CN117760786A - Sampling device for industrial wastewater detection - Google Patents

Abstract

The invention discloses a sampling device for industrial wastewater detection, which relates to the technical field of industrial wastewater detection and comprises a movable trolley, an adjusting mechanism and a sampling mechanism, wherein the adjusting mechanism is arranged on the movable trolley, and the sampling mechanism is arranged on the adjusting mechanism; according to the invention, the adjusting mechanism is arranged, so that the sampling mechanism can be automatically adjusted to a position to be sampled, and the height of the sampling mechanism can be adjusted, so that water with different depths can be sampled conveniently; according to the invention, through the cooperation of the driving component and the stirring component, the timing and quantitative sampling can be realized by adjusting the position of the sampling component, and the stirring component is driven to stir the wastewater every time the position of the sampling component is adjusted; the invention can automatically sample the filtered and unfiltered wastewater by arranging the sampling component, thereby being suitable for different detection projects.

Description

Sampling device for industrial wastewater detection

Technical Field

The invention relates to the technical field of industrial wastewater detection, in particular to a sampling device for industrial wastewater detection.

Background

Industrial wastewater detection is used to evaluate and monitor the quality and environmental impact of industrial wastewater discharge. By detecting industrial wastewater, wastewater discharge can be ensured to meet environmental regulations and standards so as to protect the environment and public health. The industrial wastewater detection needs a sampling device, which is a device for collecting industrial wastewater samples for analysis and monitoring. In industrial wastewater detection, sampling is a very important link. However, sampling of industrial wastewater presents several technical problems, including the following: 1. representative sampling: industrial wastewater is often a complex mixture containing various organic, inorganic and suspended materials, and the like, and therefore, it is necessary to ensure that the collected sample is characteristic of the whole wastewater during the sampling process, and if the sampling is insufficient or not representative, the deviation of the detection result may occur. 2. Sampling point selection: the composition and properties of the wastewater may vary from location to location, so that the degree of mixing of the wastewater and the concentration gradient that may be present need to be taken into account when selecting the sampling points, and selecting the appropriate sampling points may improve the accuracy and representativeness of the sampling; 3. sampling time point selection: the composition and properties of the wastewater may change at different times; 4. sampling techniques and methods: the detection and sampling of the wastewater need to adopt a specific technology and a specific method, some detection projects need to filter the water sample to remove suspended matters and solid impurities so as to obtain an accurate analysis result, and some detection projects do not need to filter and directly use the unfiltered water sample for analysis. Methods such as quantitative sampling and stratified sampling are also used for ensuring the accuracy and repeatability of sampling; 5. sampling process control: there may be some sources of error in the sampling process, such as air contact, contamination of the sampling equipment, human error, etc. 6. Number and frequency of samples: the number and frequency of wastewater detection samples is also a technical problem. The sampling amount is enough to meet the analysis requirement, and the sampling frequency is enough to reflect the change condition of the wastewater discharge so as to discover the abnormality and the change in time.

The Chinese patent publication No. CN112763272B discloses an industrial wastewater filtering, sampling and detecting device for environment detection, wherein when sampling is carried out, wastewater enters a box body after large-particle impurities are filtered out through a filtering inlet, so that on one hand, the influence of the impurities on a detecting device body is prevented, and on the other hand, the influence on a turbidity detecting result is avoided; after the sampling is finished, the driving mechanism drives the shell to move upwards to expose the filtering water inlet, and the waste water in the box body is discharged. Although this patent can automatically sample the wastewater, it is inconvenient to mix the wastewater and cannot take out representative wastewater, and although this patent can filter the wastewater, it cannot automatically take out both samples with suspended matter and filtered; and this patent also does not facilitate movement and sequestration of the sample, nor does it facilitate multiple sampling.

Disclosure of Invention

Aiming at the technical problems, the invention adopts the following technical scheme: the sampling device for industrial wastewater detection comprises a movable trolley, an adjusting mechanism and a sampling mechanism, wherein the adjusting mechanism is arranged on the movable trolley, and the sampling mechanism is arranged on the adjusting mechanism; the sampling mechanism comprises a driving assembly, a stirring assembly and a sampling assembly, wherein the driving assembly is arranged on the adjusting mechanism, a plurality of groups of sampling assemblies are arranged on the adjusting mechanism, the stirring assembly and the sampling assembly are arranged on the adjusting mechanism, and the driving assembly is used for enabling the sampling assembly and the stirring assembly to synchronously move; the sampling assembly comprises a driving unit, a plugging unit, an inner cylinder, an outer cylinder and an adjusting rod, wherein the driving unit is arranged on the driving assembly, the plugging unit is arranged on the driving unit, the outer cylinder is fixedly provided with the adjusting rod, the inner cylinder is slidably arranged in the outer cylinder, a water outlet pipe II and a water outlet pipe I are arranged on the outer cylinder, a plurality of water inlet holes are formed in the circumference of the inner cylinder, a water outlet hole I and a water outlet hole II are further formed in the inner cylinder, and the water outlet hole I and the water outlet Kong Erfen are respectively communicated with the water outlet pipe I and the water outlet pipe II.

Further, the driving unit comprises a driving rod, a sliding block, a sliding rod and a sliding frame, wherein the sliding rod is fixedly arranged on the driving rod, the sliding block is slidably arranged on the sliding rod, a connecting rod is fixedly arranged on the sliding block, the sliding frame is further slidably arranged on the sliding rod, and the sliding frame and the outer cylinder are fixedly arranged.

Further, the plugging unit comprises a plugging rod and a plugging plate, the plugging rod is slidably mounted on the sliding block, the plugging rod is slidably mounted on the driving rod, the plugging plate is fixedly mounted at the end part of the plugging rod, and the plugging plate and the inner cylinder are fixedly mounted.

Further, the driving assembly comprises a supporting unit and a power unit, wherein the supporting unit is arranged on the adjusting mechanism, and the power unit is arranged on the supporting unit.

Further, the supporting unit comprises a first supporting ring, a cover plate, a fixing frame, a fourth supporting ring, a third supporting ring and a second supporting ring, wherein the first supporting ring, the second supporting ring, the third supporting ring and the fourth supporting ring are sequentially and fixedly installed on the fixing frame, and the cover plate and the fixing frame are fixedly installed.

Further, the power unit include drive gear, drive ring gear, connecting axle and stirring ring gear, drive gear and drive ring gear meshing installation, drive gear pass through hold-in range and connecting axle and carry out the transmission, the connecting axle on fixed mounting have the stirring ring gear.

Further, the stirring assembly comprises a stirring gear and a stirring blade, wherein the stirring gear and the stirring gear ring are installed in a meshed mode, and the stirring gear and the stirring blade are fixedly installed.

Further, adjustment mechanism include sideslip subassembly and lifting unit, lifting unit set up on the sideslip subassembly, the sideslip subassembly be used for driving lifting unit reciprocating motion, lifting unit be used for driving sampling mechanism to go up and down.

Compared with the prior art, the invention has the beneficial effects that: (1) According to the invention, the adjusting mechanism is arranged, so that the sampling mechanism can be automatically adjusted to a position to be sampled, and the height of the sampling mechanism can be adjusted, so that water with different depths can be sampled conveniently; (2) According to the invention, through the cooperation of the driving component and the stirring component, the timing and quantitative sampling can be realized by adjusting the position of the sampling component, and the stirring component is driven to stir the wastewater every time the position of the sampling component is adjusted; (3) The invention can automatically sample the filtered and unfiltered wastewater by arranging the sampling component, thereby being suitable for different detection projects.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a schematic structural view of an adjusting mechanism of the present invention.

FIG. 3 is a schematic diagram of a sampling mechanism according to the present invention.

Fig. 4 is a schematic view of a first partial structure of the sampling mechanism.

Fig. 5 is a schematic diagram of a second partial structure of the sampling mechanism.

Fig. 6 is a schematic view of a third partial structure of the sampling mechanism.

FIG. 7 is a schematic diagram of a sampling assembly according to the present invention.

Fig. 8 is a cross-sectional view taken along the direction A-A in fig. 7.

Fig. 9 is a partial enlarged view at B in fig. 8.

Reference numerals: 1-a mobile trolley; 201-a traversing motor; 202-a lead screw; 203-traversing the sliding table; 204-traversing the slide bar; 205-a support base; 206-lifting motor; 207-lifting gear; 208-lifting racks; 301-support ring one; 302-a drive motor; 303-a drive housing; 304-cover plate; 305-synchronous wheel one; 306-synchronizing wheel two; 307-synchronous belt; 308-a drive gear; 309-driving a ring gear; 310-fixing frame; 311-support ring IV; 312-support ring three; 313-support ring two; 314-connecting shaft; 315-stirring the gear ring; 316-stirring gear; 317-stirring limiting plates; 318-stirring blade; 319-drive rod; 320-plugging rod; 321-a plugging plate; 322-arc block one; 323-a connecting rod; 324-slide block; 325-slide bar; 326-a carriage; 327-springs; 328-inner cylinder; 329-an outer cylinder; 330-adjusting the rod; 331-outlet pipe one; 332-a second water outlet pipe; 333-arc block two; 32801-water outlet hole I; 32802-second water outlet; 32803-water inlet.

Detailed Description

The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.

Examples: the sampling device for industrial wastewater detection as shown in fig. 1, 2, 3, 4, 5, 6, 7, 8 and 9 comprises a movable trolley 1, an adjusting mechanism and a sampling mechanism, wherein the adjusting mechanism is fixedly arranged on the movable trolley 1, and the sampling mechanism is fixedly arranged on the adjusting mechanism.

The adjusting mechanism comprises a transverse moving assembly and a lifting assembly, the lifting assembly is arranged on the transverse moving assembly, the transverse moving assembly is used for driving the lifting assembly to reciprocate, and the lifting assembly is used for driving the sampling mechanism to lift.

The transverse moving assembly comprises a transverse moving motor 201, a lead screw 202, a transverse moving sliding table 203 and a transverse moving sliding bar 204, wherein the transverse moving motor 201 is fixedly arranged on a moving trolley 1, an output shaft of the transverse moving motor 201 is fixedly arranged on the lead screw 202, the lead screw 202 is rotatably arranged on the moving trolley 1, the transverse moving sliding bar 204 is fixedly arranged on the moving trolley 1, the transverse moving sliding table 203 is slidably arranged on the transverse moving sliding bar 204, and the transverse moving sliding table 203 and the lead screw 202 are in threaded installation.

The lifting assembly comprises a supporting seat 205, a lifting motor 206, a lifting gear 207 and a lifting rack 208, wherein the lifting motor 206 is fixedly arranged on the transverse sliding table 203, an output shaft of the lifting motor 206 is fixedly arranged on the lifting gear 207, the lifting gear 207 is meshed with the lifting rack 208, the lifting rack 208 is fixedly arranged on the supporting seat 205, and the supporting seat 205 is slidably arranged on the transverse sliding table 203.

The sampling mechanism comprises a driving component, a stirring component and a sampling component, wherein the driving component is fixedly arranged on the adjusting mechanism, the stirring component and the sampling component are arranged on the driving component, the stirring component is provided with four groups, the sampling component is provided with six groups, and the driving component is used for enabling the sampling component and the stirring component to synchronously move.

The driving assembly comprises a supporting unit and a power unit, wherein the supporting unit is fixedly arranged on the supporting seat 205, and the power unit is arranged on the supporting unit.

The support unit comprises a first support ring 301, a cover plate 304, a fixing frame 310, a fourth support ring 311, a third support ring 312 and a second support ring 313, wherein the first support ring 301, the second support ring 313, the third support ring 312 and the fourth support ring 311 are sequentially and fixedly arranged on the fixing frame 310, the first support ring 301 is fixedly arranged on the support seat 205, the first support ring 301 and the second support ring 313 enclose a first sliding groove, the sliding groove between the first support ring 301 and the second support ring 313 comprises an annular sliding groove and a V-shaped sliding groove, the second support ring 313 and the third support ring 312 enclose a second sliding groove, the second support ring 313 and the third support ring 312 are annular sliding grooves, the third support ring 312 and the fourth support ring 311 are annular sliding grooves, and the cover plate 304 and the fixing frame 310 are fixedly arranged.

The power unit comprises a driving motor 302, a driving housing 303, a first synchronizing wheel 305, a second synchronizing wheel 306, a synchronous belt 307, a driving gear 308, a driving gear ring 309, a connecting shaft 314 and a stirring gear ring 315, wherein the driving housing 303 is fixedly arranged on a cover plate 304, the driving motor 302 is fixedly arranged on the driving housing 303, an output shaft of the driving motor 302 and the second synchronizing wheel 306 are fixedly arranged, the synchronous belt 307 is sleeved on the second synchronizing wheel 306 and the first synchronizing wheel 305, the second synchronizing wheel 306 and the first synchronizing wheel 305 are in transmission through the synchronous belt 307, the first synchronizing wheel 305 and the connecting shaft 314 are fixedly arranged, the second synchronizing wheel 306 and the driving gear 308 are fixedly arranged, the driving gear 308 and the driving gear ring 309 are in meshing installation, the driving gear ring 309 and the arc-shaped block 322 are fixedly arranged, the connecting shaft 314 is rotatably arranged on the cover plate 304, the connecting shaft 314 cannot slide along the axial direction of the connecting shaft 314, and the stirring gear ring is fixedly arranged on the connecting shaft 315.

The stirring subassembly includes stirring gear 316, stirring limiting plate 317 and stirring vane 318, and stirring limiting plate 317 fixed mounting is on support ring one 301, and stirring gear 316 rotates to be installed on stirring limiting plate 317, and stirring gear 316 and stirring ring gear 315 meshing installation, stirring gear 316 and stirring vane 318 coaxial fixed mounting.

The sampling assembly comprises a driving unit, a plugging unit, an inner cylinder 328, an outer cylinder 329, an adjusting rod 330, a first water outlet pipe 331 and a second water outlet pipe 332, wherein the driving unit is arranged on the driving assembly, the plugging unit is arranged on the driving unit, the adjusting rod 330 is fixedly arranged on the outer cylinder 329, the adjusting rod 330 is slidably arranged in the first sliding groove, the inner cylinder 328 is slidably arranged in the outer cylinder 329, tracks are arranged on two sides of the inner cylinder 328, a linear sliding groove is arranged in the inner cylinder 329 in the length direction, tracks on two sides of the inner cylinder 328 are slidably arranged on the linear sliding groove of the outer cylinder 329, a second water outlet pipe 332 and a first water outlet pipe 331 are arranged on the outer cylinder 329, a filter screen is arranged in the second water outlet 332, a plurality of water inlet holes 32803 are formed in the circumference of the inner cylinder 328, a first water outlet 32801 and a second water outlet 32802 are further arranged on the inner cylinder 328, and the first water outlet 32801 and the second water outlet 32802 are respectively communicated with the first water outlet 331 and the second water outlet 332.

The driving unit comprises a driving rod 319, arc-shaped blocks 322, a connecting rod 323, a sliding block 324, a sliding rod 325, a sliding frame 326 and arc-shaped blocks 333, wherein the driving rod 319 is in sliding installation in the third sliding groove, two arc-shaped blocks 322 are fixedly installed at the end part of the driving rod 319, the two arc-shaped blocks 322 are respectively attached to the inner side and the outer side of the supporting ring IV 311, the sliding rod 325 is fixedly installed on the driving rod 319, the sliding block 324 is in sliding installation on the sliding rod 325, the connecting rod 323 is fixedly installed on the sliding block 324, the arc-shaped blocks 333 are fixedly installed at the end part of the connecting rod 323, the arc-shaped blocks 333 are attached to the inner side of the supporting ring III 312, the connecting rod 323 is in sliding installation in the second sliding groove, the sliding frame 326 is further in sliding installation on the sliding rod 325, and the sliding frame 326 and the outer cylinder 329 are fixedly installed.

The shutoff unit includes shutoff pole 320, shutoff board 321 and spring 327, and shutoff pole 320 slidable mounting on slider 324, shutoff pole 320 still slidable mounting on actuating lever 319, and the tip fixed mounting of shutoff pole 320 has shutoff board 321, shutoff board 321 and inner tube 328 fixed mounting, and spring 327 overlaps to be established on shutoff pole 320, and the first end fixed mounting of spring 327 is on slider 324, and the second end fixed mounting of spring 327 is on shutoff board 321.

The working principle of the invention is as follows: the mobile trolley 1 can automatically move to a sampling point, and the depth and the position of sampling are adjusted by an adjusting mechanism; the transverse moving motor 201 is started, the transverse moving motor 201 drives the lead screw 202 to rotate, and the lead screw 202 drives the transverse moving sliding table 203 to slide on the transverse moving sliding rod 204, so that the position of the sampling mechanism can be adjusted; the lifting motor 206 is started, the lifting motor 206 drives the lifting gear 207 to rotate, and the lifting gear 207 drives the lifting rack 208 and the supporting seat 205 to descend, so that the depth of the sampling mechanism can be adjusted.

Starting a driving motor 302, driving the driving motor 302 to drive a synchronous wheel II 306 to rotate, driving a synchronous wheel I305 to rotate by a synchronous belt 307 by the synchronous wheel II 306, driving a stirring gear ring 315 to rotate by a connecting shaft 314 by the synchronous wheel I305, and driving a stirring gear 316 and stirring blades 318 to rotate by the stirring gear ring 315, so that stirring of industrial wastewater can be realized, and the sampled parts are uniformly mixed, so that the obtained water sample is representative; while stirring vane 318 rotates, driving motor 302 drives synchronizing wheel two 306 to rotate, synchronizing wheel two 306 drives driving gear 308 to rotate, driving gear 308 drives driving gear ring 309 to rotate, driving gear ring 309 drives six arc pieces one 322 to synchronously rotate, arc pieces one 322 drive the sampling assembly to rotate, and the position of sampling assembly can be adjusted, timing and quantitative sampling is realized by adjusting the position of sampling assembly, and each time the position of sampling assembly is adjusted, stirring assembly is driven to stir wastewater.

During sampling, the inner cylinder 328 is moved below the water surface, the first arc-shaped block 322 drives the driving rod 319 to move, the driving rod 319 drives the sliding rod 325, the sliding block 324, the connecting rod 323, the second arc-shaped block 333, the sliding frame 326, the outer cylinder 329, the adjusting rod 330 and the inner cylinder 328 to move, the connecting rod 323 slides in the second sliding groove, the adjusting rod 330 slides in the first sliding groove, after the adjusting rod 330 slides in the V-shaped sliding groove, the adjusting rod 330 drives the outer cylinder 329 to descend until the water inlet 32803 is exposed, water enters the inner cylinder 328 from the water inlet 32803, when the outer cylinder 329 moves upwards, the water inlet 32803 is blocked, then the outer cylinder 329 drives the inner cylinder 328 to move, at the moment, the first water outlet 331 is not communicated with the first water outlet 32801, and the second water outlet 332 is not communicated with the second water outlet 32802.

When detection is needed, the adjusting rod 330 drives the outer cylinder 329 to descend, the first water outlet pipe 331 is communicated with the first water outlet hole 32801, the second water outlet pipe 332 is not communicated with the second water outlet hole 32802, unfiltered water flows out, the second water outlet pipe 332 is continuously descended by the outer cylinder 329 to be communicated with the second water outlet hole 32802, the first water outlet pipe 331 is not communicated with the first water outlet hole 32801, a filter screen is arranged on the second water outlet pipe 332, and filtered water flows out from the second water outlet pipe 332.

Claims (8)

1. The utility model provides an industrial waste water detects uses sampling device, includes travelling car (1), adjustment mechanism and sampling mechanism, its characterized in that: the adjusting mechanism is arranged on the mobile trolley (1), and the sampling mechanism is arranged on the adjusting mechanism;

the sampling mechanism comprises a driving assembly, a stirring assembly and a sampling assembly, wherein the driving assembly is arranged on the adjusting mechanism, a plurality of groups of sampling assemblies are arranged on the adjusting mechanism, the stirring assembly and the sampling assembly are arranged on the adjusting mechanism, and the driving assembly is used for enabling the sampling assembly and the stirring assembly to synchronously move;

the sampling assembly comprises a driving unit, a plugging unit, an inner cylinder (328) and an outer cylinder (329), an adjusting rod (330), wherein the driving unit is arranged on the driving assembly, the plugging unit is arranged on the driving unit, the outer cylinder (329) is fixedly provided with the adjusting rod (330), the inner cylinder (328) is slidably arranged in the outer cylinder (329), the outer cylinder (329) is provided with a second water outlet pipe (332) and a first water outlet pipe (331), a plurality of water inlet holes (32803) are formed in the circumference of the inner cylinder (328), a first water outlet hole (32801) and a second water outlet hole (32802) are further formed in the inner cylinder (328), and the first water outlet hole (32801) and the second water outlet hole (32802) are respectively communicated with the first water outlet pipe (331) and the second water outlet pipe (332).

2. A sampling device for industrial wastewater detection as claimed in claim 1, wherein: the driving unit comprises a driving rod (319), a sliding block (324), a sliding rod (325) and a sliding frame (326), wherein the driving rod (319) is fixedly provided with the sliding rod (325), the sliding rod (325) is provided with the sliding block (324) in a sliding mode, the sliding block (324) is fixedly provided with the connecting rod (323), the sliding rod (325) is further provided with the sliding frame (326) in a sliding mode, and the sliding frame (326) and the outer barrel (329) are fixedly arranged.

3. A sampling device for industrial wastewater detection as claimed in claim 2, wherein: the plugging unit comprises a plugging rod (320) and a plugging plate (321), wherein the plugging rod (320) is slidably mounted on a sliding block (324), the plugging rod (320) is slidably mounted on a driving rod (319), the plugging plate (321) is fixedly mounted at the end part of the plugging rod (320), and the plugging plate (321) and the inner cylinder (328) are fixedly mounted.

4. A sampling device for industrial wastewater detection as claimed in claim 3, wherein: the driving assembly comprises a supporting unit and a power unit, wherein the supporting unit is arranged on the adjusting mechanism, and the power unit is arranged on the supporting unit.

5. The sampling device for industrial wastewater detection as claimed in claim 4, wherein: the supporting unit comprises a first supporting ring (301), a cover plate (304), a fixing frame (310), a fourth supporting ring (311), a third supporting ring (312) and a second supporting ring (313), wherein the first supporting ring (301), the second supporting ring (313), the third supporting ring (312) and the fourth supporting ring (311) are sequentially and fixedly installed on the fixing frame (310), and the cover plate (304) and the fixing frame (310) are fixedly installed.

6. The sampling device for industrial wastewater detection as claimed in claim 5, wherein: the power unit comprises a driving gear (308), a driving gear ring (309), a connecting shaft (314) and a stirring gear ring (315), wherein the driving gear (308) and the driving gear ring (309) are installed in a meshed mode, the driving gear (308) is driven through a synchronous belt and the connecting shaft (314), and the stirring gear ring (315) is fixedly installed on the connecting shaft (314).

7. A sampling device for industrial wastewater detection as claimed in claim 1, wherein: the stirring assembly comprises a stirring gear (316) and a stirring blade (318), wherein the stirring gear (316) and the stirring gear ring (315) are installed in a meshed mode, and the stirring gear (316) and the stirring blade (318) are fixedly installed.

8. A sampling device for industrial wastewater detection as claimed in claim 1, wherein: the adjusting mechanism comprises a transverse moving assembly and a lifting assembly, wherein the lifting assembly is arranged on the transverse moving assembly, the transverse moving assembly is used for driving the lifting assembly to reciprocate, and the lifting assembly is used for driving the sampling mechanism to lift.