CN214675330U - Device for monitoring biological slime of circulating water system - Google Patents

Abstract

The utility model discloses a device for circulating water system biological slime monitoring, include: the main body assembly comprises an arc-shaped plate, a second shell, a third baffle, a fourth baffle, a submersible motor, a transmission rod, a stirring blade, a camera and a second net body; the buffer assembly comprises fixed blocks, a fixed rod, a pipe body, a spring, a third shell, a supporting rod and a fourth shell, wherein eight fixed blocks are symmetrically welded on the outer side wall of the second shell; the utility model discloses a setting of arc can protect the inside structure of arc, and when the arc received the striking, the arc exerted pressure to the spring through the conduction of fourth casing, bracing piece isotructure, and the spring can slow down the external pressure of applying and produce the thrust after receiving pressure, makes the arc reset to reduce the pressure that the striking brought, avoid monitoring structures such as first PLC controller and camera impaired.

Description

Device for monitoring biological slime of circulating water system

Technical Field

The utility model relates to a biological slime monitoring facilities technical field specifically is a device that is used for circulating water system biological slime monitoring.

Background

In the circulating water, the concentration of nutrients, the rise of water temperature and the irradiation of sunlight create a condition for the bacteria and algae to rapidly reproduce. The mucus secreted by a large amount of bacteria can adhere dust impurities, chemical sediments and the like floating in water like a binder, and the sediments forming sticky paste are attached to the heat transfer surface of the heat exchanger. This deposit is sometimes referred to as biofouling and sometimes as limescale.

To the biological slime that produces in the water system need clear up in order to ensure quality of water and the smoothness of water system, need use monitoring facilities to monitor for this reason to learn whether to have biological slime in the pipeline, current monitoring facilities mostly utilize remote control unit control camera to monitor inside the pipeline, but have following defect when in actual use:

when equipment in a control pipe runs, the equipment is inevitably impacted on the inner wall of the pipeline due to control technology or water flow impact, so that monitoring structures such as a camera and the like are easily damaged, and monitoring work is influenced;

secondly, when the equipment in the pipe runs, floating objects are easily wound on the stirring blades, so that the stirring blades cannot rotate and the normal running of the equipment is influenced; therefore, the device for monitoring the biological slime of the circulating water system is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a device for circulating water system biological slime monitoring to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: an apparatus for circulating water system biological slime monitoring, comprising:

the main body assembly comprises an arc-shaped plate, a second shell, a third baffle, a fourth baffle, a submersible motor, a transmission rod, a stirring blade, a camera and a second net body;

the buffer assembly comprises fixed blocks, fixed rods, pipe bodies, springs, a third shell, supporting rods and a fourth shell, eight fixed blocks are symmetrically welded on the outer side wall of the second shell, the fixed rods are welded on one side, adjacent to two horizontally adjacent fixed blocks, of the side, adjacent to the two fixed blocks, of the fixed rods, the springs and the two pipe bodies are respectively sleeved on the outer sides of the fixed rods, two ends of each spring are respectively welded on one side, adjacent to the two adjacent pipe bodies, of the outer side wall of each pipe body, the third shell is welded on the outer side wall of each pipe body, the supporting rods are hinged inside the third shell, one end, far away from the third shell, of each supporting rod is hinged to the fourth shell, and one side, far away from the supporting rods, of the fourth shell is welded on the inner side wall of the adjacent arc-shaped plate;

the control assembly comprises a fifth shell, a second partition plate, a first PLC (programmable logic controller), a first signal transceiver, a sixth shell, a second signal transceiver, a second PLC and a touch display screen.

As further preferable in the present technical solution: the outside cover of second casing is equipped with four arcs, one side threaded connection of second casing has the third baffle, the third baffle is kept away from the camera is installed to one side of second casing, the inside wall welding of second casing has the fourth baffle, the inside of second casing is equipped with submersible motor, submersible motor's output shaft fixedly connected with transfer line, the transfer line is kept away from submersible motor's one end is run through the lateral wall of second casing, the lateral wall of transfer line pass through the bearing rotate connect in the inside of second casing, the welding of the lateral wall equidistance circumference of transfer line has the stirring leaf, one side threaded connection of fifth casing has first baffle, four equal fixedly connected with second dictyosome between the adjacent one side of arc.

As further preferable in the present technical solution: the utility model discloses a touch-control display screen, including sixth casing, second baffle, first signal transceiver, second signal transceiver, touch-control display screen, second recess has been seted up to the bottom of sixth casing.

As further preferable in the present technical solution: the bottom threaded connection of dive motor has first casing, one side fixed connection of first casing in the inside wall of second casing.

As further preferable in the present technical solution: one end of each of the four arc-shaped plates is in threaded connection with a first net body, and the other ends of the four arc-shaped plates are bonded with arc-shaped covers.

As further preferable in the present technical solution: the inside threaded connection of fifth casing has first battery, the inside wall threaded connection of sixth casing has first baffle, the inside wall threaded connection of sixth casing has the second battery.

As further preferable in the present technical solution: the bottom threaded connection of sixth casing has the second baffle, first USB charges the mouth is installed to the bottom of second baffle, first switch is installed to one side of sixth casing.

As further preferable in the present technical solution: one first recess has been seted up to the lateral wall of arc, second USB charges mouthful and second switch are installed respectively to the inside wall of first recess, the inside wall sliding connection of first recess has the flap, one side of flap bonds there is the block rubber.

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

the utility model discloses a through the setting of arc, can protect the structure in the arc, when the arc received the striking, the arc exerted pressure to the spring through the conduction of structures such as fourth casing, bracing piece, the spring can slow down the pressure that the external world was exerted and produce the thrust that reverses after receiving pressure, impel the arc to reset to reduce the pressure that the striking brought, avoid monitoring structures such as first PLC controller and camera impaired;

two, the utility model discloses a setting of arc, arc cover and second dictyosome, the use of the first dictyosome of cooperation can protect stirring leaf and transfer line from the outside, avoids stirring leaf and transfer line winding floater to lead to unable rotation, ensures the utility model discloses a normal operating.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged schematic view of the area A of FIG. 1 according to the present invention;

FIG. 3 is an enlarged schematic view of a region B in FIG. 1 according to the present invention;

fig. 4 is a schematic side view of the present invention;

fig. 5 is a left side view schematic structure diagram of the present invention;

fig. 6 is a schematic side view of a sixth housing according to the present invention;

fig. 7 is a circuit diagram of the first PLC controller of the present invention.

In the figure: 1. a first baffle plate; 2. a first housing; 3. a first storage battery; 4. a first separator; 5. a second storage battery; 6. an arc-shaped cover; 7. a first net body; 8. a first switch; 9. a second baffle; 10. a body assembly; 11. an arc-shaped plate; 12. a second housing; 13. a third baffle plate; 14. a fourth baffle; 15. a submersible motor; 16. a transmission rod; 17. stirring blades; 18. a camera; 19. a second mesh body; 20. a buffer assembly; 21. a fixed block; 22. fixing the rod; 23. a pipe body; 24. a spring; 25. a third housing; 26. a support bar; 27. a fourth housing; 30. a control component; 31. a fifth housing; 32. a second separator; 33. a first PLC controller; 34. a first signal transceiver; 35. a sixth housing; 36. a second signal transceiver; 37. a second PLC controller; 38. a touch display screen; 40. a blocking cover; 41. a rubber block; 42. a first USB charging port; 43. a first groove; 44. a second USB charging port; 45. a second switch; 46. a second groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

Referring to fig. 1-7, the present invention provides a technical solution: an apparatus for circulating water system biological slime monitoring, comprising:

the main body assembly 10 comprises an arc-shaped plate 11, a second shell 12, a third baffle 13, a fourth baffle 14, a submersible motor 15, a transmission rod 16, a stirring blade 17, a camera 18 and a second net body 19;

buffer assembly 20, buffer assembly 20 includes fixed block 21, the dead lever 22, the body 23, spring 24, third casing 25, bracing piece 26 and fourth casing 27, eight fixed blocks 21 have been welded to the lateral wall symmetry of second casing 12, the dead lever 22 has been welded to the adjacent one side of two fixed blocks 21 of level adjacent, the outside of dead lever 22 overlaps respectively and is equipped with spring 24 and two bodies 23, the both ends of spring 24 weld in the adjacent one side of two adjacent bodies 23 respectively, the lateral wall welding of body 23 has third casing 25, the inside of third casing 25 articulates there is bracing piece 26, the one end that third casing 25 was kept away from to bracing piece 26 articulates there is fourth casing 27, the one side that bracing piece 26 was kept away from to fourth casing 27 welds in the inside wall of adjacent arc 11;

the control assembly 30, the control assembly 30 includes a fifth housing 31, a second partition 32, a first PLC controller 33, a first signal transceiver 34, a sixth housing 35, a second signal transceiver 36, a second PLC controller 37 and a touch display screen 38.

In this embodiment, specifically: the outer part of the second shell 12 is sleeved with four arc-shaped plates 11, one side of the second shell 12 is in threaded connection with a third baffle 13, one side, far away from the second shell 12, of the third baffle 13 is provided with a camera 18, the inner side wall of the second shell 12 is welded with a fourth baffle 14, the inner part of the second shell 12 is provided with a submersible motor 15, an output shaft of the submersible motor 15 is fixedly connected with a transmission rod 16, one end, far away from the submersible motor 15, of the transmission rod 16 penetrates through the outer side wall of the second shell 12, the outer side wall of the transmission rod 16 is rotatably connected into the second shell 12 through a bearing, stirring blades 17 are welded on the outer side wall of the transmission rod 16 at equal intervals in circumference, and second net bodies 19 are fixedly connected between adjacent sides of the four arc-shaped plates 11; can drive stirring leaf 17 rotatory through transfer line 16 after dive motor 15 starts, thereby promote rivers, make second casing 12 remove, setting through fourth casing 27, can have the effect of protection to inner structure such as dive motor 15, setting through camera 18, can monitor water system, setting through second dictyosome 19 can avoid the floater to get into the inside of arc 11 from the gap between the arc 11, avoid floater winding transfer line 16 and stirring leaf 17.

In this embodiment, specifically: a fifth shell 31 is welded on the inner side wall of the second shell 12, the inner side wall of the fifth shell 31 is connected with a second partition plate 32 through screw threads, a first PLC 33 is installed on one side of the second partition plate 32, a first signal transceiver 34 is installed on the outer side wall of the second shell 12, a touch display screen 38 is installed on the inner side wall of a sixth shell 35, and a second groove 46 is formed in the bottom of the sixth shell 35; the first storage battery 3 and the first PLC controller 33 are conveniently stored through the arrangement of the fifth shell 31, a monitoring instruction can be sent through the touch display screen 38, the second PLC controller 37 receives the monitoring instruction and then sends the monitoring instruction to the first signal transceiver 34 through the second signal transceiver 36, the first signal transceiver 34 receives the monitoring instruction and then sends the monitoring instruction to the first PLC controller 33, the first PLC controller 33 starts the submersible motor 15, so that the submersible motor 15 drives the stirring blades 17 to rotate through the transmission rod 16, so that the second shell 12 is pushed to move, simultaneously, utilize camera 18 to monitor in the pipeline, utilize first signal transceiver 34 to send the condition of pipeline inner wall to second signal transceiver 36 through first PLC controller 33, second signal transceiver 36 receives the information after and shows through touch-control display screen 38 behind the second PLC controller 37 to carry out the monitoring work of circulating water system biological slime.

In this embodiment, specifically: the bottom of the submersible motor 15 is in threaded connection with a first shell 2, one side of the first shell 2 is fixedly connected to the inner side wall of the second shell 12, and one side of the fifth shell 31 is in threaded connection with a first baffle plate 1; the first housing 2 has a supporting function for the submersible motor 15, and the first baffle 1 has a blocking function for the fifth housing 31.

In this embodiment, specifically: one end threaded connection of four arcs 11 has first dictyosome 7, and the other end of four arcs 11 bonds has arc cover 6, through the setting of first dictyosome 7, can block aquatic floater, avoids floater winding transfer line 16 and stirring leaf 17, through the setting of arc cover 6, utilizes curved physique can have the guide effect to the rivers of impact, reduces the resistance that rivers brought.

In this embodiment, specifically: the first storage battery 3 is connected to the inner thread of the fifth shell 31, the first partition plate 4 is connected to the inner side wall of the sixth shell 35 in a threaded manner, and the second storage battery 5 is connected to the inner side wall of the sixth shell 35 in a threaded manner; the first PLC controller 33 can be supplied with power by the setting of the first battery 3, and the second PLC controller 37 can be supplied with power by the setting of the second battery 5.

In this embodiment, specifically: a second baffle 9 is connected to the bottom of the sixth shell 35 in a threaded manner, a first USB charging port 42 is installed at the bottom of the second baffle 9, and a first switch 8 is installed at one side of the sixth shell 35; through the setting of first USB mouth 42 that charges, be convenient for charge second battery 5, through the setting of first switch 8, be convenient for start second PLC controller 37 operation.

In this embodiment, specifically: a first groove 43 is formed in the outer side wall of one arc-shaped plate 11, a second USB charging port 44 and a second switch 45 are respectively installed on the inner side wall of the first groove 43, a blocking cover 40 is connected to the inner side wall of the first groove 43 in a sliding mode, and a rubber block 41 is bonded to one side of the blocking cover 40; through the setting of second USB mouth 44 that charges, be convenient for charge first PLC controller 33, through the setting of second switch 45, be convenient for start first PLC controller 33 operation, through the setting of keeping off lid 40 and block rubber 41, can avoid first recess 43 to intake with the shutoff of first recess 43.

In this embodiment, the arc cover 6 is made of acrylic material, and has a transparent characteristic, and does not affect the shooting effect of the camera 18, the specific models of the first PLC controller 33 and the second PLC controller 37 are SM1EM331, the electrical output terminal of the second USB charging port 44 is electrically connected to the electrical input terminal of the first battery 3, the electrical output terminal of the first battery 3 is electrically connected to the electrical input terminal of the second switch 45, the electrical output terminal of the second switch 45 is electrically connected to the electrical input terminal of the first PLC controller 33, the electrical output terminal of the first PLC controller 33 is electrically connected to the submersible motor 15, the first signal transceiver 34 and the electrical input terminal of the camera 18, the signal transmission terminal of the first PLC controller 33 is in signal connection with the signal transmission terminal of the first signal transceiver 34, the signal transmission terminal of the first signal transceiver 34 is in signal connection with the signal transmission terminal of the second signal transceiver 36, the signal transmission end of the second signal transceiver 36 is in signal connection with the signal transmission end of the second PLC controller 37, the electrical output end of the first USB charging port 42 is electrically connected with the electrical input end of the second battery 5, the electrical output end of the second battery 5 is electrically connected with the electrical input end of the first switch 8, the electrical output end of the first switch 8 is electrically connected with the electrical input end of the second PLC controller 37, and the electrical output end of the second PLC controller 37 is electrically connected with the electrical input ends of the touch display screen 38 and the second signal transceiver 36, respectively.

Working principle or structural principle, when in use, the first PLC controller 33 is started through the second switch 45, so that the first PLC controller 33 starts the first signal transceiver 34 and the camera 18, the second PLC controller 37 is started through the first switch 8, so that the second PLC controller 37 starts the second signal transceiver 36 and the touch display screen 38, the arc plate 11 is placed in the circulating water system pipeline, the touch display screen 38 is used for sending out a monitoring instruction, the second PLC controller 37 receives the instruction and then sends the instruction to the first signal transceiver 34 through the second signal transceiver 36, the first signal transceiver 34 receives the information and then sends the information to the first PLC controller 33, the first PLC controller 33 starts the submersible motor 15, so that the submersible motor 15 drives the stirring vane 17 to rotate through the transmission rod 16, so that the second shell 12 is pushed to move, and meanwhile, the camera 18 is used for monitoring in the pipeline, the condition of the inner wall of the pipeline is sent to a second signal transceiver 36 by a first signal transceiver 34 through a first PLC controller 33, the second signal transceiver 36 receives information and then is processed by a second PLC controller 37, and then is displayed through a touch display screen 38, so that the monitoring work of the biological slime of the circulating water system is carried out, when the arc plate 11 impacts the inner wall of the pipeline, the second shell 12 extrudes the supporting rod 26 through the fourth shell 27, so that the supporting rod 26 pushes the pipe body 23 to extrude the spring 24 through the third shell 25, the spring 24 can slow down the pressure applied by the outside and generate a reverse thrust after being extruded, so that the pipe body 23 resets, thereby the arc plate 11 resets, the pressure caused by impact is reduced, the monitoring structures such as the first PLC controller 33 and the camera 18 are prevented from being damaged, and through the arrangement of the arc plate 11, the arc cover 6, the first net body 7 and the second net body 19, can protect stirring leaf 17 and transfer line 16 from the outside, avoid stirring leaf 17 and transfer line 16 winding to float and lead to unable rotation, guarantee the utility model discloses a normal operating.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a device that is used for biological slime monitoring of circulating water system which characterized in that: the method comprises the following steps:

the main body assembly (10) comprises an arc-shaped plate (11), a second shell (12), a third baffle plate (13), a fourth baffle plate (14), a submersible motor (15), a transmission rod (16), stirring blades (17), a camera (18) and a second net body (19);

the buffer component (20), the buffer component (20) comprises fixed blocks (21), fixed rods (22), tube bodies (23), springs (24), a third shell (25), a support rod (26) and a fourth shell (27), eight fixed blocks (21) are symmetrically welded on the outer side wall of the second shell (12), the fixed rods (22) are welded on one adjacent sides of the fixed blocks (21) horizontally adjacent to each other, the springs (24) and the two tube bodies (23) are respectively sleeved on the outer portions of the fixed rods (22), the two ends of the springs (24) are respectively welded on one adjacent side of the two tube bodies (23), the third shell (25) is welded on the outer side wall of the tube bodies (23), the support rod (26) is hinged inside the third shell (25), one end, far away from the third shell (25), of the support rod (26) is hinged to the fourth shell (27), one side of the fourth shell (27) far away from the supporting rod (26) is welded on the inner side wall of the adjacent arc-shaped plate (11);

the control assembly (30) comprises a fifth shell (31), a second partition plate (32), a first PLC (programmable logic controller) controller (33), a first signal transceiver (34), a sixth shell (35), a second signal transceiver (36), a second PLC controller (37) and a touch display screen (38).

2. An apparatus for circulating water system biofouling monitoring according to claim 1, wherein: four arc-shaped plates (11) are sleeved outside the second shell (12), one side of the second shell (12) is in threaded connection with a third baffle (13), a camera (18) is arranged on one side of the third baffle (13) far away from the second shell (12), a fourth baffle (14) is welded on the inner side wall of the second shell (12), a submersible motor (15) is arranged in the second shell (12), an output shaft of the submersible motor (15) is fixedly connected with a transmission rod (16), one end of the transmission rod (16) far away from the submersible motor (15) penetrates through the outer side wall of the second shell (12), the outer side wall of the transmission rod (16) is rotatably connected to the inside of the second shell (12) through a bearing, stirring blades (17) are welded on the circumference of the outer side wall of the transmission rod (16) in an equidistant mode, and four stirring blades are fixedly connected between the adjacent sides of the arc-shaped plates (11) and are respectively connected with a second net body (19).

3. An apparatus for circulating water system biofouling monitoring according to claim 1, wherein: the utility model discloses a portable electronic device, including second casing (12), first signal transceiver (34) is installed to the lateral wall of second casing (12), the inside wall welding of second casing (12) has fifth casing (31), the inside wall of fifth casing (31) has second baffle (32) through screw thread connection, first PLC controller (33) are installed to one side of second baffle (32), first signal transceiver (34) are installed to the lateral wall of second casing (12), touch-control display screen (38) are installed to the inside wall of sixth casing (35), second recess (46) have been seted up to the bottom of sixth casing (35).

4. An apparatus for circulating water system biofouling monitoring according to claim 1, wherein: the bottom threaded connection of dive motor (15) has first casing (2), one side fixed connection in of first casing (2) in the inside wall of second casing (12), one side threaded connection of fifth casing (31) has first baffle (1).

5. An apparatus for circulating water system biofouling monitoring according to claim 1, wherein: one end of each of the four arc-shaped plates (11) is in threaded connection with a first net body (7), and the other end of each of the four arc-shaped plates (11) is bonded with an arc-shaped cover (6).

6. An apparatus for circulating water system biofouling monitoring according to claim 1, wherein: the inside threaded connection of fifth casing (31) has first battery (3), the inside wall threaded connection of sixth casing (35) has first baffle (4), the inside wall threaded connection of sixth casing (35) has second battery (5).

7. An apparatus for circulating water system biological slime monitoring according to claim 5, wherein: the bottom threaded connection of sixth casing (35) has second baffle (9), first USB charges mouthful (42) is installed to the bottom of second baffle (9), first switch (8) are installed to one side of sixth casing (35).

8. An apparatus for circulating water system biofouling monitoring according to claim 1, wherein: one first recess (43) have been seted up to the lateral wall of arc (11), second USB charges mouth (44) and second switch (45) are installed respectively to the inside wall of first recess (43), the inside wall sliding connection of first recess (43) has flap (40), one side bonding of flap (40) has block rubber (41).

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