CN219695084U - Engineering geology reconnaissance water quality monitoring system - Google Patents

Abstract

The utility model belongs to the field of geological exploration, and particularly relates to a water quality monitoring system for engineering geological exploration, which solves the problems of low single collection efficiency and unstable horizontal locking in the prior art.

Description

Engineering geology reconnaissance water quality monitoring system

Technical Field

The utility model relates to the technical field of geological exploration, in particular to a water quality monitoring system for engineering geological exploration.

Background

At present, geological exploration is a geological work, and is an investigation and research work for geological conditions of rocks, stratum structures, minerals, groundwater, landforms and the like in a certain area by applying geological exploration methods such as mapping, geophysical exploration, geochemical prospecting, drilling, pothole exploration, sampling test, geological remote sensing and the like according to the requirements of economic construction, national defense construction and scientific technology development, and the geological exploration also comprises regional geological investigation, marine geological investigation, geothermal field exploration, earthquake geological investigation, environmental geological investigation and the like with various scales. Geological exploration is based on geological observation research, and according to task requirements, the principle of obtaining more and better geological achievements is adopted by shorter time and less workload, and necessary technical means or methods such as mapping, geophysical exploration, geochemical prospecting, drilling, pothole exploration, sampling test, geological remote sensing and the like are selected. The use or construction of these methods or means is also within the scope of geological exploration. In a narrow sense, in the actual geological work of China, the geological investigation work is also divided into 5 stages, namely regional geological investigation, census, detailed investigation, exploration and development exploration.

The authorized bulletin number in the prior art is: the utility model discloses an engineering geological investigation water quality monitoring system of CN114839338A, which comprises a water quality monitor, a sampling device and a manual air pump, wherein the sampling device is communicated with the water quality monitor, the manual air pump is communicated with the sampling device, the structure is simple, the cost is low, the weight is light, the manual air pump is used for changing the air pressure change in the sampling device, the overall quality of sample collection equipment is reduced while water sampling is realized, the working intensity of staff is reduced, the manual air pump is positioned outside the sampling device, the manual air pump is communicated through an air pipe, the disassembly and the replacement are convenient, the actual practicability of the sample collection equipment is improved, in addition, the manual air pump is manual, electric power is not needed, and the system is more suitable for outdoor water sample collection, however, only one storage water tank is needed for single sampling, multiple times of collection and detection analysis are needed for water samples with different depths, the efficiency is low, the buckle device for keeping the level is not firm, the outdoor wet sliding environment is easy to enable the buckle to slide, the equipment level is influenced, and the equipment is damaged and the hidden danger of side turning over is caused.

Disclosure of Invention

The utility model aims to provide a water quality monitoring system for engineering geological investigation, which solves the problems of low single acquisition efficiency and unstable horizontal locking.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an engineering geology reconnaissance water quality monitoring system, includes the casing, the inside of casing is respectively through screw fixedly connected with mounting panel and water tank, the mounting panel with be connected with the sliding sleeve through screw fixedly on the casing jointly, rotate on the casing and install the worm, water quality testing appearance is installed at the top of casing, the top of casing is through screw fixedly connected with hinge, the rotation portion of hinge is through screw fixedly connected with protection casing;

install the suction pump on the mounting panel, suction pump's both sides fixedly connected with water inlet and hose respectively, rotate on the mounting panel and install rotatory screw rod, screw fixedly connected with worm wheel is passed through to the bottom of rotatory screw rod, the inside sliding fit of sliding sleeve has the slider, the slider with rotatory screw rod threaded connection, the other end fixedly connected with of hose is in on the slider, the opposite side fixedly connected with delivery port of slider, screw fixedly connected with rocking handle is passed through to the one end of worm.

Preferably, the bottom of casing is through screw fixedly connected with base, through screw fixedly connected with four symmetrical arrangement's fixed plate on the base, four equal threaded connection has lifting screw on the fixed plate, four all rotate on the lifting screw and install the runner.

Preferably, a thread groove is formed in the slider, the rotary screw rod penetrates through the thread groove, and the shape and the size of the rotary screw rod are the same as those of the thread groove.

Preferably, the worm wheel and the worm are engaged.

Preferably, the shell is provided with a through groove, and the water inlet penetrates through the inside of the through groove.

Preferably, through holes are formed in the four fixing plates, the four lifting screws penetrate through the four through holes respectively, and the four lifting screws and the four through holes are identical in shape and size.

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

1. according to the utility model, through the arrangement of the structures such as the water outlet pipe and the water tank, the water pipe connected with the water inlet is placed into river water to be detected, the water suction pump is started, the extracted water sample flows into the water tank through the water outlet, the rocking handle is rotated, the worm is rotated to drive the worm wheel to rotate, the rotating screw rod is rotated to enable the sliding block to ascend, when water samples with different depths or water samples in different areas are collected, the collected water samples flow into another water tank, and multiple water samples can be collected for monitoring and analysis at the same time through single sampling, so that the effect of improving the collection efficiency is realized.

2. According to the utility model, through the arrangement of the structures such as the fixed plate and the lifting screw, when the ground is uneven during outdoor collection, the lifting screw at a low-lying angle is rotated, so that the lifting screw is lowered against the low-lying ground, the whole equipment can be kept horizontal, the influence of the rotating structure on the moist environment is low, the firm structure is ensured, the equipment is prevented from tilting and tilting, and the effect of keeping the horizontal structure of the equipment firm is realized.

Drawings

FIG. 1 is a front view of the present utility model;

FIG. 2 is an enlarged view of structure A of the present utility model;

fig. 3 is a schematic overall structure of the present utility model.

In the figure: 1. a housing; 2. a water inlet; 3. a base; 4. a fixing plate; 5. lifting screw rods; 6. a rotating wheel; 7. a worm; 8. a rocking handle; 9. a mounting plate; 10. a water pump; 11. a worm wheel; 12. rotating the screw; 13. a hose; 14. a slide block; 15. a water outlet; 16. a sliding sleeve; 17. a protective cover; 18. a hinge; 19. a water quality detector; 20. a water tank.

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.

Referring to fig. 1-3, an engineering geological investigation water quality monitoring system, which comprises a housing 1, the inside of casing 1 is respectively through screw fixedly connected with mounting panel 9 and water tank 20, the joint passes through screw fixedly connected with sliding sleeve 16 on mounting panel 9 and the casing 1, install worm 7 on the casing 1, water quality detector 19 is installed at the top of casing 1, the top of casing 1 is through screw fixedly connected with hinge 18, the rotation portion of hinge 18 is through screw fixedly connected with protection casing 17, install suction pump 10 on mounting panel 9, suction pump 10's both sides are fixedly connected with water inlet 2 and hose 13 respectively, install rotatory screw 12 on mounting panel 9, the bottom of rotatory screw 12 is through screw fixedly connected with worm wheel 11, sliding sleeve 16's inside sliding fit has slider 14, slider 14 and rotatory screw 12 threaded connection, the other end fixedly connected with of hose 13 is on slider 14, the opposite side fixedly connected with delivery port 15 of slider 14, one end of worm 7 is through screw fixedly connected with handle 8, through the setting of structure such as outlet pipe, water tank 20, put into the water pipe that water inlet 2 department is connected with and wait to detect, start suction pump 10, the rotation of worm wheel 12 is installed in the water sample is flowed into the different sample collection areas through screw 11 when the rotation of screw 12, the sample is rotated by the rotation of the screw 11, simultaneously, sample collection efficiency is different sample collection samples are realized to sample collection in the time of sample collection samples is different sample collection areas when the sample is rotated in the water is different, the sample collection is different in the water sample collection area is different, and the sample collection is rotated by the time, and when the sample collection is different in the sample is different sample is rotated by the rotation and is measured.

Referring to fig. 1-3, the bottom of the housing 1 is fixedly connected with a base 3 through screws, four symmetrically arranged fixing plates 4 are fixedly connected with the base 3 through screws, lifting screws 5 are connected to the four fixing plates 4 in a threaded manner, rotating wheels 6 are rotatably arranged on the four lifting screws 5, when the ground is uneven during outdoor collection through the arrangement of the fixing plates 4, the lifting screws 5 with low-lying angles are rotated, the lifting screws 5 are enabled to fall against the low-lying topography, the whole equipment can be kept horizontal, the rotating structure is affected by the humid environment less, the firmness of the structure is guaranteed, the equipment is prevented from tilting, and the effect of keeping the horizontal structure of the equipment firm is achieved.

Referring to fig. 1, a threaded groove is formed in the slider 14, the rotary screw 12 passes through the threaded groove, and the rotary screw 12 and the threaded groove have the same shape and size.

Referring to fig. 1, the worm wheel 11 is engaged with the worm 7.

Referring to fig. 1, a casing 1 is provided with a through groove, and a water inlet 2 passes through the inside of the through groove

Referring to fig. 1, through holes are formed in the four fixing plates 4, and four lifting screws 5 respectively penetrate through the four through holes, and the four lifting screws 5 and the four through holes are identical in shape and size.

The specific implementation process of the utility model is as follows: the water pipe that is connected with water inlet 2 is put into the river that waits to detect, start suction pump 10, the water sample of extraction flows into water tank 20 through delivery port 15, when the different degree of depth water sources of extraction or different regional water sources, rotate rocking handle 8, worm 7 rotates and drives worm wheel 11 pivoted, rotatory screw rod 12 rotates and makes slider 14 rise, the water sample is gathered from delivery port 15 flow direction different water tank 20, the water sample of collection completion can drip into water quality detector 19 and monitor the analysis, the single sampling can collect several kinds of water samples simultaneously and carry out analysis contrast, improve collection efficiency.

When the ground is uneven during outdoor collection, the lifting screw 5 at the low-lying angle of the topography is rotated, so that the lifting screw 5 is descended against the low-lying topography, the whole equipment can be kept horizontal, the rotating structure is affected by the humid environment to be lower, and the structure is guaranteed to be firm and prevent the equipment from tilting.

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.

Claims (6)

1. The utility model provides an engineering geology reconnaissance water quality monitoring system, includes casing (1), its characterized in that: the inside of the shell (1) is fixedly connected with a mounting plate (9) and a water tank (20) through screws respectively, the mounting plate (9) and the shell (1) are jointly connected with a sliding sleeve (16) through screws, a worm (7) is rotatably installed on the shell (1), a water quality detector (19) is installed at the top of the shell (1), a hinge (18) is fixedly connected to the top of the shell (1) through screws, and a protection cover (17) is fixedly connected to a rotating part of the hinge (18) through screws;

install suction pump (10) on mounting panel (9), the both sides of suction pump (10) are fixedly connected with water inlet (2) and hose (13) respectively, rotate on mounting panel (9) and install rotatory screw rod (12), screw fixedly connected with worm wheel (11) are passed through to the bottom of rotatory screw rod (12), the inside sliding fit of sliding sleeve (16) has slider (14), slider (14) with rotatory screw rod (12) threaded connection, the other end fixedly connected with of hose (13) is in on slider (14), the opposite side fixedly connected with delivery port (15) of slider (14), screw fixedly connected with rocking handle (8) are passed through to the one end of worm (7).

2. An engineering geological survey water quality monitoring system according to claim 1, wherein: the bottom of casing (1) is through screw fixedly connected with base (3), be connected with four symmetrical arrangement's fixed plate (4) through screw fixedly on base (3), four equal threaded connection has lifting screw (5) on fixed plate (4), four all rotate on lifting screw (5) and install runner (6).

3. An engineering geological survey water quality monitoring system according to claim 1, wherein: the inside of slider (14) has seted up the screw thread groove, rotatory screw rod (12) pass the inside of screw thread groove, rotatory screw rod (12) with the shape size of screw thread groove is the same.

4. An engineering geological survey water quality monitoring system according to claim 1, wherein: the worm wheel (11) is meshed with the worm (7).

5. An engineering geological survey water quality monitoring system according to claim 1, wherein: the shell (1) is provided with a through groove, and the water inlet (2) penetrates through the inside of the through groove.

6. An engineering geological survey water quality monitoring system according to claim 2, wherein: through holes are formed in the four fixing plates (4), the four lifting screws (5) penetrate through the four through holes respectively, and the shape and the size of the four lifting screws (5) are the same as those of the four through holes.