CN220231714U - Monitoring facilities for ecological environment monitoring experiments - Google Patents

Abstract

The utility model provides a monitoring facilities for ecological environment monitoring experiments, including the base case, base case internally mounted sliding is equipped with multiunit sample tube, the lateral wall passes the connection and is equipped with the screwed pipe on the base case, the screwed pipe outside is connected and is equipped with the nut, nut inner wall middle part is equipped with annular spout, the inboard relative both sides of annular spout slide are equipped with the slider respectively, two sets of sliders one side are connected respectively and are equipped with the connecting rod, be equipped with the spout respectively on the relative both sides wall of screwed pipe, two sets of connecting rod other ends pass the spout respectively and connect between and be equipped with monitoring facilities, the base case upside is connected and is equipped with the support frame, support frame upside installation is equipped with control panel. Compared with the prior art, the utility model has the advantages that: each group of sample tubes corresponds to one group of monitoring mechanisms, can monitor the river water in the sample tubes with different reactions, and the nuts are rotated outside the threaded tubes to enable the nuts to move up and down, so that the monitoring mechanisms are driven to move up and down, and the height of the water quality monitor in the sample tubes is adjusted.

Description

Monitoring facilities for ecological environment monitoring experiments

Technical Field

The utility model relates to the technical field of ecological environment monitoring, in particular to monitoring equipment for an ecological environment monitoring experiment.

Background

The ecological environment pollution of the river channel is mainly caused by human activities, substances or energy are directly or indirectly introduced into the river environment, so that the harmful effects of damaging river biological resources, damaging river water and river environment quality, harming human health and the like are caused, the pollution degree changes along with time, the diffusion is fast, the pollution effect is large, and in order to avoid the river channel from being excessively polluted, and in order to suppress the pollution in the stage with the lowest harm, workers need to monitor the water quality of the river channel from time to time.

When the laboratory monitors the river water quality, the river water quality is usually put into a plurality of groups of sample pipes, different reaction reagents are added to generate different reactions with the river water, the river water is detected, a plurality of groups of detection equipment is usually directly inserted into the sample pipes to monitor the river water, but the river water can be layered in the sample pipes, the detection equipment cannot conveniently adjust the height in the sample pipes, and the river water with different layered heights cannot be monitored, so that the laboratory river water monitoring device is inconvenient to use.

Disclosure of Invention

The utility model provides monitoring equipment for ecological environment monitoring experiments, which comprises a bottom box, wherein a box door is arranged on the front side of the bottom box, a plurality of groups of sample tubes are slidably arranged in the bottom box, threaded tubes are respectively arranged on the upper side wall of the bottom box and right above the plurality of groups of sample tubes in a penetrating mode, nuts are arranged on the outer sides of the threaded tubes in a matched threaded mode, annular sliding grooves are formed in the middle of the inner wall of the nuts, sliding blocks are respectively arranged on the opposite sides of the inner sides of the annular sliding grooves in a sliding mode, connecting rods are respectively arranged on the two sides of the inner sides of the annular sliding grooves in a connecting mode, sliding grooves matched with the sliding connecting rods are respectively arranged on the opposite side walls of the threaded tubes, monitoring mechanisms are respectively arranged on the other ends of the two groups of the connecting rods in a penetrating through the sliding grooves in a connecting mode, a supporting frame is arranged on the upper side of the bottom box in a connecting mode, a control panel is arranged on the upper side of the supporting frame in a connecting mode, and a display is arranged on the rear portion of the upper side of the supporting frame in a connecting mode.

As an improvement: the multi-group sample tube is characterized in that a supporting transverse plate is sleeved between the outer sides of the sample tubes in a sliding manner, positioning tubes which are matched with the sample tubes to pass through are arranged on the supporting transverse plate, and limiting sliding grooves which are matched with the supporting transverse plate are respectively arranged on the upper parts of the inner walls of the left side and the right side of the bottom box.

As an improvement: an auxiliary transverse plate is connected between the lower parts of the inner walls of the left side and the right side of the bottom box, and a plurality of groups of limit U-shaped grooves matched with the sample tubes are formed in the front side of the auxiliary transverse plate.

As an improvement: the monitoring mechanism comprises a control box, a round pipe is connected to the lower side of the control box, a water quality monitor is connected to the lower end of the round pipe, and a connecting wire is connected to the upper side of the control box.

As an improvement: the upper end of the connecting wire is connected with the corresponding plate of the control panel, and the connecting wire is of an elastic spiral structure.

As an improvement: the sliding block is of an arc-shaped structure, a plurality of groups of balls are uniformly embedded in the side wall of the sliding block in a rotating mode, and the plurality of groups of balls are respectively contacted with the inner wall of the annular sliding groove.

Compared with the prior art, the utility model has the advantages that: the multiunit sample tube is installed simultaneously inside the base box, and every group sample tube corresponds a set of monitoring mechanism, can monitor the inside river of sample tube that takes place different reactions simultaneously, rotates in the screwed pipe outside through the nut, makes the nut reciprocate to drive monitoring mechanism reciprocates, adjust the height of water quality monitor inside the sample tube, can monitor the river of different co-altitude, convenient operation.

Drawings

FIG. 1 is a schematic structural diagram of a monitoring device for ecological environment monitoring experiments;

FIG. 2 is a front view of a monitoring device for ecological environment monitoring experiments according to the present utility model;

FIG. 3 is a schematic view of the inner side structure of a nut of the monitoring device for ecological environment monitoring experiments;

FIG. 4 is a schematic diagram of a monitoring mechanism of the monitoring device for ecological environment monitoring experiments;

the attached label is a comparison table:

1. a bottom box; 2. a door; 3. limiting sliding grooves; 4. a supporting cross plate; 5. a positioning tube; 6. a sample tube; 7. an auxiliary cross plate; 8. a limit U-shaped groove; 9. a threaded tube; 10. a nut; 11. a monitoring mechanism; 11.1, a control box; 11.2, round tube; 11.3, a water quality monitor; 11.4, connecting wires; 12. an annular chute; 13. a slide block; 14. a connecting rod; 15. a ball; 16. a chute; 17. a support frame; 18. a control panel; 19. a display.

Detailed Description

Specific embodiments of the present utility model will be further described below with reference to the accompanying drawings.

As shown in fig. 1-4, a monitoring device for ecological environment monitoring experiments comprises a bottom box 1, the front side of the bottom box 1 is provided with a box door 2, the inside slidable mounting of the bottom box 1 is provided with a plurality of groups of sample tubes 6, the upper side wall of the bottom box 1 and the parts right above the plurality of groups of sample tubes 6 are respectively provided with threaded tubes 9 through connection, threaded connection is provided with nuts 10 in the outer side of the threaded tubes 9, the middle part of the inner wall of each nut 10 is provided with an annular sliding groove 12, two groups of sliding blocks 13 are respectively provided with sliding blocks 13 in a sliding manner, one side of each sliding block 13 close to each other is respectively connected with a connecting rod 14, the two groups of sliding grooves 16 matched with the sliding of the connecting rods 14 are respectively arranged on the two opposite side walls of the threaded tubes 9, the other ends of each connecting rod 14 respectively penetrate through the sliding grooves 16 and are connected with a monitoring mechanism 11, the upper side of the bottom box 1 is provided with a supporting frame 17, a control panel 18 is arranged on the upper side of the supporting frame 17, the rear part of the supporting frame 17 is connected with a display 19, different reflecting reagents are added into the plurality of the sample tubes 6 to react, the threaded tubes 9 are placed on the lower side of the corresponding relevant monitoring mechanism, the nuts 10 are rotated, the nuts 10 are driven by the nuts 10 to move to the corresponding monitoring mechanism, the nuts 10 are driven by the nuts 10 to move the appropriate side of the nuts 10 to the appropriate side and the nuts 10 to the inner side of the monitoring mechanism through the sliding mechanism and the sliding mechanism through the sliding grooves and the nuts 10 to the appropriate side and the sliding mechanism.

The multi-group sample tube 6 is provided with a supporting transverse plate 4 in a sliding sleeve manner between the outer sides, the supporting transverse plate 4 is provided with a positioning tube 5 which is matched with the sample tube 6 to pass through, the upper parts of the inner walls of the left side and the right side of the bottom box 1 are respectively provided with a limiting chute 3 which is matched with the supporting transverse plate 4, the sample tube 6 containing river water and reaction reagents passes through the positioning tube 5, the upper part of the sample tube is supported on the upper side of the positioning tube 5, after the sample tube 6 is correspondingly installed, the box door 2 is opened, the supporting transverse plate 4 is aligned with the limiting chute 3 and inserted into the limiting chute 3, the supporting transverse plate 4 moves towards the inside of the bottom box 1, the supporting transverse plate 4 moves to the bottom of the limiting chute 3, and the sample tube 6 corresponds to a matched monitoring mechanism 11.

The connection is equipped with supplementary diaphragm 7 between the inner wall lower part of the left and right sides of base case 1, supplementary diaphragm 7 front side is equipped with spacing U type groove 8 of multiunit cooperation sample cell 6, and sample cell 6 lower part removes to U type inslot 8, and U type inslot 8 is inside to be equipped with the rubber cushion, sends out horizontal rocking when preventing sample cell 6 removal.

As shown in fig. 4, the monitoring mechanism 11 includes a control box 11.1, a circular tube 11.2 is connected to the lower side of the control box 11.1, a water quality monitor 11.3 is connected to the lower end of the circular tube 11.2, a connecting wire 11.4 is connected to the upper side of the control box 11.1, the water quality monitor 11.3 is inserted into the sample tube 6 to monitor river, and the connecting wire passes through the circular tube 11.2 and is connected with the control box 11.1.

The upper end of the connecting wire 11.4 is connected with a corresponding plate of the control panel 18, the connecting wire 11.4 is of an elastic spiral structure, when the monitoring mechanism 11 moves up and down, the connecting wire 11.4 can be pulled to be unfolded, the control box 11.1 is connected with the control panel 18 through the connecting wire 11.4, and the control box 11.1 is controlled through the control panel 18.

The sliding block 13 is of an arc-shaped structure, a plurality of groups of balls 15 are uniformly embedded in the side wall of the sliding block 13 in a rotating mode, the plurality of groups of balls 15 are respectively contacted with the inner wall of the annular sliding groove 12, the sliding block 13 is ensured to stably slide in the annular sliding groove 12 through the plurality of groups of balls 15, and the moving resistance is small.

The above description is illustrative of the preferred embodiments of the present utility model and is not intended to limit the scope of the present utility model, but is to be accorded the full scope of the claims.

Claims (6)

1. The utility model provides a monitoring facilities for ecological environment monitoring experiments, includes base box (1), base box (1) front side is equipped with chamber door (2), its characterized in that: the inside slidable mounting of base case (1) is equipped with multiunit sample pipe (6), lateral wall just is located multiunit sample pipe (6) and passes respectively and connect directly over being equipped with screwed pipe (9), screwed pipe (9) outside cooperation threaded connection is equipped with nut (10), nut (10) inner wall middle part is equipped with annular spout (12), the inboard opposite sides of annular spout (12) are the slip respectively and are equipped with slider (13), two sets of one side that slider (13) are close to is connected respectively and is equipped with connecting rod (14), be equipped with respectively on screwed pipe (9) opposite both sides wall cooperation connecting rod (14) gliding spout (16), two sets of connecting rod (14) other end are passed spout (16) respectively and are connected between and are equipped with monitoring mechanism (11), base case (1) upside connection is equipped with support frame (17), support frame (17) upside installation is equipped with control panel (18), support frame (17) upside rear connection is equipped with display (19).

2. The monitoring device for ecological environment monitoring experiments according to claim 1, wherein: the multi-group sample tube (6) is slidably sleeved with a supporting transverse plate (4), positioning tubes (5) which are matched with the sample tubes (6) to pass through are arranged on the supporting transverse plate (4), and limiting sliding grooves (3) matched with the supporting transverse plate (4) are respectively arranged on the upper parts of the inner walls of the left side and the right side of the bottom box (1).

3. The monitoring device for ecological environment monitoring experiments according to claim 1, wherein: an auxiliary transverse plate (7) is connected between the lower parts of the inner walls of the left side and the right side of the bottom box (1), and a plurality of groups of limit U-shaped grooves (8) matched with the sample tubes (6) are formed in the front side of the auxiliary transverse plate (7).

4. The monitoring device for ecological environment monitoring experiments according to claim 1, wherein: the monitoring mechanism (11) comprises a control box (11.1), a circular tube (11.2) is connected to the lower side of the control box (11.1), a water quality monitor (11.3) is connected to the lower end of the circular tube (11.2), and a connecting wire (11.4) is connected to the upper side of the control box (11.1).

5. The monitoring device for ecological environment monitoring experiments according to claim 4, wherein: the upper end of the connecting wire (11.4) is connected with a corresponding plate of the control panel (18), and the connecting wire (11.4) is of an elastic spiral structure.

6. The monitoring device for ecological environment monitoring experiments according to claim 1, wherein: the sliding block (13) is of an arc-shaped structure, a plurality of groups of balls (15) are uniformly embedded in the side wall of the sliding block (13) in a rotating mode, and the plurality of groups of balls (15) are respectively contacted with the inner wall of the annular sliding groove (12).