CN115524464A

CN115524464A - Factory wastewater detection machine

Info

Publication number: CN115524464A
Application number: CN202211169316.4A
Authority: CN
Inventors: 陈建香
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-09-22
Filing date: 2022-09-22
Publication date: 2022-12-27

Abstract

The invention provides a factory wastewater detector which comprises a machine shell, wherein a sliding mechanism, a detection mechanism, a sampling mechanism, an auxiliary mechanism, an extraction mechanism and a conveying mechanism are arranged in the machine shell; the waste water collecting and sampling device detects waste water at different depths in a waste water tank, samples and stores the waste water at different depths, collects and samples waste materials accumulated at the bottom of the waste water tank, drives a shell to move up and down in the waste water tank through an electric control take-up pulley, detects the waste water tank at different depths, washes a water quality detector through a second corrugated pipe, drives a second piston to move through mutual attraction of a cathode electromagnet and an anode electromagnet when detecting the quality of the waste water through a second liquid pumping shell, collects the waste materials at the bottom of the tank into a first extraction box through a drilling shaft, performs solid-liquid separation on a mixture of the waste materials and the waste water through an air pump, and drives a high-pressure spray head to move through a first sliding block to wash the shell.

Description

Factory wastewater detection machine

Technical Field

The invention relates to the technical field of wastewater detection, in particular to a factory wastewater detector.

Background

Waste water is the general name of discharged water and runoff rainwater among the resident's activity process, often need use waste water check out test set to carry out corresponding detection to turbidity, colourity, suspended solid, pH value, heavy metal etc. of waste water, has following several defects in the existing equipment:

first, the sampling head of current waste water check out test set carries out direct contact through sampling head and sewage at the sampling in-process, has a large amount of debris in the sewage, and still has other defects among the existing equipment, for example current application number: in the document of CN202122623468.4, the utility model connects the filter cartridge at the bottom of the sampling head, the inner cavity of the filter cartridge is longitudinally and equidistantly provided with a first pull filter screen, a second pull filter screen and a third pull filter screen with gradually reduced aperture, thereby effectively avoiding the problems of easy blockage, low sampling efficiency and high maintenance cost in the sampling process, but after the utility model detects the waste water, more waste water can be remained on the surface of the equipment, some waste water has corrosivity, the remained waste water easily corrodes the surface of the equipment and reduces the service life of the equipment;

secondly, the existing partial waste gas and waste water detection device mostly detects collected samples when in use, and the detection timeliness is poor because the existing partial waste gas and waste water detection device does not have a sampling function and can not sample in situ for detection;

thirdly, after primary detection is carried out in the existing detection equipment, waste water remains on the detection equipment, and if waste water at different depths needs to be detected, the waste water remaining on the surface of the detection equipment is easy to influence the detection result;

fourth, a large amount of waste materials are piled up usually on the wastewater disposal basin bottom, and then need carry out the sample detection analysis to the bottom of the pool waste material sometimes, and can only detect waste water among the current check out test set, can not sample the collection to the waste material of bottom of the pool when detecting waste water, and the function is comparatively single.

Disclosure of Invention

The invention aims to provide a factory wastewater detector which is used for overcoming the defects in the prior art.

The factory wastewater detector comprises a machine shell, wherein bases which are symmetrical in left and right positions are arranged on the left and right sides of the machine shell, supports are fixedly arranged on the top wall of the base, a top plate is arranged between the two supports, an electric control take-up pulley is arranged in the bottom wall of the top plate, a rope is wound on the electric control take-up pulley, the lower end of the rope is fixedly connected with the top wall of the machine shell, a first rack is fixedly arranged in the side wall, close to the machine shell, of each support, a first sliding block is connected onto the side wall, close to the machine shell, of each support in a sliding mode, a first motor is fixedly arranged in the side wall, close to the first rack, of each first sliding block, a first rotating shaft is arranged on each first motor, a first gear meshed with the first rack is fixedly arranged on each first rotating shaft, and a sliding mechanism for driving the first sliding blocks to move up and down is arranged in each first sliding block;

a first liquid pumping shell is arranged in the bottom wall of the shell, a first liquid pumping groove with a downward opening is formed in the first liquid pumping shell, a first piston is connected in the first liquid pumping groove in a sliding mode, a matching cavity is formed in the top wall of the shell above the first liquid pumping shell, and a detection mechanism for driving the first piston to move up and down is arranged in the matching cavity;

the liquid sampling device is characterized in that a cavity is formed in the right side wall of the shell, the upper side wall and the lower side wall of the cavity are rotatably connected with a rotary table, four second liquid pumping shells are mounted on the left side wall of the rotary table at equal intervals, and a sampling mechanism which drives the rotary table to rotate and pump liquid and store samples is arranged in the cavity.

Beneficially, the sliding mechanism includes a first belt wheel fixedly arranged on the first rotating shaft, a first corrugated pipe is arranged on a side wall, close to the casing, of the first sliding block, a high-pressure nozzle is arranged on the first corrugated pipe, a sliding cavity is arranged in a side wall of the first sliding block, a reciprocating block is connected to a bottom wall of the sliding cavity in a sliding mode, a reciprocating groove penetrating through front and rear side walls of the reciprocating block is formed in the reciprocating block, a reciprocating shaft extending into the reciprocating groove is connected to a rear side wall of the sliding cavity in a rotating mode, a cam in abutting-pressing connection with left and right side walls of the reciprocating groove is fixedly arranged on the reciprocating shaft, a second belt wheel is fixedly arranged on the reciprocating shaft, a belt is arranged between the second belt wheel and the first belt wheel, and a connecting rod hinged with the high-pressure nozzle is fixedly arranged on a side wall, close to the high-pressure nozzle, of the reciprocating block.

Therefore, the outer wall of the machine shell can be cleaned, and the phenomenon that the surface of the machine shell is corroded due to the fact that waste water is remained on the surface of the machine shell is avoided.

Beneficially, detection mechanism includes first filter plate on the first drawing liquid tank bottom wall, set firmly on the first piston roof and extend to the first drawing liquid pole of cooperation intracavity, first drawing liquid pole upper end has set firmly first positive pole electro-magnet, install first negative pole electro-magnet on the cooperation chamber roof, first negative pole electro-magnet with install the spring between the first positive pole electro-magnet, the intercommunication runs through on the first drawing liquid tank left side wall first drawing liquid shell left side wall extends to the second bellows of casing roof top, the water quality testing ware of position symmetry about installing in the lateral wall about the first drawing liquid tank.

This allows the detection of waste water.

Advantageously, the sampling mechanism comprises a second motor fixedly arranged on the top wall of the cavity, a second rotating shaft is mounted on the second motor, an annular rack is fixedly arranged on the side wall of the rotary table, a second gear meshed with the annular rack is fixedly arranged on the second rotating shaft, a second liquid pumping groove is formed in the second liquid pumping shell, a second piston is connected in the second liquid pumping groove in a sliding mode, a second liquid pumping rod extending out of the right side wall of the second liquid pumping shell is fixedly arranged on the right side wall of the second piston, a second cathode electromagnet is mounted at the right end of the second liquid pumping rod, a second anode electromagnet is mounted on the right side wall of the cavity, a third corrugated pipe extending into the cavity is communicated with the right side wall of the first liquid pumping shell, and an auxiliary mechanism for communicating the third corrugated pipe with the second liquid pumping shell is arranged in the cavity.

Thus, the waste water to be detected can be sampled and stored.

Beneficially, the auxiliary mechanism includes a first electric control ball valve installed in the third corrugated pipe, a connecting piece is communicated with the right end of the third corrugated pipe in the cavity, a first hydraulic cylinder is installed on the wall of the left side of the cavity, a right first telescopic rod is installed on the first hydraulic cylinder, a connecting plate fixedly connected with the bottom wall of the connecting piece is fixedly installed on the first telescopic rod, a liquid outlet pipe penetrating through the left side wall of the second liquid pumping shell is fixedly installed on the left side wall of the second liquid pumping shell, a second electric control ball valve is installed in the liquid outlet pipe, an extraction cavity with a downward opening is formed in the bottom wall of the left side of the shell, a second sliding block is connected to the left side wall and the right side wall of the extraction cavity in a sliding mode, a rotating groove is formed in the second sliding block, and an extraction mechanism which drives the second sliding block to move up and down and extract waste materials is arranged in the extraction cavity.

Thus, the wastewater being detected can be sampled and stored.

Beneficially, the extracting mechanism comprises a third motor fixedly arranged in the right side wall of the rotating groove, a third rotating shaft extending into the rotating groove is mounted on the third motor, a second rack is fixedly arranged on the rear side wall of the extracting cavity, a third gear meshed with the second rack is fixedly arranged on the third rotating shaft, a first extracting box with a downward opening is fixedly arranged on the bottom wall of the second sliding block, a drilling shaft extending into the rotating groove is rotatably connected to the top wall of the first extracting box, a first bevel gear is fixedly arranged on the drilling shaft in the rotating groove, a second bevel gear meshed with the first bevel gear is fixedly arranged on the third rotating shaft, a collecting shell is fixedly arranged on the rear side wall of the extracting cavity, a collecting cavity is arranged in the collecting shell, a collecting box with an upward opening is mounted on the bottom wall of the collecting cavity, and a conveying mechanism for conveying waste materials into the collecting box is arranged in the collecting cavity.

In this way, waste material can be extracted from the bottom of the lagoon.

Beneficially, conveying mechanism draws the box including the second that sets firmly on collect the chamber rear side wall opening forward, the second draw the box with first draw box rear side wall intercommunication, install the fourth motor on the second draws box rear side wall, install on the fourth motor and extend to the conveying axle in the second draws the box, conveying axle front side the second draws the box in and installs third automatically controlled ball valve, install the air pump on the second slider rear side bottom wall, install on the air pump with the second draws the trachea of box intercommunication, the trachea below the second draws the box bottom wall on the intercommunication have the downcomer, the downcomer intraductally set firmly with the second draws box smooth connection's second filter plate, the second filter plate below install fourth automatically controlled ball valve in the fourth automatically controlled ball valve, collect the intracavity the second draw box rear side bottom wall on the intercommunication have the discharging pipe, install fifth automatically controlled ball valve in the discharging pipe.

In this way, waste material can be collected and stored.

The invention has the beneficial effects that:

the waste water collecting and sampling device can detect waste water at different depths in the waste water pool, sample and store the waste water at different depths and collect and sample waste materials accumulated at the bottom of the waste water pool through the sliding mechanism, the detection mechanism, the sampling mechanism, the auxiliary mechanism, the extraction mechanism and the conveying mechanism;

according to the invention, the shell is driven to move up and down in the wastewater tank through the electric control take-up pulley, wastewater tanks with different depths can be detected, and the water quality detector is flushed through the second corrugated pipe, so that the influence of residual wastewater on the authenticity of later detection data is avoided;

when the quality of wastewater is detected through the second liquid pumping shell, the second piston is driven to move through the mutual attraction of the cathode electromagnet and the anode electromagnet, and the wastewater in the water layer at the depth is pumped into the second liquid pumping shell and is stored;

according to the invention, after the equipment sinks into the bottom of the wastewater pool through the drilling shaft, the waste accumulated at the bottom of the pool moves upwards and is collected into the first extraction box, the mixture of the waste and the wastewater is subjected to solid-liquid separation through the air pump, and the solid waste is collected and stored through the collection box;

the invention washes the detected shell by driving the high-pressure spray nozzle to move up and down through the first sliding block, washes the waste water remained on the surface of the shell from the shell, and drives the high-pressure spray nozzle to continuously adjust the water spraying direction by moving the reciprocating block left and right, thereby ensuring that the surface of the whole shell can be washed and prolonging the service life of the shell.

Drawings

FIG. 1 is a schematic external view of the present invention;

FIG. 2 is a schematic view of the overall structure of a plant wastewater detection machine according to the present invention;

FIG. 3 is a schematic view of the first slider of FIG. 2 in accordance with the present invention;

FIG. 4 is a schematic view of the housing of FIG. 2 in accordance with the present invention;

FIG. 5 is a schematic view of the cavity of FIG. 2 according to the present invention;

FIG. 6 is a schematic view of the extraction chamber of FIG. 2 according to the present invention;

FIG. 7 isbase:Sub>A schematic view of A-A of FIG. 6 in accordance with the present invention;

as shown in the figure:

10. a housing; 11. a base; 12. a support; 13. a top plate; 14. an electric control take-up pulley; 15. a rope; 16. a first rack; 17. a first slider; 18. a first motor; 19. a first rotating shaft; 20. a first gear; 21. a first pulley; 22. a belt; 23. a sliding cavity; 24. a reciprocating block; 25. a reciprocating groove; 26. a connecting rod; 27. a first bellows; 28. a high pressure spray head; 29. a reciprocating shaft; 30. a second pulley; 31. a cam; 32. a first liquid pumping shell; 33. a first liquid pumping groove; 34. a second bellows; 35. a water quality detector; 36. a first piston; 37. a first pumping rod; 38. a mating cavity; 39. a first cathode electromagnet; 40. a first anode electromagnet; 41. a spring; 42. a cavity; 43. a turntable; 44. an annular rack; 45. a second motor; 46. a second rotating shaft; 47. a second gear; 48. a second liquid pumping shell; 49. a second liquid pumping groove; 50. a liquid outlet pipe; 51. a second electrically controlled ball valve; 52. a second piston; 53. a second liquid pumping rod; 54. a second cathode electromagnet; 55. a second anode electromagnet; 56. a first hydraulic cylinder; 57. a first telescopic rod; 58. a connecting plate; 59. a third bellows; 60. a first electrically controlled ball valve; 61. a connecting member; 62. a first filter plate; 63. an extraction chamber; 64. a second slider; 65. a rotating groove; 66. a third motor; 67. a third rotating shaft; 68. a second rack; 69. a third gear; 70. a second bevel gear; 71. a first extraction cartridge; 72. a drilling shaft; 73. a first bevel gear; 74. collecting the shells; 75. a second extraction cartridge; 76. a collection box; 77. a discharge pipe; 78. a fourth motor; 79. a delivery shaft; 80. an air pump; 81. an air tube; 82. a collection chamber; 83. a sewer pipe; 84. a second filter plate; 85. a fourth electrically controlled ball valve; 86. a third electrically controlled ball valve; 87. a fifth electric control ball valve; 88. a sliding mechanism; 89. a detection mechanism; 90. a sampling mechanism; 91. an auxiliary mechanism; 92. an extraction mechanism; 93. a conveying mechanism.

Detailed Description

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description of the present invention, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further explained by combining the embodiments as follows:

referring to fig. 1-7, the factory wastewater detector includes a housing 10, wherein bases 11 are installed on the left and right sides of the housing 10, the bases 11 are symmetrically installed on the left and right sides, a bracket 12 is fixedly installed on the top wall of the base 11, a top plate 13 is installed between the two brackets 12, an electrically controlled take-up pulley 14 is installed in the bottom wall of the top plate 13, a rope 15 is wound on the electrically controlled take-up pulley 14, the lower end of the rope 15 is fixedly connected with the top wall of the housing 10, a first rack 16 is fixedly installed in the side wall of the bracket 12 close to the housing 10, a first slider 17 is slidably connected to the side wall of the bracket 12 close to the housing 10, a first motor 18 is fixedly installed in the side wall of the first rack 16, a first rotating shaft 19 is installed on the first motor 18, a first gear 20 engaged with the first rack 16 is fixedly installed on the first rotating shaft 19, and a sliding mechanism 88 for driving the first slider 17 to move up and down is installed in the first slider 17;

a first liquid pumping shell 32 is arranged in the bottom wall of the casing 10, a first liquid pumping groove 33 with a downward opening is arranged in the first liquid pumping shell 32, a first piston 36 is connected in the first liquid pumping groove 33 in a sliding manner, a matching cavity 38 is arranged in the top wall of the casing 10 above the first liquid pumping shell 32, and a detection mechanism 89 for driving the first piston 36 to move up and down is arranged in the matching cavity 38;

a cavity 42 is formed in the right side wall of the casing 10, the upper side wall and the lower side wall of the cavity 42 are rotatably connected with a rotary disc 43, four second liquid-pumping shells 48 are equidistantly mounted on the left side wall of the rotary disc 43, and a sampling mechanism 90 which drives the rotary disc 43 to rotate and performs liquid pumping and sample storage is arranged in the cavity 42.

In this embodiment, slide mechanism 88 is including setting firmly in first band pulley 21 on the first axis of rotation 19, first slider 17 is close to install first bellows 27 on the lateral wall of casing 10, install high pressure nozzle 28 on the first bellows 27, be equipped with slip chamber 23 in the first slider 17 lateral wall, sliding connection has reciprocating block 24 on the 23 diapire of slip chamber, be equipped with on reciprocating block 24 and run through reciprocating groove 25 of lateral wall around reciprocating block 24, it extends to rotate on the lateral wall behind the slip chamber 23 to be connected with the reciprocating shaft 29 in the reciprocating groove 25, reciprocating shaft 29 is last set firmly with reciprocating groove 25 about the lateral wall support the cam 31 of pressure connection, reciprocating shaft 29 is last to set firmly second band pulley 30, second band pulley 30 with install belt 22 between the first band pulley 21, reciprocating block 24 is close to set firmly on the lateral wall of high pressure nozzle 28 with the connecting rod 26 that high pressure nozzle 28 is connected, works as first motor 18 starts, first motor 18 passes through first axis of rotation gear 19 and first band pulley 20 drive first band pulley 20 and the swing of high pressure gear 20 through first band pulley 20 and the reciprocating shaft drives reciprocating shaft 25 and drives reciprocating shaft 20 and moves about the reciprocating shaft 20 and moves the reciprocating groove 31, and drives the reciprocating shaft 17 and moves the reciprocating groove.

In this embodiment, the detection mechanism 89 includes the first filter plate 62 on the bottom wall of the first liquid pumping tank 33, a first liquid pumping rod 37 extending into the matching chamber 38 is fixedly arranged on the top wall of the first piston 36, a first anode electromagnet 40 is fixedly arranged at the upper end of the first liquid pumping rod 37, a first cathode electromagnet 39 is arranged on the top wall of the matching chamber 38, a spring 41 is arranged between the first cathode electromagnet 39 and the first anode electromagnet 40, the left side wall of the first liquid pumping tank 33 is communicated with a second corrugated pipe 34 penetrating through the left side wall of the first liquid pumping shell 32 and extending to the top wall of the housing 10, a water quality detector 35 with symmetrical left and right positions is arranged in the left and right side walls of the first liquid pumping tank 33, when the first cathode electromagnet 39 and the first anode electromagnet 40 are powered on, the first cathode electromagnet 39 and the first anode electromagnet 40 attract each other and drive the first liquid pumping rod 37 to move upward, the first liquid pumping rod 37 drives the first piston 36 to move upward, and pump wastewater quality detector 35 to start the first liquid pumping tank 33.

In this embodiment, the sampling mechanism 90 includes a second motor 45 fixedly disposed on the top wall of the cavity 42, the second motor 45 is provided with a second rotating shaft 46, the side wall of the rotating disc 43 is fixedly provided with an annular rack 44, the second rotating shaft 46 is fixedly provided with a second gear 47 engaged with the annular rack 44, a second liquid-pumping groove 49 is disposed in the second liquid-pumping casing 48, a second piston 52 is slidably connected to the second liquid-pumping groove 49, the right side wall of the second piston 52 is fixedly provided with a second liquid-pumping rod 53 extending out of the right side wall of the second liquid-pumping casing 48, the right end of the second liquid-pumping rod 53 is provided with a second cathode electromagnet 54, the right side wall of the cavity 42 is provided with a second anode electromagnet 55, the right side wall of the first liquid-pumping casing 32 is communicated with a second corrugated tube 59 extending into the cavity 42, the cavity 42 is provided with an auxiliary mechanism 91 communicating the third corrugated tube 59 with the second liquid-pumping casing 48, and when the second cathode electromagnet 54 and the second anode 55 and the second liquid-pumping casing 32 are energized, the second gear 54 and the second cathode electromagnet 47 are driven by the second motor 45 to rotate, the second liquid-pumping groove 52 and the second liquid-pumping groove 52 are driven by the second cathode electromagnet 47.

In this embodiment, the auxiliary mechanism 91 includes a first electrical ball valve 60 installed in the third bellows 59, a connecting member 61 is communicated with the right end of the third bellows 59 in the cavity 42, a first hydraulic cylinder 56 is installed on the left side wall of the cavity 42, a first telescopic rod 57 facing right is installed on the first hydraulic cylinder 56, a connecting plate 58 fixedly connected with the bottom wall of the connecting member 61 is fixedly installed on the first telescopic rod 57, a liquid outlet pipe 50 penetrating through the left side wall of the second liquid pumping casing 48 is fixedly installed on the left side wall of the second liquid pumping groove 49, a second electrical ball valve 51 is installed in the liquid outlet pipe 50, an extraction cavity 63 with a downward opening is installed in the bottom wall of the left side of the housing 10, a second slider 64 is slidably connected to the left and right side walls of the extraction cavity 63, a rotating groove 65 is installed in the second slider 64, an extraction mechanism 92 for driving the second slider 64 to move up and down and extracting waste materials is installed in the extraction cavity 63, when the first hydraulic cylinder 56 is started, the first hydraulic cylinder 56 drives the connecting plate 58 to move the connecting member 61 and the connecting member 58 is communicated with the liquid outlet pipe 50.

In this embodiment, the extracting mechanism 92 includes a third motor 66 fixed in the right side wall of the rotating groove 65, a third rotating shaft 67 extending into the rotating groove 65 is installed on the third motor 66, a second rack 68 is fixed on the rear side wall of the extracting cavity 63, a third gear 69 engaged with the second rack 68 is fixed on the third rotating shaft 67, a first extracting box 71 with a downward opening is fixed on the bottom wall of the second slider 64, a drilling shaft 72 extending into the rotating groove 65 is connected on the top wall of the first extracting box 71 in a rotating manner, a first bevel gear 73 is fixed on the drilling shaft 72 in the rotating groove 65, a second bevel gear 70 engaged with the first bevel gear 73 is fixed on the third rotating shaft 67, a collecting shell 74 is fixed on the rear side wall of the extracting cavity 63, a collecting cavity 82 is installed in the collecting cavity 74, a collecting box 76 with an upward opening is installed on the bottom wall of the collecting cavity 82, a conveying mechanism 93 for conveying the waste into the collecting box 76 is installed in the collecting cavity 82, when the third motor 66 is started, the third motor drives the third rotating shaft 66 to rotate the second bevel gear 72 and drive the second rack 72 to move the waste water tank 69 to move up and down through the second rack 72, and the waste water tank 71, the waste collecting box 71, and the waste collecting box is moved by the third rotating shaft 71, and the second rack 71, the rotating shaft 72, the waste collecting box 71 is moved up and the waste water collecting box 72, and the waste water collecting box 71.

In this embodiment, the conveying mechanism 93 includes a second extraction box 75 with a forward opening and fixedly disposed on the rear side wall of the collection chamber 82, the second extraction box 75 is communicated with the rear side wall of the first extraction box 71, a fourth motor 78 is mounted on the rear side wall of the second extraction box 75, a conveying shaft 79 extending into the second extraction box 75 is mounted on the fourth motor 78, a third electrically controlled ball valve 86 is mounted in the second extraction box 75 in front of the conveying shaft 79, an air pump 80 is mounted on the bottom wall of the rear side of the second slider 64, an air pipe 81 communicated with the second extraction box 75 is mounted on the air pump 80, a sewer pipe 83 is communicated with the bottom wall of the second extraction box 75 below the air pipe 81, a second filter plate 84 smoothly connected with the second extraction box 75 is fixedly disposed in the sewer pipe 83, a fourth electric control ball valve 85 is installed in the fourth electric control ball valve 85 below the second filter plate 84, a discharge pipe 77 is communicated with the bottom wall of the rear side of the second extraction box 75 in the collection cavity 82, a fifth electric control ball valve 87 is installed in the discharge pipe 77, when the fourth motor 78 is started, the fourth motor 78 rotates through the conveying shaft 79, the conveying shaft 79 conveys waste materials in the drilling shaft 72 into the second extraction box 75, the air pump 80 is started, the air pump 80 downwards pressurizes the waste materials through the air pipe 81, the air pump 80 discharges the waste materials in the second extraction box 75 out of the second extraction box 75 through the sewer pipe 83, only waste materials are left in the second extraction box 75, and the waste materials pass through the discharge pipe 77 and downwards fall into the collection box 76 for storage.

The invention relates to a factory wastewater detector, which comprises the following working procedures:

initial state:

the discharge pipe 77 is located right above the collecting box 76, the connecting member 61 and the second liquid-extracting shell 48 on the front side are located at the same horizontal straight line position, the first cathode electromagnet 39, the first anode electromagnet 40, the second cathode electromagnet 54 and the second anode electromagnet 55 are all in a power-off state, the two first corrugated pipes 27 and the second corrugated pipe 34 can be connected with clean water, the second electric-controlled ball valve 51, the first electric-controlled ball valve 60, the fourth electric-controlled ball valve 85, the third electric-controlled ball valve 86 and the fifth electric-controlled ball valve 87 are all in a closed state, and the second filter plate 84 only provides wastewater to pass through;

firstly, when waste water in a waste water tank needs to be detected, two bases 11 are placed beside the waste water tank, an electric control take-up pulley 14 is started, the electric control take-up pulley 14 slowly places the shell 10 into the waste water tank through a rope 15, the shell 10 sinks in the waste water tank continuously, and the depth position of the shell 10 in the waste water tank is determined through the unreeling length of the rope 15;

when the wastewater in the water layer needs to be detected, the first cathode electromagnet 39 and the first anode electromagnet 40 are energized, the first cathode electromagnet 39 and the first anode electromagnet 40 attract each other and drive the first liquid pumping rod 37 to move upwards, the first liquid pumping rod 37 drives the first piston 36 to move upwards and pump the wastewater into the first liquid pumping groove 33, the water quality detector 35 is started, the water quality detector 35 detects the wastewater in the first liquid pumping groove 33, the first hydraulic cylinder 56 is started, the first hydraulic cylinder 56 drives the connecting plate 58 to move through the first telescopic rod 57, the connecting plate 58 drives the connecting piece 61 to move rightwards and communicate the connecting piece 61 with the liquid outlet pipe 50 on the front side, the second electrically controlled ball valve 51 and the first electrically controlled ball valve 60 are opened, the wastewater in the first liquid pumping groove 33 flows into the third corrugated pipe 59 through the first electrically controlled ball valve 60, the second cathode electromagnet 54 and the second anode electromagnet 55 attract each other and drive the second corrugated pipe 52 to move rightwards and pump the wastewater in the second liquid pumping groove 52, and drive the second cathode electromagnet 53 and the second liquid pumping rod 53 to move rightwards and drive the second piston 52 to pump the piston 52 and pump the piston 52 to move rightwards and drive the second liquid pumping groove 52;

thirdly, sampling and storing the wastewater of the second pumping shell 48 at the front side, closing the second electric-controlled ball valve 51 and the first electric-controlled ball valve 60, starting the first hydraulic cylinder 56 in the reverse direction, driving the connecting piece 61 to move leftwards by the first hydraulic cylinder 56 through the connecting plate 58, disconnecting the connecting piece 61 from the liquid outlet pipe 50 at the front side, starting the second motor 45, driving the second gear 47 to rotate by the second motor 45 through the second rotating shaft 46, driving the rotary disc 43 to rotate by the second gear 47 through meshing with the annular rack 44, and rotating the second pumping shell 48 with the sampled front side downwards by the rotary disc 43 and rotating the second pumping shell 48 with the empty front side to the position of the second pumping shell 48 at the front side, so as to sample and store the wastewater at the next time;

fourthly, after sampling and detecting the wastewater in the water layer, introducing clean water into the second corrugated pipe 34, allowing the clean water in the second corrugated pipe 34 to flow into the first liquid pumping shell 32, flushing the first liquid pumping shell 32 and the two water quality detectors 35, flushing the wastewater in the water layer in the first liquid pumping groove 33 out of the first liquid pumping groove 33, restarting the electric control take-up pulley 14, unreeling the rope 15 again, moving the machine shell 10 downwards again, detecting the wastewater in the deeper water layer, and repeating the working procedures of the second and third steps;

a fifth step, when the collection and sampling of the deposited waste at the bottom of the wastewater tank is required, the electrically controlled take-up reel 14 is activated again and the rope 15 is unwound, the housing 10 sinks to the bottom of the wastewater tank, the third motor 66 is activated, the third motor 66 drives the third gear 69 and the second bevel gear 70 to rotate through the third rotating shaft 67, the third gear 69 drives the second slider 64 to move downward through the engagement with the second rack 68, the second bevel gear 70 drives the drilling shaft 72 to rotate through the engagement with the first bevel gear 73, the lower end of the drilling shaft 72 contacts the bottom of the wastewater tank, the drilling shaft 72 rotates the deposited waste at the bottom of the wastewater tank into the first collection box 71 and moves upward, the third electrically controlled ball valve 86 is opened, the fourth motor 78 is activated, the fourth motor 78 rotates through the delivery shaft 79, the delivery shaft 79 delivers the waste in the drilling shaft 72 into the second collection box 75, the third electrically controlled ball valve 86 is closed and opens the fourth ball valve 80, the electrically controlled waste collection box 80 opens, the waste in the second collection box 75 and the waste collection box 75 is discharged through the second air pump 80, the second air pump 75 and the waste collection box 75 is closed, the waste collection box 75 is discharged through the air pump 80, and the air pump 85 is closed, the air pump 75 and the remaining waste collection box 75 is discharged;

sixthly, after the wastewater in different water layers is detected and the waste at the bottom of the wastewater tank is collected and sampled, the electric control take-up pulley 14 is reversely started, the electric control take-up pulley 14 takes up the rope 15 and pulls the casing 10 upwards from the bottom of the wastewater tank until the casing 10 is pulled out of the water surface, the first motor 18 is started, the first motor 18 drives the first gear 20 and the first belt pulley 21 to rotate through the first rotating shaft 19, the first gear 20 drives the first sliding block 17 to move up and down through meshing with the first rack 16, the first belt pulley 21 drives the second belt pulley 30 to rotate through the belt 22, the second belt pulley 30 drives the cam 31 to rotate through the reciprocating shaft 29, the cam 31 drives the reciprocating groove 25 to move left and right through abutting contact with the left and right side walls of the reciprocating groove 25, the reciprocating groove 25 drives the high-pressure spray nozzle 28 to swing through the connecting rod 26 and continuously change the angle of spraying the high-pressure spray nozzle 28, the clean water is introduced into the first corrugated pipe 27, the two high-pressure spray nozzles 28 are started, the surface of the casing 10 is washed, and the surface of the wastewater flows into the casing 10 to prevent the clean water from eroding the surface of the wastewater.

The foregoing detailed description of the preferred embodiments of the invention has been presented. It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. The utility model provides a mill waste water detection machine, includes casing (10), its characterized in that: the portable winding machine is characterized in that bases (11) which are symmetrical in left and right positions are installed on the left side and the right side of the machine shell (10), supports (12) are fixedly arranged on the top wall of each base (11), a top plate (13) is installed between every two supports (12), an electric control take-up pulley (14) is installed in the bottom wall of each top plate (13), a rope (15) is wound on each electric control take-up pulley (14), the lower end of each rope (15) is fixedly connected with the top wall of the machine shell (10), a first rack (16) is fixedly arranged in the side wall, close to the machine shell (10), of each support (12), a first sliding block (17) is connected onto the side wall, close to the machine shell (10), of each support (12), a first motor (18) is fixedly arranged in the side wall, close to the first rack (16), a first rotating shaft (19) is installed on the first rotating shaft (19), a first gear (20) meshed with the first rack (16) is fixedly arranged in the first sliding block (17), and a sliding mechanism (88) for driving the first sliding block (17) to move up and down is arranged in the first sliding block (17);

a first liquid pumping shell (32) is arranged in the bottom wall of the machine shell (10), a first liquid pumping groove (33) with a downward opening is formed in the first liquid pumping shell (32), a first piston (36) is connected in the first liquid pumping groove (33) in a sliding manner, a matching cavity (38) is formed in the top wall of the machine shell (10) above the first liquid pumping shell (32), and a detection mechanism (89) for driving the first piston (36) to move up and down is arranged in the matching cavity (38);

be equipped with cavity (42) in casing (10) right side wall, it is connected with carousel (43) to rotate on the lateral wall about cavity (42), liquid shell (48) are taken out to four seconds of equidistant installation on carousel (43) left side wall, be equipped with the drive in cavity (42) carousel (43) rotate and carry out the sampling mechanism (90) of taking out liquid and deposit kind.

2. The plant wastewater detection machine according to claim 1, characterized in that: slide mechanism (88) include first band pulley (21), first bellows (27), high pressure nozzle (28), reciprocal piece (24), reciprocal axle (29), cam (31), second band pulley (30), belt (22), connecting rod (26), high pressure nozzle (28) are installed on first bellows (27), second band pulley (30) cam (31) with reciprocal axle (29) fixed connection, belt (22) are installed first band pulley (21) with between second band pulley (30), reciprocal piece (24) with connecting rod (26) fixed connection, connecting rod (26) with high pressure nozzle (28) hinge joint.

3. The plant wastewater detection machine according to claim 1, characterized in that: detection mechanism (89) include first filter plate (62), first liquid pole (37), first positive pole electro-magnet (40), first negative pole electro-magnet (39), spring (41), second bellows (34), water quality testing ware (35) of taking out, first liquid pole (37) with first positive pole electro-magnet (40) fixed connection, spring (41) respectively with first positive pole electro-magnet (40) with first negative pole electro-magnet (39) fixed connection, first filter plate (62) with first liquid groove (33) fixed connection takes out.

4. The plant wastewater detection machine according to claim 1, wherein: the sampling mechanism (90) comprises a second motor (45), a second rotating shaft (46), an annular rack (44), a second gear (47), a second piston (52), a second liquid pumping rod (53), a second cathode electromagnet (54), a second anode electromagnet (55), a third corrugated pipe (59) and an auxiliary mechanism (91) communicated with the second liquid pumping shell (48), wherein the second rotating shaft (46) is installed on the second motor (45), the second gear (47) is fixedly connected with the second rotating shaft (46), the second gear (47) is meshed with the annular rack (44), the annular rack (44) is fixedly connected with the rotating disc (43), and the second piston (52) and the second cathode electromagnet (54) are respectively fixedly connected with the second liquid pumping rod (53).

5. The plant wastewater detection machine according to claim 4, wherein: auxiliary mechanism (91) including install in first automatically controlled ball valve (60) in third bellows (59), in cavity (42) the intercommunication has connecting piece (61) on third bellows (59) right-hand member, cavity (42) left side wall mounting has first pneumatic cylinder (56), install first telescopic link (57) to the right on first pneumatic cylinder (56), first telescopic link (57) set firmly with connecting piece (61) diapire fixed connection's connecting plate (58) on (57), set firmly on second drawing liquid groove (49) left side wall and run through drain pipe (50) of second drawing liquid shell (48) left side wall, install second automatically controlled ball valve (51) in drain pipe (50), be equipped with opening extraction chamber (63) down in casing (10) left side diapire, sliding connection has second slider (64) on the lateral wall about extraction chamber (63), be equipped with in second slider (64) and rotate groove (65), it drives to be equipped with in extraction chamber (63) second slider (64) and carry out the mechanism (92) that draw that reciprocates to draw.

6. The plant wastewater detection machine according to claim 5, wherein: the extraction mechanism (92) comprises a third motor (66) fixedly arranged in the right side wall of the rotating groove (65), a third rotating shaft (67) extending into the rotating groove (65) is installed on the third motor (66), a second rack (68) is fixedly arranged on the rear side wall of the extraction cavity (63), a third gear (69) meshed with the second rack (68) is fixedly arranged on the third rotating shaft (67), a first extraction box (71) with a downward opening is fixedly arranged on the bottom wall of the second sliding block (64), a drilling shaft (72) extending into the rotating groove (65) is rotatably connected to the top wall of the first extraction box (71), a first bevel gear (73) is fixedly arranged on the drilling shaft (72) in the rotating groove (65), a second bevel gear (70) meshed with the first bevel gear (73) is fixedly arranged on the third rotating shaft (67), a collection shell (74) is fixedly arranged on the rear side wall of the extraction cavity (63), a waste collection cavity (82) is arranged in the collection cavity (74), and a conveying mechanism (93) for conveying the collection box (76) to the collection cavity (76) is installed on the bottom wall.

7. The plant wastewater detection machine according to claim 6, wherein: the conveying mechanism (93) comprises a second extraction box (75) which is fixedly arranged on the rear side wall of the collection cavity (82) and has a forward opening, the second extraction box (75) is communicated with the rear side wall of the first extraction box (71), a fourth motor (78) is arranged on the rear side wall of the second extraction box (75), a conveying shaft (79) extending into the second extraction box (75) is arranged on the fourth motor (78), a third electric control ball valve (86) is arranged in the second extraction box (75) on the front side of the conveying shaft (79), an air pump (80) is arranged on the bottom wall of the rear side of the second sliding block (64), an air pipe (81) communicated with the second extraction box (75) is arranged on the air pump (80), a sewer pipe (83) is communicated with the bottom wall of the second extraction box (75) below the air pipe (81), a second discharge pipe (85) smoothly connected with the second extraction box (75) is arranged in the bottom wall of the second extraction box (75), a discharge pipe (85) is arranged in the fourth electric control ball valve (85) below the second extraction box (75), and a filter plate (85) is communicated with a discharge pipe (77) on the bottom wall of the second extraction box (75).