CN114636707B - Inside clean effect verifying attachment of chemical drum - Google Patents

Abstract

The invention discloses a device for testing the cleaning effect of the interior of a chemical bucket, which relates to the technical field of test analysis and comprises an installation top plate, wherein a bottom wall contact plate is fixedly connected with the lower end face of a fixed main shaft; according to the invention, by arranging the mounting top plate, the reaction cylinder, the sampling liquid pump, the main shaft telescopic cylinder, the mounting main shaft, the detection agent liquid pump, the optical measurement spring, the measurement slide block, the light sensor, the light source and the detection light channel, the invention can detect the more precise cleaning residual granular substances in the barrel, can detect the cleaning effects of various different chemical components by a circulating detection method of solution chemical reaction, has higher accuracy on the detection result of the cleaning effect in the chemical barrel, and greatly improves the use safety of the chemical barrel.

Description

Inside clean effect verifying attachment of chemical drum

Technical Field

The application relates to a test analysis field especially relates to an inside clean effect verifying attachment of chemical drum.

Background

The chemical barrel is mostly made of plastics and inert alloy, generally called plastic chemical barrel and plastic chemical barrel, is developed and blow molded by using scientific formula, has various colors and elegant appearance, achieves the packing performance index in the aspects of acid and alkali resistance, corrosion resistance, leakage resistance, no fading, no deformation and the like, is an ideal choice for long-distance transportation of the packing material of the current chemical products, and is the corrosion-resistant storage and transportation equipment of the current most ideal chemical liquid; chemical engineering buckets are frequently required to be replaced by chemical engineering processes in the using process, so that the cleaning of the chemical engineering buckets is almost a necessary work, and the chemical engineering buckets also need to be cleaned when being recycled, but the problem of how to judge the cleaning effect is solved;

the invention with the publication number of CN202823371U discloses a novel chemical reaction kettle, which relates to the technical field of chemical machinery and comprises a reaction kettle body, a long feed inlet, a discharge outlet, a stirring shaft, stirring paddles, a kettle internal cleanliness detection device and a cleaning spraying device, wherein the cleaning spraying device is arranged on two sides above the reaction kettle body, the long feed inlet is arranged on the upper side of the left cleaning spraying device, the kettle internal cleanliness detection device is arranged below the right cleaning spraying device, the stirring shaft is arranged in the reaction kettle body, the stirring paddles are arranged on two sides of the stirring shaft, and the discharge outlet is arranged at the bottom of the reaction kettle body. The novel cleaning device is simple in structure and novel in design, the cleanliness detection device is arranged, the cleanliness on the inner wall of the kettle is detected firstly, then the mechanical cleaning device is adopted for cleaning, the cleaning effect is good, the product quality is improved, the feeding distance is prolonged, and the materials are dispersed more uniformly.

Disclosure of Invention

An object of this application is to provide an inside clean effect verifying attachment of chemical drum adopts following technical scheme:

a device for testing the cleaning effect in a chemical barrel comprises an installation top plate, wherein a main shaft air pump is fixedly connected to the lower end face of the installation top plate, a handle is fixedly connected to the upper end face of the installation top plate, a main shaft telescopic cylinder is dynamically connected to the lower end face of the main shaft air pump, an installation main shaft is fixedly connected to the lower end face of the main shaft telescopic cylinder, an installation main shaft bottom plate is fixedly connected to the lower end face of the installation main shaft, a fixed main shaft is fixedly connected to the lower end face of the installation main shaft bottom plate, a bottom wall contact plate is fixedly connected to the lower end face of the fixed main shaft, a circulating mechanism is arranged at the upper end of the installation top plate, an auxiliary mechanism is arranged at the lower end of the main shaft air pump, a barrel wall detection mechanism is arranged at the upper end of the installation main shaft bottom plate, a bottom wall detection mechanism is arranged at the upper end of the bottom wall contact plate, the circulating mechanism can assist in detecting the cleaning effect in the chemical barrel, the auxiliary mechanism can provide a detection medium and switch the detection position, the barrel wall detection mechanism can sample the barrel wall cleaning effect, and the bottom wall detection mechanism can detect the barrel bottom cleaning effect.

Preferably, the auxiliary mechanism includes fixed connection in the detection agent jar of installation spindle bottom plate up end, detection agent liquid pump, bucket wall detection air pump and the flexible base of bucket wall, be equipped with the detection agent chamber in the detection agent jar, detection agent liquid pump left end face fixedly connected with detection agent extraction tube, detect fixed connection in the agent chamber right side wall detection agent extraction tube, the detection agent extraction tube runs through detection agent chamber right-hand member wall, detection agent liquid pump upper end fixedly connected with detection agent pipeline, bucket wall detection air pump right-hand member power is connected with the section of thick bamboo wall and detects the telescopic cylinder, sliding fixed connection on the flexible base of bucket wall the section of thick bamboo wall detects the telescopic cylinder, the section of thick bamboo wall detects telescopic cylinder right-hand member face fixedly connected with bucket wall and detects the workstation.

Preferably, section of thick bamboo wall detection mechanism includes fixed connection and is in the bucket wall of bucket wall detection workstation up end detects the jar, bucket wall detects jar right-hand member face sliding connection and has the seal cover, it detects the chamber to be equipped with the bucket wall in the bucket wall detection jar, bucket wall detects intracavity sliding connection and has bucket wall to detect the sliding plate, bucket wall detects sliding plate right-hand member face fixedly connected with bucket wall and detects the cushion collar, be equipped with in the bucket wall detects the cushion collar and detects the sample chamber, fixedly connected with sampling output tube and bucket wall pressure pipe in the detection sample chamber left end wall.

Preferably, the barrel wall pressure pipe and the sampling output pipe penetrate through the left end wall of the detection sample cavity and the barrel wall detection sliding plate, the sampling output pipe and the barrel wall pressure pipe penetrate through the left end wall of the barrel wall detection cavity, a sliding plate pressure channel is arranged in the barrel wall pressure pipe, a barrel wall reagent pipe is slidably connected in the sliding plate pressure channel, the barrel wall reagent pipe penetrates through and is communicated with the detection sample cavity, the sliding plate pressure channel is communicated with the barrel wall detection cavity, the left end of the barrel wall pressure pipe is fixedly connected with the barrel wall detection air pump through a pipeline, and the left end face of the barrel wall reagent pipe is fixedly connected with the detection agent pipeline through a pipeline.

Preferably, circulation mechanism includes that two symmetries are fixed installation piece on the both ends face about the installation roof, installation roof up end fixed connection has reaction cylinder and sampling liquid pump, be equipped with the reaction chamber in the reaction cylinder, sampling liquid pump left end face fixedly connected with filling tube, fixed connection in the reaction chamber right-hand member wall the filling tube, the filling tube runs through the reaction chamber right-hand member wall, sampling liquid pump right-hand member face power is connected with the sampling pipeline, sampling pipeline fixed connection the sampling output tube, board and reaction chamber push pipe are looked to fixedly connected with in the reaction chamber upper end wall, the reaction chamber push pipe runs through the reaction chamber upper end wall.

Preferably, diapire detection mechanism includes fixed connection and is in the diapire of diapire contact plate up end detects air pump and diapire and detects flexible section of thick bamboo, the diapire detects air pump right-hand member face power and is connected with the flexible base of diapire, diapire detects flexible section of thick bamboo upper end sliding connection the flexible base of diapire, the flexible base right-hand member face fixedly connected with diapire of diapire detects the jar.

Preferably, the fixed main shaft front and back terminal surface fixedly connected with two fixed air pump seats of front and back symmetry, two equal fixedly connected with fixed bolster air pump on the fixed air pump seat, two equal power connection has fixed telescopic bracket on the fixed bolster air pump, two front and back symmetries fixed telescopic bracket mutually supports for support and balanced chemical drum.

Preferably, a bottom wall detection air cavity is arranged in the bottom wall detection cylinder, a light measurement fixing sleeve is fixedly connected in the bottom wall detection air cavity, a measurement sliding block is slidably connected in the bottom wall detection air cavity and located on the lower side of the light measurement fixing sleeve, a light measurement spring is fixedly connected between the upper end face of the measurement sliding block and the lower end face of the light measurement fixing sleeve, a light measurement air pipe is fixedly connected in the upper end wall of the bottom wall detection air cavity, the upper end of the light measurement air pipe is fixedly connected with the bottom wall detection air pump through a pipeline, a light measurement installation cavity is arranged in the measurement sliding block, and a light sensor is fixedly connected to the lower end wall of the light measurement installation cavity.

Preferably, an optical measurement auxiliary cavity is arranged in the right end wall of the bottom wall detection air cavity, an auxiliary optical measurement fixed block is fixedly connected in the optical measurement auxiliary cavity, an optical measurement auxiliary sliding block is slidably connected in the optical measurement auxiliary cavity, an optical measurement auxiliary spring is fixedly connected between the right end face of the optical measurement auxiliary sliding block and the left end face of the auxiliary optical measurement fixed block, a light source is fixedly connected to the left end face of the optical measurement auxiliary sliding block, a detection light channel is fixedly connected in the right end wall of the optical measurement installation cavity, and the right end face of the light sensor is fixedly connected to the detection light channel.

Compared with the prior art, the invention provides a device for inspecting the internal cleaning effect of a chemical barrel, which has the following beneficial effects:

the invention can provide power to support the circulation detection of the cleaning effect in the multi-position chemical engineering barrel by arranging the mounting top plate, the reaction cylinder, the sampling liquid pump, the reaction cavity top pipe and the detection agent cylinder, can detect the cleaning residual condition of non-granular chemical substances in the barrel by arranging the main shaft air pump, the main shaft telescopic barrel, the mounting main shaft, the detection agent liquid pump, the barrel wall detection air pump, the barrel wall detection telescopic barrel, the barrel wall detection cylinder, the sealing sleeve, the barrel wall detection workbench, the barrel wall detection sliding plate, the barrel wall pressure pipe, the barrel wall reagent pipe, the sampling output pipe, the barrel wall detection buffer sleeve and the sealing sleeve, and can ensure the accuracy of the detection result at the same time The invention can detect more fine granular substances remained in the barrel, can detect the cleaning effect of various chemical components by a circular detection method of solution chemical reaction, has higher accuracy on the detection result of the cleaning effect in the chemical barrel, does not pollute the environment in the barrel, is suitable for the detection of various cleaning effects in the barrel, and greatly improves the use safety of the chemical barrel.

Drawings

FIG. 1 is a schematic three-dimensional structure diagram of an inspection device for the cleaning effect inside a chemical bucket according to the present invention;

FIG. 2 is a schematic view of the overall structure of the device for inspecting the internal cleaning effect of the chemical bucket according to the present invention;

FIG. 3 is an enlarged partial schematic view of FIG. 2;

FIG. 4 is an enlarged partial schematic view of FIG. 3;

FIG. 5 is an enlarged partial schematic view of FIG. 2;

FIG. 6 is an enlarged partial schematic view of FIG. 5;

FIG. 7 is an enlarged partial schematic view of FIG. 2;

FIG. 8 is an enlarged partial schematic view of FIG. 2;

in the figure: 11. a circulating mechanism; 12. an auxiliary mechanism; 13. a cylinder wall detection mechanism; 14. a bottom wall detection mechanism; 15. installing a top plate; 16. mounting blocks; 17. a handle; 18. a reaction cylinder; 19. a reaction chamber; 20. an injection pipe; 21. a sampling liquid pump; 22. a sampling pipe; 23. a main shaft air pump; 24. a main shaft telescopic cylinder; 25. installing a main shaft; 26. a detector conduit; 27. the wall of the cylinder detects the telescopic cylinder; 28. a barrel wall detection cylinder; 29. sealing sleeves; 30. a bottom wall detection cylinder; 31. a barrel wall detection workbench; 32. a bottom wall detection telescopic cylinder; 33. a bottom wall telescopic base; 34. the bottom wall detects the air pump; 35. a barrel wall telescopic base; 36. a barrel wall detection air pump; 37. a bottom wall contact plate; 38. fixing the main shaft; 39. fixing a telescopic bracket; 40. installing a main shaft bottom plate; 41. a detector liquid pump; 42. a detection agent extraction tube; 43. a detection agent cylinder; 44. a detector chamber; 45. a barrel wall detection chamber; 46. a tub wall detection slide plate; 47. a barrel wall detection buffer sleeve; 48. a detection sample cavity; 49. a barrel wall pressure tube; 50. a cartridge wall reagent tube; 51. sampling and outputting the pipe; 52. a slide plate pressure channel; 53. a bottom wall detection air cavity; 54. a photometric fixing sleeve; 55. measuring a sliding block; 56. a photometric mounting cavity; 57. a light sensor; 58. an auxiliary optical measurement fixed block; 59. a light measuring spring; 60. a light-measuring trachea; 61. an optical measurement auxiliary spring; 62. a light measurement auxiliary cavity; 63. an optical measurement auxiliary slide block; 64. a light source; 65. detecting a light channel; 66. jacking a reaction cavity; 67. a peep plate; 68. a fixed bracket air pump; 69. and fixing the air pump seat.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments;

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.

Referring to fig. 1 to 8, the device for testing the cleaning effect inside the chemical engineering barrel according to the embodiment of the present invention includes a top installation plate 15, a main shaft air pump 23 is fixedly connected to a lower end surface of the top installation plate 15, a handle 17 is fixedly connected to an upper end surface of the top installation plate 15, a main shaft telescopic cylinder 24 is dynamically connected to a lower end surface of the main shaft air pump 23, an installation main shaft 25 is fixedly connected to a lower end surface of the main shaft telescopic cylinder 24, an installation main shaft bottom plate 40 is fixedly connected to a lower end surface of the installation main shaft 25, a fixed main shaft 38 is fixedly connected to a lower end surface of the installation main shaft bottom plate 40, a bottom wall contact plate 37 is fixedly connected to a lower end surface of the fixed main shaft 38, a circulation mechanism 11 is arranged at an upper end of the top installation plate 15, an auxiliary mechanism 12 is arranged at a lower end of the main shaft air pump 23, a barrel wall detection mechanism 13 is arranged at an upper end of the installation main shaft bottom plate 40, and a bottom wall detection mechanism 14 is arranged at an upper end of the bottom wall contact plate 37, the circulation mechanism 11 can assist in detecting the cleaning effect in the chemical bucket, the auxiliary mechanism 12 can provide a detection medium and switch the detection position, the barrel wall detection mechanism 13 can sample the cleaning effect of the barrel wall, and the bottom wall detection mechanism 14 can detect the cleaning effect of the barrel bottom.

In an embodiment of the present invention, the auxiliary mechanism 12 includes a detection agent cylinder 43 fixedly connected to the upper end surface of the mounting spindle base plate 40, a detection agent liquid pump 41, a barrel wall detection air pump 36, and a barrel wall telescopic base 35, a detection agent cavity 44 is disposed in the detection agent cylinder 43, a detection agent extraction pipe 42 is fixedly connected to the left end surface of the detection agent liquid pump 41, the detection agent extraction pipe 42 is fixedly connected to the right end wall of the detection agent cavity 44, the detection agent extraction pipe 42 penetrates through the right end wall of the detection agent cavity 44, a detection agent pipeline 26 is fixedly connected to the upper end of the detection agent liquid pump 41, a barrel wall detection telescopic barrel 27 is dynamically connected to the right end of the barrel wall detection air pump 36, the barrel wall telescopic base 35 is slidably and fixedly connected to the barrel wall detection telescopic barrel 27, and a barrel wall detection workbench 31 is fixedly connected to the right end surface of the barrel wall detection telescopic barrel 27.

In the embodiment of the present invention, the barrel wall detecting mechanism 13 includes a barrel wall detecting cylinder 28 fixedly connected to the upper end surface of the barrel wall detecting workbench 31, a sealing sleeve 29 is slidably connected to the right end surface of the barrel wall detecting cylinder 28, a barrel wall detecting cavity 45 is arranged in the barrel wall detecting cylinder 28, a barrel wall detecting sliding plate 46 is slidably connected to the barrel wall detecting cavity 45, a barrel wall detecting buffer sleeve 47 is fixedly connected to the right end surface of the barrel wall detecting sliding plate 46, a detecting sample cavity 48 is arranged in the barrel wall detecting buffer sleeve 47, and a sampling output tube 51 and a barrel wall pressure tube 49 are fixedly connected to the left end wall of the detecting sample cavity 48.

In the embodiment of the present invention, the barrel wall pressure tube 49 and the sampling output tube 51 penetrate through the left end wall of the detection sample cavity 48 and the barrel wall detection sliding plate 46, the sampling output tube 51 and the barrel wall pressure tube 49 penetrate through the left end wall of the barrel wall detection cavity 45, a sliding plate pressure channel 52 is arranged in the barrel wall pressure tube 49, a barrel wall reagent tube 50 is slidably connected in the sliding plate pressure channel 52, the barrel wall reagent tube 50 penetrates through the detection sample cavity 48, the sliding plate pressure channel 52 communicates with the barrel wall detection cavity 45, the left end of the barrel wall pressure tube 49 is fixedly connected to the barrel wall detection air pump 36 through a pipeline, and the left end face of the barrel wall reagent tube 50 is fixedly connected to the detection agent pipeline 26 through a pipeline.

In the embodiment of the present invention, the circulation mechanism 11 includes two mounting blocks 16 symmetrically fixed on the left and right end surfaces of the mounting top plate 15, the upper end surface of the mounting top plate 15 is fixedly connected with a reaction cylinder 18 and a sampling liquid pump 21, the reaction cylinder 18 is internally provided with a reaction chamber 19, the left end surface of the sampling liquid pump 21 is fixedly connected with an injection pipe 20, the right end wall of the reaction chamber 19 is internally fixedly connected with the injection pipe 20, the injection pipe 20 penetrates through the right end wall of the reaction chamber 19, the right end surface of the sampling liquid pump 21 is dynamically connected with a sampling pipeline 22, the sampling pipeline 22 is fixedly connected with the sampling output pipe 51, the upper end wall of the reaction chamber 19 is internally fixedly connected with a peeping plate 67 and a reaction chamber top pipe 66, and the reaction chamber top pipe 66 penetrates through the upper end wall of the reaction chamber 19.

In an embodiment of the present invention, the bottom wall detection mechanism 14 includes a bottom wall detection air pump 34 and a bottom wall detection telescopic cylinder 32 fixedly connected to an upper end surface of the bottom wall contact plate 37, a bottom wall telescopic base 33 is dynamically connected to a right end surface of the bottom wall detection air pump 34, an upper end of the bottom wall detection telescopic cylinder 32 is slidably connected to the bottom wall telescopic base 33, and a bottom wall detection cylinder 30 is fixedly connected to a right end surface of the bottom wall telescopic base 33.

In the embodiment of the present invention, two fixed air pump bases 69 that are symmetrical front and back are fixedly connected to the front and back end surfaces of the fixed main shaft 38, fixed bracket air pumps 68 are fixedly connected to both of the two fixed air pump bases 69, fixed telescopic brackets 39 are dynamically connected to both of the two fixed bracket air pumps 68, and the two fixed telescopic brackets 39 that are symmetrical front and back are mutually matched for supporting and balancing a chemical drum.

In the embodiment of the present invention, a bottom wall detection air cavity 53 is arranged in the bottom wall detection cylinder 30, a photometric fixing sleeve 54 is fixedly connected in the bottom wall detection air cavity 53, a measurement slider 55 is slidably connected in the bottom wall detection air cavity 53, the measurement slider 55 is located at the lower side of the photometric fixing sleeve 54, a photometric spring 59 is fixedly connected between the upper end surface of the measurement slider 55 and the lower end surface of the photometric fixing sleeve 54, a photometric air tube 60 is fixedly connected in the upper end wall of the bottom wall detection air cavity 53, the upper end of the photometric air tube 60 is fixedly connected to the bottom wall detection air pump 34 through a pipeline, a photometric mounting cavity 56 is arranged in the measurement slider 55, and a light sensor 57 is fixedly connected to the lower end wall of the photometric mounting cavity 56.

In the embodiment of the present invention, a light measurement auxiliary cavity 62 is arranged in the right end wall of the bottom wall detection air cavity 53, an auxiliary light measurement fixing block 58 is fixedly connected in the light measurement auxiliary cavity 62, a light measurement auxiliary slide block 63 is slidably connected in the light measurement auxiliary cavity 62, a light measurement auxiliary spring 61 is fixedly connected between the right end surface of the light measurement auxiliary slide block 63 and the left end surface of the auxiliary light measurement fixing block 58, a light source 64 is fixedly connected on the left end surface of the light measurement auxiliary slide block 63, a detection light channel 65 is fixedly connected in the right end wall of the light measurement installation cavity 56, and the right end surface of the light sensor 57 is fixedly connected with the detection light channel 65.

The invention discloses a device for testing the cleaning effect of the interior of a chemical barrel, which comprises the following working procedures:

in the initial state, the light measurement auxiliary spring 61 is in a relaxed state, and drives the light measurement auxiliary slider 63 and the light source 64 to be located at the positions to be worked, at this time, the light source 64 is located in the bottom wall detection air cavity 53, the light measurement spring 59 is in a contracted state, and drives the measurement slider 55, the light sensor 57 and the detection light channel 65 to be located in the bottom wall detection air cavity 53 to be stationary, at this time, the measurement slider 55 is located at the upper side position of the light measurement auxiliary cavity 62, the barrel wall detection buffer sleeve 47 and the barrel wall detection sliding plate 46 are located at the leftmost standby position in the barrel wall detection cavity 45, at this time, the barrel wall detection sliding plate 46 is attached to the left end wall of the barrel wall detection cavity 45, the seal sleeve 29 seals the detection sample cavity 48 to be protected from contamination, at this time, the fixed bracket air pump 68 and the bottom wall detection air pump 34, the barrel wall detection air pump 36, the detection agent liquid pump 41, the main shaft air pump 23, and the sampling liquid pump 21 are not activated, and the light source 64 and the light sensor 57 are not energized.

When the detection action is prepared, firstly, the sealing sleeve 29 is taken down from the right end of the barrel wall detection cylinder 28, then the whole device is quickly placed into the barrel to prevent the detection result from being inaccurate due to the pollution of the external environment, then the mounting block 16 is mounted and fixed at the position of the barrel opening, then the main shaft air pump 23 is started to drive the main shaft telescopic barrel 24 to extend, and the mounting main shaft 25, the mounting main shaft bottom plate 40, the fixed main shaft 38 and the bottom wall contact plate 37 are driven to integrally move towards the barrel bottom wall.

In the process that the bottom wall contact plate 37 is driven to move downwards, the bottom wall detection air pump 34 is started to drive the bottom wall telescopic base 33 to extend, the bottom wall detection cylinder 30 is driven to move to a proper position in the direction of the barrel side wall, the main shaft air pump 23 is closed after the bottom wall contact plate 37 moves to the barrel bottom, then the two front-back symmetrical fixed support air pumps 68 are started to drive the two front-back symmetrical fixed telescopic supports 39 to extend respectively, and after the fixed telescopic supports 39 contact the barrel wall, the fixed support air pumps 68 are closed and the position is kept, so that the preparatory installation alignment adjustment work is completed.

When the detection of the bottom wall of the barrel is started, the light source 64 is first powered on to emit detection light, then the light sensor 57 is powered on to stand by, then the bottom wall detection air pump 34 is started to drive the compressed air to enter the bottom wall detection air cavity 53 through the light detection air tube 60, so as to drive the detection slide block 55 to move downwards, when the detection slide block 55 moves downwards to the maximum descending distance of the lower end wall bottom surface of the bottom wall detection air cavity 53, the air pressure in the bottom wall detection air cavity 53 is kept stable, at the moment, the detection light emitted by the light source 64 is transmitted through the detection light channel 65 to be detected by the light sensor 57, if residual particulate matters exist in the bottom wall of the barrel, the uncleaned particulate matters can cause the detection slide block 55 not to be attached to the lower end surface flush position of the bottom wall detection air cavity 53, so that the detection light emitted by the light source 64 does not pass through the detection light channel 65, and therefore, the light sensor 57 cannot detect light signals, thereby giving an alarm indicating that the bottom wall of the tub still has particles unclean.

When the side wall of the barrel is detected, firstly, the barrel wall detection air pump 36 is started to make compressed air enter the barrel wall detection cavity 45 through the corresponding pipeline through the sliding plate pressure channel 52, the barrel wall detection sliding plate 46 and the barrel wall detection buffer sleeve 47 move to the right, when the barrel wall detection buffer sleeve 47 is tightly pressed on the side wall of the barrel to achieve a sealing state, then the detection agent liquid pump 41 is started to pump detection sample solution in the detection agent cavity 44 through the detection agent extraction pipe 42 and pump the detection sample solution into the barrel wall reagent pipe 50 through the detection agent pipeline 26, then the sampling liquid pump 21 is started to pump detection solution which is filled in the detection sample cavity 48 by the barrel wall reagent pipe 50 and contacts with the side wall of the barrel through the sampling pipeline 22 and the sampling output pipe 51, and then the detection solution is pumped into the reaction cavity 19 through the injection pipe 20 and mixed with the matching detection solution, at this time, if the side wall of the barrel is not clean and has residual chemical substances, the matching detection solution in the reaction chamber 19 will produce a predetermined reaction after mixing, and the detection result can be observed by looking at the plate 67.

When the detection result is obtained, cleaning action is required, cleaning agent is added into the detection agent cavity 44 through a pipeline, detection work is continuously carried out on the side wall of the same barrel, the cleaning agent circulates to the barrel side wall of a cleaning detection point in the detection sample cavity 48 under the detection work action, is pumped into the reaction cavity 19 through the sampling output pipe 51 by the sampling liquid pump 21, is discharged through the reaction cavity top pipe 66, accordingly, the detection work of the integral cleaning effect in the barrel is completed, and all parts are restored to the initial state.

The above description is only an embodiment of the present invention, and is not intended to limit the scope of the present invention, and all equivalent structures or equivalent processes performed by the present invention or directly or indirectly applied to other related technical fields will be covered by the scope of the present invention.

Claims (2)

1. The utility model provides an inside clean effect verifying attachment of chemical drum, includes installation roof (15), its characterized in that: the device comprises a mounting top plate (15), a main shaft air pump (23) is fixedly connected to the lower end face of the mounting top plate (15), a handle (17) is fixedly connected to the upper end face of the mounting top plate (15), a main shaft telescopic cylinder (24) is dynamically connected to the lower end face of the main shaft air pump (23), a mounting main shaft (25) is fixedly connected to the lower end face of the main shaft telescopic cylinder (24), a mounting main shaft bottom plate (40) is fixedly connected to the lower end face of the mounting main shaft bottom plate (40), a fixing main shaft (38) is fixedly connected to the lower end face of the fixing main shaft (38), a bottom wall contact plate (37) is fixedly connected to the lower end face of the fixing main shaft (38), a circulating mechanism (11) is arranged at the upper end of the mounting top plate (15), an auxiliary mechanism (12) is arranged at the lower end of the main shaft air pump (23), a cylinder wall detection mechanism (13) is arranged at the upper end of the mounting main shaft bottom plate (40), and a bottom wall detection mechanism (14) is arranged at the upper end of the bottom wall contact plate (37), the circulating mechanism (11) can assist in detecting the cleaning effect in the chemical barrel, the auxiliary mechanism (12) can provide a detection medium and switch the detection position, the barrel wall detection mechanism (13) can sample the barrel wall cleaning effect, and the bottom wall detection mechanism (14) can detect the barrel bottom cleaning effect;

the auxiliary mechanism (12) comprises a detection agent cylinder (43), a detection agent liquid pump (41), a barrel wall detection air pump (36) and a barrel wall telescopic base (35) which are fixedly connected to the upper end face of the installation spindle base plate (40), wherein a detection agent cavity (44) is formed in the detection agent cylinder (43), a detection agent extraction pipe (42) is fixedly connected to the left end face of the detection agent liquid pump (41), the detection agent extraction pipe (42) is fixedly connected to the right end wall of the detection agent cavity (44), the detection agent extraction pipe (42) penetrates through the right end wall of the detection agent cavity (44), a detection agent pipeline (26) is fixedly connected to the upper end of the detection agent liquid pump (41), a barrel wall detection telescopic barrel (27) is dynamically connected to the right end of the barrel wall detection air pump (36), and the barrel wall telescopic base (35) is fixedly connected to the barrel wall detection telescopic barrel (27) in a sliding manner, the right end face of the cylinder wall detection telescopic cylinder (27) is fixedly connected with a cylinder wall detection workbench (31);

the barrel wall detection mechanism (13) comprises a barrel wall detection cylinder (28) fixedly connected to the upper end face of the barrel wall detection workbench (31), the right end face of the barrel wall detection cylinder (28) is connected with a sealing sleeve (29) in a sliding manner, a barrel wall detection cavity (45) is arranged in the barrel wall detection cylinder (28), a barrel wall detection sliding plate (46) is connected in the barrel wall detection cavity (45) in a sliding manner, the right end face of the barrel wall detection sliding plate (46) is fixedly connected with a barrel wall detection buffer sleeve (47), a detection sample cavity (48) is arranged in the barrel wall detection buffer sleeve (47), and a sampling output tube (51) and a barrel wall pressure tube (49) are fixedly connected in the left end wall of the detection sample cavity (48);

the barrel wall pressure pipe (49) and the sampling output pipe (51) penetrate through the left end wall of the detection sample cavity (48) and the barrel wall detection sliding plate (46), the sampling output pipe (51) and the barrel wall pressure pipe (49) penetrate through the left end wall of the barrel wall detection cavity (45), a sliding plate pressure channel (52) is arranged in the barrel wall pressure pipe (49), a barrel wall reagent pipe (50) is connected in the sliding plate pressure channel (52) in a sliding mode, the barrel wall reagent pipe (50) penetrates and is communicated with the detection sample cavity (48), the sliding plate pressure channel (52) is communicated with the barrel wall detection cavity (45), the left end of the barrel wall pressure pipe (49) is fixedly connected with the barrel wall detection air pump (36) through a pipeline, and the left end face of the barrel wall reagent pipe (50) is fixedly connected with the detection agent pipeline (26) through a pipeline;

the circulating mechanism (11) comprises two mounting blocks (16) which are symmetrically fixed on the left end surface and the right end surface of the mounting top plate (15), the upper end surface of the mounting top plate (15) is fixedly connected with a reaction cylinder (18) and a sampling liquid pump (21), a reaction cavity (19) is arranged in the reaction cylinder (18), the left end face of the sampling liquid pump (21) is fixedly connected with an injection pipe (20), the right end wall of the reaction cavity (19) is fixedly connected with the injection pipe (20), the injection pipe (20) penetrates through the right end wall of the reaction cavity (19), the right end face of the sampling liquid pump (21) is dynamically connected with a sampling pipeline (22), the sampling pipeline (22) is fixedly connected with the sampling output pipe (51), the upper end wall of the reaction cavity (19) is internally and fixedly connected with a peeping plate (67) and a reaction cavity top pipe (66), the reaction cavity top pipe (66) penetrates through the upper end wall of the reaction cavity (19);

the bottom wall detection mechanism (14) comprises a bottom wall detection air pump (34) and a bottom wall detection telescopic cylinder (32), the bottom wall detection air pump (34) and the bottom wall detection telescopic cylinder are fixedly connected to the upper end face of the bottom wall contact plate (37), the right end face of the bottom wall detection air pump (34) is in power connection with a bottom wall telescopic base (33), the upper end of the bottom wall detection telescopic cylinder (32) is in sliding connection with the bottom wall telescopic base (33), and the right end face of the bottom wall telescopic base (33) is fixedly connected with a bottom wall detection cylinder (30);

the front end face and the rear end face of the fixed main shaft (38) are fixedly connected with two fixed air pump seats (69) which are symmetrical front and rear, fixed support air pumps (68) are fixedly connected to the two fixed air pump seats (69), fixed telescopic supports (39) are dynamically connected to the two fixed support air pumps (68), and the two fixed telescopic supports (39) which are symmetrical front and rear are matched with each other and used for supporting and balancing a chemical engineering barrel;

the device is characterized in that a bottom wall detection air cavity (53) is arranged in the bottom wall detection cylinder (30), a light measurement fixing sleeve (54) is fixedly connected in the bottom wall detection air cavity (53), a measurement sliding block (55) is connected in the bottom wall detection air cavity (53) in a sliding manner, the measurement sliding block (55) is positioned on the lower side of the light measurement fixing sleeve (54), a light measurement spring (59) is fixedly connected between the upper end surface of the measurement sliding block (55) and the lower end surface of the light measurement fixing sleeve (54), a light measurement air pipe (60) is fixedly connected in the upper end wall of the bottom wall detection air cavity (53), the upper end of the light measurement air pipe (60) is fixedly connected with the bottom wall detection air pump (34) through a pipeline, a light measurement mounting cavity (56) is arranged in the measurement sliding block (55), and a light sensor (57) is fixedly connected to the lower end wall of the light measurement mounting cavity (56).

2. The chemical bucket interior cleaning effect testing device of claim 1, wherein: an auxiliary optical measurement cavity (62) is arranged in the right end wall of the bottom wall detection air cavity (53), an auxiliary optical measurement fixing block (58) is fixedly connected in the auxiliary optical measurement cavity (62), an auxiliary optical measurement sliding block (63) is slidably connected in the auxiliary optical measurement cavity (62), an auxiliary optical measurement spring (61) is fixedly connected between the right end surface of the auxiliary optical measurement sliding block (63) and the left end surface of the auxiliary optical measurement fixing block (58), a light source (64) is fixedly connected to the left end surface of the auxiliary optical measurement sliding block (63), an optical detection channel (65) is fixedly connected in the right end wall of the optical measurement installation cavity (56), and the right end surface of the light sensor (57) is fixedly connected with the optical detection channel (65).

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