor and display screen, the degree of depth that the first water absorption pipe that is located the top visited into the water can be calculated by the depth of water sensor, and the display screen can show the depth of detection of depth of water sensor in real time to operating personnel effective control first water absorption pipe is at the deep degree of depth of water in the water, and the controllability of depth of water sampling is high.

In summary, the utility model discloses a water sampling and preserving device for water quality monitoring, when it samples water quality to the waters of certain degree of depth, the continuity and stability of water quality sampling are higher, further also improved the sampling efficiency of different order end water depth; the device is simple to operate, and the sample precision controllability is high, easily uses widely.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

Fig. 1 is the utility model relates to a water sample sampling and save set's for water quality monitoring structural schematic diagram.

FIG. 2 is a disassembled view of the water intake line of FIG. 1.

Fig. 3 is a schematic view of the guide mechanism and the driving mechanism in fig. 1.

Fig. 4 is an enlarged perspective view of a portion a of fig. 2.

Description of reference numerals:

1-a base; 2-water taking pipeline; 21-a first water suction pipe;

22-a second suction pipe; 3, a water taking mechanism; 31-a water pump;

32-a drain pipe; 33-a tap; 4, a guide mechanism;

41-a first support frame; 42-a first guide roll; 5-a driving mechanism;

51, an electric push rod; 52-a second support; 53-second guide roll;

54-a motor; 6-water depth sensor; 7, a display screen;

8-a test tube storage assembly; 81-fixed block; 82-pipe sleeve.

Detailed Description

Referring to fig. 1, the present embodiment provides a water sampling and storing device for water quality monitoring, which includes a base 1.

Above-mentioned a subassembly 8 is deposited to water sample and save set for water quality monitoring still includes water intaking pipeline 2, water intaking mechanism 3, guiding mechanism 4, actuating mechanism 5 and four at least test tubes.

Wherein, the base 1 is used as a supporting platform for the device; meanwhile, a storage battery can be arranged on the base 1, and the storage battery provides the running power for the driving device of the device.

Please refer to fig. 2, wherein the water intake pipeline 2 vertically penetrates through one side of the upper surface of the base 1; the water taking pipeline 2 comprises at least four first water suction pipes 21 which are vertically disassembled and overlapped and a second water suction pipe 22 which is detachably connected to the upper end face of the first water suction pipe 21 at the head end. Under the cooperation of four first suction pipes 21, it can be used to provide water guide channel in vertical extension to the water, and second suction pipe 22 can be used to connect negative pressure equipment.

First connecting heads and connecting grooves are arranged at the head end and the tail end between every two adjacent first water suction pipes 21; one end of the second suction pipe 22 is provided with a second connector, and the second suction pipe 22 is detachably connected with the first suction pipe 21 through the second connector. The second barrel 22 is a tortuous path. The connection between the connecting groove and the first connecting head thread facilitates the overlapping connection between two adjacent first water absorption pipes 21; the second water suction pipe 22 is connected with the connecting groove on the first water suction pipe 21 through a second connector, so that the disassembly and the assembly of the second water suction pipe and the connecting groove are convenient; and a second water suction pipe 22 provided in the bent passage for preventing the negative pressure water suction hose from being bent.

It should be noted that the water intake pipeline 2 in this embodiment is applicable to increase or decrease the number of the connection lengths of the first water absorption pipes 21 according to the sampling requirements of different water depths, so as to meet the deep water depth requirements, and the application range is wide.

Referring to fig. 3, the water intake mechanism 3 is connected to the water outlet of the second suction pipe 22 and is fixed on the base 1; the water taking mechanism 3 comprises a water pump 31, a water outlet pipe 32 fixedly arranged at a water outlet port of the water pump 31 and a water tap 33 arranged on the outer circumferential wall of the water outlet pipe 32 in a penetrating way.

When the water taking mechanism 3 is used, the water pump 31 performs negative pressure water pumping action to enable the first water suction pipe 21 in water to pump water in a negative pressure manner, the pumped water is pumped into the water pump 31 along the second water suction pipe 22 and the hose and is discharged into the water body through the external pipeline of the water discharge pipe 32, and waste of the sampled water body can be avoided; meanwhile, by controlling the opening of the valve on the faucet 33, the sampling water body can be conveniently extracted from the faucet 33, and the sampling is more convenient.

Wherein, the guiding mechanism 4 is fixedly arranged on the upper surface of the base 1 and corresponds to one side of the outer circumferential wall of the first water suction pipe 21; the guide mechanism 4 comprises a first support frame 41 and a first guide roller 42 which is rotatably connected to the inner side of the first support frame 41 and is in transmission connection with the outer circumferential wall of the first water suction pipe 21.

Wherein, the driving mechanism 5 is parallel and corresponding to one side of the guide mechanism 4 and is fixedly arranged on the base 1; the driving mechanism 5 comprises an electric push rod 51 fixed on the upper surface of the base 1, a second support frame 52 fixedly installed at the position of the output end of the electric push rod 51 facing the outer circumferential wall of the first water absorbing pipe 21, a second guide roller 53 rotatably connected to the inner side of the second support frame 52, and a motor 54 coaxially and fixedly connected to one end of the second guide roller 53 and fixedly installed on the side surface of the second support frame 52.

The upper surface of the base 1 is vertically provided with a guide groove matched with the first water suction pipe 21 in a penetrating way. The guide groove may provide a vertical guiding capability of the first suction pipe 21 to prevent lateral deviation when the first suction pipe 21 vertically acts.

When the first suction pipe 21 is provided between the first guide roller 42 and the second guide roller 53, the first suction pipe 21 is vertically driven.

When the guide mechanism 4 and the driving mechanism 5 are used, the vertically overlapped first water suction pipe 21 can penetrate through the guide groove and is attached to the inner side of the first guide roller 42, then the electric push rod 51 is controlled to drive the second guide roller 53 on the second support frame 52 to be attached to the outer circumferential wall of the first water suction pipe 21, the first guide roller 42 and the second guide roller 53 provide a moving attaching force for the first water suction pipe 21, and then the motor 54 can be controlled to drive the front and the back, so that the first water suction pipe 21 can be vertically lifted, and the requirement of extending sampling at different depths of a water body can be met; it should be noted that when the second suction pipe 22 moves vertically along with the first suction pipe 21, the hose connecting the second suction pipe 22 and the water pump 31 is not easily bent due to the zigzag structure of the second suction pipe 22.

Referring to fig. 4, a water depth sensor 6 is fixedly mounted on an inner circumferential wall of the first water suction pipe 21 at the tail end, a display screen 7 is mounted on the base 1, and an output end of the water depth sensor 6 is wirelessly connected with an input end of the display screen 7. Under the synergistic effect of water depth sensor 6 and display screen 7, the degree of depth that is arranged in the first suction pipe 21 at top and probes into the water can be calculated by water depth sensor 6, and display screen 7 can show the detection depth of water depth sensor 6 in real time to operating personnel effective control first suction pipe 21 is at the deep depth of water in the water, and the controllability of water depth sampling is high.

Wherein, subassembly 8 is deposited to four at least test tubes of subassembly 8 fixed mounting in base 1 one side, and every test tube is deposited subassembly 8 and is included fixed block 81 and fixed mounting in fixed block 81 one side pipe box 82 of base 1 side dorsad.

When the test tube storage assembly 8 is used, after water is discharged and sampled through the position of the water faucet 33, the plurality of pipe sleeves 82 can provide a temporary storage interval for sampling test tubes, so that water sampling and storage have cooperativity; simultaneously, through the setting of a plurality of pipe casings 82, can conveniently carry out the classification in different stages to a plurality of sampling test tubes, improve the resolution of sampling.

In conclusion, the water sampling and storage device for water quality monitoring of this embodiment has following advantage compared with present water sampling and storage device: when the device is used for sampling water quality in a water area with a certain depth, the continuity and stability of water quality sampling are high, and the sampling efficiency of water depths of different orders is further improved; the classification of different stages is carried out on a plurality of sampling test tubes, so that the sampling resolution is improved; the device is simple to operate, and the controllability of sampling accuracy is high, easily uses widely.

The above, only be the utility model discloses a preferred embodiment, it is not right the utility model discloses do any restriction, all according to the utility model discloses the technical entity all still belongs to any simple modification, change and the equivalent structure change of doing above embodiment the utility model discloses technical scheme's within the scope of protection.

Claims (7)

1. A water sampling and storing device for water quality monitoring comprises a base (1);

the method is characterized in that: the water sample sampling and storing device comprises:

the water taking pipeline (2) vertically penetrates through one side of the upper surface of the base (1); the water taking pipeline (2) comprises at least four first water suction pipes (21) which are vertically disassembled and overlapped and a second water suction pipe (22) which is detachably connected to the upper end surface of the first water suction pipe (21) at the head end;

the hose is communicated with the water outlet port of the second water suction pipe (22) and is fixedly arranged on the water taking mechanism (3) on the base (1); the water pump comprises a water pump (31), a water discharge pipe (32) fixedly arranged at a water outlet port of the water pump (31) and a water faucet (33) arranged on the outer circumferential wall of the water discharge pipe (32) in a penetrating way;

the guide mechanism (4) is fixedly arranged on the upper surface of the base (1) and corresponds to one side of the outer circumferential wall of the first water suction pipe (21); the guide mechanism (4) comprises a first support frame (41) and a first guide roller (42) which is rotatably connected to the inner side of the first support frame (41) and is in transmission connection with the outer circumferential wall of the first water suction pipe (21); and

parallel correspondence is in guiding mechanism (4) one side and fixed mounting are in actuating mechanism (5) on base (1), actuating mechanism (5) are established including the mount electric putter (51), the fixed mounting of base (1) upper surface are in electric putter (51) output terminal towards second support frame (52), the rotation of first water-absorbing pipe (21) outer circumferential wall position are connected second deflector roll (53) and the coaxial link firmly of second deflector roll (53) inboard second deflector roll (53) one end and fixed mounting are in motor (54) of second support frame (52) side surface.

2. A water sampling and storage device for water quality monitoring according to claim 1, characterized in that: a first connecting head and a connecting groove are arranged at the head end and the tail end between every two adjacent first water suction pipes (21);

one end of the second water suction pipe (22) is provided with a second connector, and the second water suction pipe (22) is connected with the first water suction pipe (21) in a threaded dismounting manner through the second connector.

3. A water sampling and storage device for water quality monitoring according to claim 1, characterized in that: the second suction pipe (22) is a zigzag bent passage.

4. A water sampling and storage device for water quality monitoring according to claim 1, characterized in that: when a first water suction pipe (21) is arranged between the first guide roller (42) and the second guide roller (53), the first water suction pipe (21) is vertically driven.

5. A water sampling and storage device for water quality monitoring according to claim 1, characterized in that: the upper surface of the base (1) is vertically provided with a guide groove matched with the first water suction pipe (21) in a penetrating manner.

6. A water sampling and storage device for water quality monitoring according to claim 1, characterized in that: a water depth sensor (6) is fixedly mounted on the inner circumferential wall of the first water suction pipe (21) at the tail end, a display screen (7) is mounted on the base (1), and the output end of the water depth sensor (6) is in wireless connection with the input end of the display screen (7).

7. A water sample sampling and storing device for water quality monitoring according to claim 1, characterized in that: water sample and save set is still including fixed mounting four at least test tubes of base (1) one side deposit subassembly (8), every test tube deposit subassembly (8) are including fixed block (81) and fixed mounting fixed block (81) one side dorsad pipe sleeve (82) of base (1) side.

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