CN220289095U - Underground water detection sampling equipment - Google Patents

Abstract

The utility model relates to the technical field of groundwater sampling, in particular to a detection sampling device for groundwater, which comprises a sampling box, wherein a water suction pipe is fixedly arranged at the top of the sampling box, a soft telescopic pipe is fixedly connected at the port of the water suction pipe, a retaining plate is fixedly arranged at the port of the soft telescopic pipe, a mounting plate is arranged on one side of the sampling box, the bottom end of the soft telescopic pipe is fixed on the upper part of the mounting plate, a shell is fixedly connected at the bottom end of the mounting plate, and a driving motor is fixedly arranged in the shell. According to the utility model, the driving motor, the drill bit, the lifting frame and the lifting control mechanism are arranged, the bottom end of the soft telescopic pipe stretches into a hole drilled by the drill bit, so that the end part of the soft telescopic pipe can extract underground water through the interception plate, and the driving motor, the drill bit, the lifting frame and the lifting control mechanism are used for facilitating underground drilling by workers, avoiding manual drilling and solving the problems of time and labor waste and high labor intensity caused by complexity of a monitored area and a geological environment in underground water sampling.

Description

Underground water detection sampling equipment

Technical Field

The utility model relates to the technical field of groundwater sampling, in particular to groundwater detection sampling equipment.

Background

The water quality sampler is a water quality sample collection tool with a metal block and acrylic structure, and can be used for collecting water samples of any level in water according to the collection needs and any depth in the water when the tool is used for collecting water samples.

The utility model provides a sample device for groundwater detection is recorded to sample device for groundwater detection that authorizes bulletin number CN214334345U, includes the sampling box, the inside of sampling box is provided with first baffle, second baffle and water storage box, the top of first baffle is provided with the battery, the top of second baffle is provided with water pump and water pressurizer, the top intercommunication of sampling box has the water inlet, the other end intercommunication of water inlet has the connection pad, the opposite side intercommunication of connection pad has the connector, the other end intercommunication of connector has the raceway, the other end intercommunication of raceway has the connector, the opposite side intercommunication of connector has the sampling head.

The sampling device for groundwater detection in the prior art can realize the sampling of groundwater though the water pump, sampling box, water pipe and the like are arranged, but because the prior device is not provided with a drilling structure, when water samples of different levels in water are collected, manual excavation or drilling is needed, the water samples are extracted by the water pump, and the groundwater sampling is time-consuming and labor-consuming due to the complexity of the monitored area and the geological environment, and the labor intensity is high, so that the detection sampling equipment for groundwater is needed to be designed to solve the problems.

Disclosure of Invention

The utility model aims to provide a device for detecting and sampling groundwater, which solves the problems that in the prior art, the sampling device for detecting groundwater can realize the sampling of groundwater through a water pump, a sampling box, a water pipe and the like, but because the prior device is not provided with a drilling structure, when water samples of different layers in water are collected, manual excavation or drilling is needed, the water samples are extracted by the water pump, and the groundwater is time-consuming and labor-consuming due to the complexity of a monitoring area and a geological environment, and the labor intensity is high.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a groundwater detection sampling device comprising: the sampling box, the top fixed mounting of sampling box has the drinking-water pipe, the port department rigid coupling of drinking-water pipe has soft flexible pipe, the port department fixed mounting of soft flexible pipe has the interception board, one side of sampling box is equipped with the mounting panel, the bottom mounting of soft flexible pipe is on mounting panel upper portion, the bottom rigid coupling of mounting panel has the shell, the inside fixed mounting of shell has driving motor, the rigid coupling has the drill bit on driving motor's the output, the back rigid coupling of mounting panel has the crane, the sampling box one side rigid coupling at soft flexible pipe back has the installation shell, be provided with elevating system in the installation shell, the crane is installed on elevating system.

Preferably, universal wheels are mounted at the bottom end of the sampling box.

Preferably, the front surface of the sampling box is embedded and fixed with a visual window.

Preferably, a water pump is fixedly arranged on one side of the inside of the sampling box, and one end, away from the soft telescopic pipe, of the water suction pipe is fixedly connected to the input end of the water pump.

Preferably, the bottom of the sampling box is fixedly communicated with a water sampling pipe.

Preferably, the front and the back of the water pump are welded and fixed with fixing blocks, and bolts are arranged on the fixing blocks and the inner wall of the sampling box in a threaded manner.

Preferably, the lifting control mechanism comprises a servo motor, the servo motor is fixedly arranged at the top end inside the installation shell, a screw rod is connected to the output end of the servo motor, the bottom end of the screw rod is rotationally connected to the bottom of the installation shell through a bearing, a through groove is formed in the front surface of the installation shell, the lifting frame penetrates through the through groove and is installed on the screw rod in a threaded mode, a vertical rod is fixedly connected in the through groove, and the vertical rod penetrates through the lifting frame.

Compared with the prior art, the utility model has the beneficial effects that:

1. through being provided with driving motor, the drill bit, crane and lift control mechanism, the lift control mechanism drive crane that sets up drives mounting panel downward movement, when mounting panel downward movement, driving motor control drill bit rotates, make the drill bit drill, along with the downward movement of mounting panel, soft flexible pipe bottom stretches into in the hole that the drill bit was bored, make the tip of soft flexible pipe extract groundwater through retaining the board, through driving motor, the drill bit, crane and lift control mechanism, make things convenient for the staff to drill in underground, avoided artifical drilling, because the complexity that receives monitoring area and geological environment when having solved the groundwater sample, waste time and energy, problem that intensity of labour is big.

2. Through being provided with servo motor, lead screw, logical groove and vertical pole, by the servo motor control lead screw rotation of circular telegram to make the crane carry out elevating movement along the vertical pole, in order that the flexible pipe bottom of crane control stretches into the hole that drills.

Drawings

FIG. 1 is a schematic elevational, partial cross-sectional view of a structure of the present utility model;

FIG. 2 is a schematic side cross-sectional view of a mounting housing structure of the present utility model;

FIG. 3 is a schematic side cross-sectional view of the mounting shell and crane structure of the present utility model;

fig. 4 is a schematic side cross-sectional view of the housing structure of the present utility model.

In the figure: 110. sampling box; 111. a water pumping pipe; 112. a flexible extension tube; 113. a retaining plate; 114. a mounting plate; 115. a housing; 116. a driving motor; 117. a drill bit; 118. a lifting frame; 119. a mounting shell; 120. a universal wheel; 121. a visual window; 122. a water pump; 123. a fixed block; 124. a bolt; 125. a water intake pipe; 200. a lifting control mechanism; 210. a servo motor; 211. a screw rod; 212. a through groove; 213. a vertical rod.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. 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.

Example 1

Referring to fig. 1-4, an embodiment of the present utility model is provided: a groundwater detection sampling device comprising: the sampling box 110, sampling box 110's top fixed mounting has the drinking-water pipe 111, the port department rigid coupling of drinking-water pipe 111 has soft flexible pipe 112, port department fixed mounting of soft flexible pipe 112 has interception board 113, one side of sampling box 110 is equipped with mounting panel 114, the bottom mounting of soft flexible pipe 112 is in mounting panel 114 upper portion, the bottom rigid coupling of mounting panel 114 has shell 115, the inside fixed mounting of shell 115 has driving motor 116, the rigid coupling has drill bit 117 on the output of driving motor 116, the back rigid coupling of mounting panel 114 has crane 118, sampling box 110 one side rigid coupling at the back of soft flexible pipe 112 has installation shell 119, be provided with lifting control mechanism 200 in the installation shell 119, crane 118 installs on lifting control mechanism 200, when using the device, soft flexible pipe 112 is used for extracting groundwater, the lifting control mechanism 200 that sets up drives crane 118 and is driving mounting panel 114 down motion, driving motor 116 control drill bit 117 rotates when mounting panel 114 down motion, along with the downward motion of mounting panel 114, the bottom of soft flexible pipe 112 stretches into in the hole that drill bit 117 drills out, make the tip of soft flexible pipe 112 through interception board 113, the groundwater, the lifting control mechanism is provided with lifting control of crane 118, the underground water is difficult problem is avoided when the drilling is monitored with the lifting control of the lifting mechanism 118, the underground water is difficult and the underground water is difficult because of the ground, the problem is avoided the underground water is easy to be difficult to be monitored, and the underground environment is easy to be difficult to the ground.

Further, a water pump 122 is fixedly arranged at one side of the inside of the sampling box 110, one end of the water pumping pipe 111, which is far away from the soft telescopic pipe 112, is fixedly connected to the input end of the water pump 122, the water pump 122 pumps groundwater out of the water pumping pipe 111 through the soft telescopic pipe 112, and the groundwater is discharged into the inside of the sampling box 110, and the sampling box 110 is used for storing the pumped groundwater.

Example two

In contrast to the first embodiment, referring to fig. 1-2, the bottom end of the sampling tank 110 is provided with the universal wheel 120, and the universal wheel 120 is convenient for the device to move on the ground and for changing the placement position of the device.

Further, the front surface of the sampling tank 110 is embedded and fixed with a visual window 121, and when the soft telescopic tube 112 extracts groundwater, the amount of groundwater in the sampling tank 110 can be observed through the visual window 121 to determine whether the extraction needs to be stopped.

Further, the bottom of the sampling tank 110 is fixedly connected with the water intake pipe 125, after water pumping is completed, the water intake pipe 125 is opened, and groundwater is discharged from the sampling tank 110 through the water intake pipe 125, so that sampling is completed.

Further, the front and the back of the water pump 122 are welded and fixed with a fixing block 123, bolts 124 are screwed on the fixing block 123 and the inner wall of the sampling box 110, and the bolts 124 are used for fixing the fixing block 123 on the inner wall of the sampling box 110, so that stable installation of the water pump 122 is realized, and the water pump 122 is conveniently used.

Example III

Compared with the first embodiment, referring to fig. 2-3, the lifting control mechanism 200 comprises a servo motor 210, the servo motor 210 is fixedly arranged at the top end inside the installation shell 119, a screw rod 211 is connected to the output end of the servo motor 210, the bottom end of the screw rod 211 is rotatably connected to the bottom of the installation shell 119 through a bearing, a through groove 212 is formed in the front surface of the installation shell 119, the lifting frame 118 passes through the through groove 212 and is threadedly arranged on the screw rod 211, a vertical rod 213 is fixedly connected in the through groove 212, the vertical rod 213 passes through the lifting frame 118, and when the lifting control mechanism is used, the screw rod 211 is controlled to rotate by the energized servo motor 210, so that the lifting frame 118 moves up and down along the vertical rod 213, and the bottom end of the soft telescopic tube 112 is controlled by the lifting frame 118 to extend into a drilled hole.

Working principle: when the device is used, the soft telescopic tube 112 is used for extracting groundwater, the lifting control mechanism 200 drives the lifting frame 118 to drive the mounting plate 114 to move downwards, the driving motor 116 controls the drill bit 117 to rotate when the mounting plate 114 moves downwards, so that the drill bit 117 drills, along with the downward movement of the mounting plate 114, the bottom end of the soft telescopic tube 112 stretches into a hole drilled by the drill bit 117, the end part of the soft telescopic tube 112 extracts groundwater through the interception plate 113, and the lifting control mechanism 200, the lifting frame 118 and the driving motor 116 facilitate underground drilling by workers, so that manual drilling is avoided, and the problems of time and labor waste and high labor intensity due to the complexity of the monitored area and geological environment during groundwater sampling are solved.

During use, the screw rod 211 is controlled to rotate by the electrified servo motor 210, so that the lifting frame 118 moves up and down along the vertical rod 213, the bottom end of the soft telescopic pipe 112 is controlled by the lifting frame 118 to extend into a drilled hole, the water pump 122 pumps groundwater out of the soft telescopic pipe 112 and the pumping pipe 111 and discharges the groundwater into the sampling tank 110, the sampling tank 110 is used for storing the pumped groundwater, the sampling pipe 125 is opened after the pumping is finished, the groundwater is discharged from the sampling tank 110 through the sampling pipe 125, sampling is completed, the fixing block 123 is fixed on the inner wall of the sampling tank 110 by the bolt 124, and therefore stable installation of the water pump 122 is realized, the water pump 122 is used, and when the groundwater is pumped out of the soft telescopic pipe 112, the amount of the groundwater in the sampling tank 110 can be observed through the visual window 121, so that whether the pumping is required to be stopped or not is judged.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. A groundwater detection sampling device, comprising: sampling box (110), the top fixed mounting of sampling box (110) has drinking-water pipe (111), the port department rigid coupling of drinking-water pipe (111) has flexible pipe (112), the port department fixed mounting of flexible pipe (112) has interception board (113), one side of sampling box (110) is equipped with mounting panel (114), the bottom mounting of flexible pipe (112) is on mounting panel (114) upper portion, the bottom rigid coupling of mounting panel (114) has shell (115), the inside fixed mounting of shell (115) has driving motor (116), the rigid coupling has drill bit (117) on the output of driving motor (116), the back rigid coupling of mounting panel (114) has lifting frame (118), sampling box (110) one side rigid coupling at flexible pipe (112) back has mounting shell (119), be provided with lift control mechanism (200) in mounting shell (119), lifting frame (118) are installed on lift control mechanism (200).

2. The groundwater detection sampling device according to claim 1, wherein: the universal wheel (120) is installed to the bottom of sampling box (110).

3. The groundwater detection sampling device according to claim 1, wherein: the front surface of the sampling box (110) is embedded and fixed with a visual window (121).

4. A groundwater detection sampling device according to claim 3, wherein: one side of the inside of the sampling box (110) is fixedly provided with a water pump (122), and one end of the water suction pipe (111) far away from the soft telescopic pipe (112) is fixedly connected to the input end of the water pump (122).

5. The groundwater detection sampling device according to claim 4, wherein: the bottom of the sampling box (110) is fixedly communicated with a water intake pipe (125).

6. The groundwater detection sampling device according to claim 4, wherein: the front and the back of the water pump (122) are welded and fixed with a fixed block (123), and bolts (124) are arranged on the fixed block (123) and the inner wall of the sampling box (110) in a threaded manner.

7. The groundwater detection sampling device according to claim 1, wherein: lifting control mechanism (200) are including servo motor (210), servo motor (210) fixed mounting is on the inside top of installation shell (119), be connected with lead screw (211) on the output of servo motor (210), the bottom of lead screw (211) is passed through the bearing and is rotated and connect in installation shell (119) bottom, logical groove (212) have been seted up in the front of installation shell (119), crane (118) pass logical groove (212) and screw thread installation on lead screw (211), rigid coupling has vertical pole (213) in logical groove (212), vertical pole (213) run through crane (118).