CN111220417B - Contactless sewage detection sample collecting device - Google Patents

Abstract

The invention discloses a non-contact sewage detection sample collecting device, which comprises a sewage collecting cavity arranged in a machine body, wherein a working cavity is arranged at the lower side of the sewage collecting cavity, a sample bottle cavity communicated with the working cavity is arranged at the front side of the working cavity, a first conveying device for conveying a sample bottle into the working cavity is arranged in the sample bottle cavity, and the first conveying device comprises a bottle inlet formed in the upper side wall of the sample bottle cavity and communicated with the outside of the machine body; the sample bottle sealing device is simple and convenient to operate and low in manufacturing cost, the pressing block can be driven to move up and down through the sliding fit of the guide groove seven and the sliding block II, the sample bottle is sealed through the soft plug, the push rod can be driven to move back and forth through the sliding fit of the sliding block III and the guide groove nine, and the sealed sample bottle is collected.

Description

Contactless sewage detection sample collecting device

Technical Field

The invention relates to the technical field of sewage detection, in particular to non-contact sewage detection sample collection equipment.

Background

Sewage treatment is for making sewage reach certain water of discharge or the quality of water requirement of reuse to its process of purifying, often need use among the sewage treatment check out test set to carry out the analysis of detection to sewage, before the analysis of detection, need collect sewage, the collection of present sewage is all that the manual work is held the test tube and is collected, because contains many pollutants in the sewage, causes the influence to surveyor's health easily.

Disclosure of Invention

The invention aims to provide a non-contact sewage detection sample collection device which is used for overcoming the defects in the prior art.

The non-contact sewage detection sample collection equipment comprises a machine body, wherein a sewage collection cavity is arranged in the machine body, a working cavity is arranged on the lower side of the sewage collection cavity, a sample bottle cavity communicated with the working cavity is arranged on the front side of the working cavity, a first conveying device for conveying a sample bottle into the working cavity is arranged in the sample bottle cavity, the first conveying device comprises a bottle inlet communicated with the outside of the machine body, which is formed in the upper side wall of the sample bottle cavity, first guide grooves are symmetrically formed in the positions of the left and right walls of the sample bottle cavity, a first sliding block is slidably installed between the first guide grooves on the two sides, a first pushing block is fixedly arranged on the rear side wall of the first sliding block, a first spring is fixedly arranged between the front side wall of the first sliding block and the front side wall of the first guide groove, a first auxiliary hole communicated with the outside of the machine body is formed in the front side wall of the machine body, the tail end of the front side of the first rotating shaft is fixedly provided with a first connecting rod, the first connecting rod is fixedly provided with a first handle, the front side wall of the first sliding block is fixedly provided with a first rope, the first rope penetrates through the first auxiliary hole and is wound on the first rotating shaft, the rear side of the working cavity is provided with a transmission cavity, the rear side wall of the working cavity is provided with a second guide groove communicated with the transmission cavity, the right side wall of the second guide groove is fixedly provided with a motor, the left side wall of the motor is rotatably provided with a screw rod, a nut spirally matched with the screw rod is arranged in the second guide groove in a sliding manner, the left and right positions of the front side wall of the nut are symmetrically and fixedly provided with first supporting blocks, the left side wall of the sample bottle cavity is provided with a third guide groove communicated with the working cavity, the left side wall of the third guide groove is provided with a fourth guide groove, a stop block is arranged in the fourth guide groove in a sliding manner, a second pushing block is fixedly arranged on the rear side wall of the stop block and is positioned on the left side of the first supporting block on the left side; the first handle is shaken to drive the first rotating shaft to rotate, the first rotating shaft drives the first sliding block to move forwards through the rope, a sample bottle is placed into the sample bottle cavity from the bottle inlet, the first handle is released, the sample bottle is pushed by the first push block to move towards the working cavity, the second push block is pushed by the first support block on the left side to drive the stop block to move leftwards, and when the second push block is completely arranged in the third guide groove, the sample bottle is pushed by the first push block to move between the first support blocks on two sides.

On the basis of the technical scheme, sewage is collected chamber downside wall and is set firmly the proportional valve, the shower nozzle is installed to proportional valve downside wall, lateral wall fixed mounting has the water pump on the organism, water pump downside wall install water pipe one with sewage is collected the intracavity intercommunication, water pipe two is installed to the lateral wall before the water pump, sewage is collected the chamber front side and is equipped with the water pipe and accomodates the chamber, the water pipe is accomodate the intracavity and is rotated and be equipped with and extend forward outside the organism rotation axis two, the intracavity is accomodate to the water pipe two go up around being equipped with water pipe three, three one end of water pipe with water pipe dual-purpose connector is connected, the three other ends of water pipe extend to outside the organism, two front side ends of rotation axis have set firmly connecting rod two, the handle two have set firmly on the connecting.

On the basis of the technical scheme, a soft plug cavity communicated with the working cavity is arranged on the right side of the sample bottle cavity, a second conveying device for pushing the soft plug into the working cavity is arranged in the soft plug cavity, a sealing device for sealing the soft plug filled with sewage for the sample bottle is arranged in the working cavity, a sample bottle collecting cavity communicated with the working cavity is arranged on the right side of the soft plug cavity, the front side of the sample bottle collecting cavity is communicated with the outside of the machine body, and a collecting device for pushing the sealed sample bottle into the sample bottle collecting cavity is arranged in the working cavity.

On the basis of the technical scheme, the conveying device II comprises a plug inlet which is formed in the side wall of the soft plug cavity and communicated with the outside of the machine body, guide grooves five are symmetrically formed in the left wall and the right wall of the soft plug cavity, pushing blocks three are arranged in the guide grooves five in two sides in a sliding mode, springs three are fixedly arranged between the front side walls of the pushing blocks three and the front side walls of the guide grooves five, auxiliary holes two communicated with the outside of the machine body are formed in the front side walls of the soft plug cavity, ropes two are fixedly arranged on the front side walls of the pushing blocks three, and the ropes two penetrate through the auxiliary holes two and are wound on the rotating shaft one.

On the basis of the technical scheme, the sealing device comprises a pressing block arranged in the working cavity, six guide grooves are symmetrically arranged on the front wall and the rear wall of the transmission cavity, the six guide grooves on the front side are communicated with the working cavity, sliding rods extending into the working cavity are arranged in the six guide grooves on the front side and the rear side in a sliding manner, a spring IV is fixedly arranged between the sliding rod and the upper side wall of the guide groove VI, the tail end of the front side of the sliding rod is fixedly arranged on the pressing block, a rack is fixedly arranged on the rear side wall of the nut, a first transmission shaft is rotatably arranged between the upper wall and the lower wall of the transmission cavity, the transmission shaft I is positioned on the left side of the sliding rod, an auxiliary wheel, a disk-shaped ratchet wheel and a bevel gear I meshed with the rack are fixedly arranged on the transmission shaft I from top to bottom in sequence, the auxiliary wheel is provided with a guide groove seven, and the left side wall of the sliding rod is fixedly provided with a sliding block II in sliding fit with the guide groove seven.

On the basis of the technical scheme, the collecting device comprises eight guide grooves which are formed in the rear side wall of the working cavity and communicated with the transmission cavity, guide blocks are arranged in the eight guide grooves in a sliding mode, auxiliary blocks are fixedly arranged on the rear side wall of each guide block, nine guide grooves are formed in the auxiliary blocks, a second transmission shaft is arranged on the lower side wall of the transmission cavity in a rotating mode, a disc and a second bevel gear meshed with the rack are sequentially and fixedly arranged on the second transmission shaft from top to bottom, a third sliding block is fixedly arranged on the upper side wall of the disc, the third sliding block is slidably arranged in the nine guide grooves, ten guide grooves are formed in the guide blocks, a second limiting block is arranged in the ten guide grooves in a sliding mode, a fifth spring is fixedly arranged between the rear side wall of the second limiting block and the ten rear side wall of each guide groove, and a push rod extending.

On the basis of the technical scheme, a partition plate is arranged on the front side of the machine body, support blocks II are symmetrically and fixedly arranged on the left and right sides of the rear side wall of the partition plate, guide grooves eleven are symmetrically formed in the left and right walls of the sample bottle collecting cavity, sliding blocks IV are slidably arranged in the guide grooves eleven and fixedly arranged on the support blocks II, guide grooves twelve are formed in the support blocks II in an array mode, limiting blocks III are slidably arranged in the guide grooves twelve, springs six are fixedly arranged between the limiting blocks III and the guide grooves twelve, and handles III are fixedly arranged on the front side wall of the partition plate.

The invention has the beneficial effects that: the sample bottle sealing device is simple and convenient to operate and low in manufacturing cost, the pressing block can be driven to move up and down through the sliding fit of the guide groove seven and the sliding block II, the sample bottle is sealed through the soft plug, the push rod can be driven to move back and forth through the sliding fit of the sliding block III and the guide groove nine, and the sealed sample bottle is collected.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic front view of a non-contact sewage test sample collection apparatus according to the present invention;

FIG. 2 is a schematic front view of the structure of FIG. 1;

FIG. 3 is a schematic view of the structure at A-A in FIG. 1;

FIG. 4 is a schematic view of the structure at B-B in FIG. 1;

FIG. 5 is a schematic view of the structure at C-C in FIG. 1;

FIG. 6 is a schematic view of the structure of FIG. 1 at D-D;

FIG. 7 is a schematic view of the structure at E-E in FIG. 5;

FIG. 8 is an enlarged view of the structure of FIG. 4 at the stop;

FIG. 9 is an enlarged view of the push rod of FIG. 4;

FIG. 10 is an enlarged view of the three positions of the limiting block in FIG. 4; .

Detailed Description

The invention will now be described in detail with reference to fig. 1-10, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1-10, a non-contact sewage detection sample collecting apparatus according to an embodiment of the present invention includes a machine body 10, a sewage collecting chamber 11 is disposed in the machine body 10, a working chamber 21 is disposed at a lower side of the sewage collecting chamber 11, a sample bottle chamber 49 communicated with the working chamber 21 is disposed at a front side of the working chamber 21, a first conveying device 88 for conveying a sample bottle 24 into the working chamber 21 is disposed in the sample bottle chamber 49, the first conveying device 88 includes a bottle inlet 48 formed in an upper side wall of the sample bottle chamber 49 and communicated with an outside of the machine body 10, first guide grooves 50 are symmetrically formed in left and right walls of the sample bottle chamber 49, first sliding blocks 52 are slidably mounted between the first guide grooves 50 on both sides, first push blocks 53 are fixedly mounted on a rear side wall of the first sliding blocks 52, first springs 51 are fixedly mounted between front side walls of the first sliding blocks 52 and the first guide grooves 50, the front side wall of the sample bottle cavity 49 is provided with a first auxiliary hole 36 communicated with the outside of the machine body 10, the front side wall of the machine body 10 is rotatably provided with a first rotating shaft 39, the tail end of the front side of the first rotating shaft 39 is fixedly provided with a first connecting rod 38, the first connecting rod 38 is fixedly provided with a first handle 35, the front side wall of the first sliding block 52 is fixedly provided with a first rope 40, the first rope 40 passes through the first auxiliary hole 36 and is wound on the first rotating shaft 39, the rear side of the working cavity 21 is provided with a transmission cavity 56, the rear side wall of the working cavity 21 is provided with a second guide groove 20 communicated with the transmission cavity 56, the right side wall of the second guide groove 20 is fixedly provided with a motor 19, the left side wall of the motor 19 is rotatably provided with a screw rod 22, a nut 55 in threaded fit with the screw rod 22 is arranged in the second guide groove 20 in a sliding manner, the left and right positions of the front side wall of the nut 55 are symmetrically provided with, a fourth guide groove 84 is formed in the left side wall of the third guide groove 86, a stop block 82 is arranged in the fourth guide groove 84 in a sliding manner, a first limit block 83 is fixedly arranged on the front side wall of the stop block 82, a second spring 85 is fixedly arranged between the first limit block 83 and the right side wall of the fourth guide groove 84, a second push block 81 is fixedly arranged on the rear side wall of the stop block 82, and the second push block 81 is positioned on the left side of the first support block 23 on the left side; the first handle 35 is shaken to drive the first rotating shaft 39 to rotate, the first rotating shaft 39 drives the first sliding block 52 to move forwards through the first rope 40, the sample bottle 24 is placed into the sample bottle cavity 49 from the bottle inlet 48, the first handle 35 is released, so that the sample bottle 24 is pushed by the first push block 53 to move towards the working cavity 21, the second push block 81 is pushed by the first support block 23 on the left side to drive the stop block 82 to move leftwards, and when the second push block 81 is completely arranged in the third guide groove 86, the sample bottle 24 is pushed by the first push block 53 to move to the position between the first support blocks 23 on the two sides.

In addition, in one embodiment, a quantitative valve 26 is fixedly arranged on the lower side wall of the sewage collecting cavity 11, the lower side wall of the proportional valve 26 is provided with a spray head 25, the upper side wall of the machine body 10 is fixedly provided with a water pump 12, a water pipe 44 arranged on the lower side wall of the water pump 12 is communicated with the sewage collecting cavity 11, a second water pipe 27 is arranged on the front side wall of the water pump 12, a water pipe accommodating cavity 46 is arranged on the front side of the sewage collecting cavity 11, a second rotating shaft 29 extending forwards to the outside of the machine body 10 is rotatably arranged in the water pipe accommodating cavity 46, a third water pipe 42 is wound on the second rotating shaft 29 in the water pipe accommodating cavity 46, one end of the third water pipe 42 is connected with the second water pipe 27 through a connector 45, the other end of the water pipe III 42 extends out of the machine body 10, a connecting rod II 43 is fixedly arranged at the tail end of the front side of the rotating shaft II 29, and a handle II 28 is fixedly arranged on the connecting rod II 43.

In one embodiment, a cork chamber 37 communicating with the working chamber 21 is provided on the right side of the sample bottle chamber 49, a second conveying device 89 for pushing the cork 30 into the working chamber 21 is provided in the cork chamber 37, a sealing device 90 for sealing the sample bottle 24 filled with contaminated water with the cork 30 is provided in the working chamber 21, a sample bottle collecting chamber 67 communicating with the working chamber 21 is provided on the right side of the cork chamber 37, the front side of the sample bottle collecting chamber 67 communicates with the outside of the machine body 10, and a collecting device 91 for pushing the sealed sample bottle 24 into the sample bottle collecting chamber 67 is provided in the working chamber 21.

In addition, in one embodiment, the second conveying device 89 includes a plug inlet 63 formed in an upper side wall of the soft plug cavity 37 and communicated with the outside of the machine body 10, guide grooves five 32 symmetrically formed in left and right walls of the soft plug cavity 37, push blocks three 61 slidably arranged in the guide grooves five 32 on two sides, a spring three 62 fixedly arranged between front side walls of the push blocks three 61 and front side walls of the guide grooves five 32, an auxiliary hole two 64 formed in a front side wall of the soft plug cavity 37 and communicated with the outside of the machine body 10, a rope two 41 fixedly arranged on a front side wall of the push blocks three 61, and the rope two 41 passing through the auxiliary hole two 64 and wound on the first rotating shaft 39; the first rotating shaft 39 rotates to drive the third pushing block 61 to move forwards through the second rope 41, the soft plug 30 is placed into the soft plug cavity 37 from the plug inlet 63, and the third pushing block 61 pushes the soft plug 30 to move towards the working cavity 21 through the third spring 62.

In addition, in one embodiment, the sealing device 90 includes a pressing block 15 disposed in the working chamber 21, guide grooves six 13 are symmetrically disposed on front and rear walls of the transmission chamber 56, the guide grooves six 13 on the front side are communicated with the working chamber 21, sliding rods 75 extending into the working chamber 21 are slidably disposed in the guide grooves six 13 on the front and rear sides, a spring four 14 is fixedly disposed between the sliding rods 75 and the upper side walls of the guide grooves six 13, the front end of the sliding rod 75 is fixedly disposed on the pressing block 15, a rack 54 is fixedly disposed on the rear side wall of the nut 55, a first transmission shaft 69 is rotatably disposed between the upper and lower walls of the transmission chamber 56, the first transmission shaft 69 is disposed on the left side of the sliding rod 75, an auxiliary wheel 80, a disc-shaped ratchet 78 and a first bevel gear 70 engaged with the rack 54 are fixedly disposed on the first transmission shaft 69 from top to bottom, a guide groove seven 79 is disposed on the auxiliary wheel 80, a second sliding block 57 in sliding fit with the seventh guide groove 79 is fixedly arranged on the left side wall of the sliding rod 75; the nut 55 moves rightwards along the second guide groove 20, the nut 55 is meshed with the first bevel gear 70 through the rack 54 to drive the first transmission shaft 69 to rotate, the first transmission shaft 69 is in sliding fit with the second sliding block 57 through the seventh guide groove 79 to drive the sliding rod 75 to slide upwards along the sixth guide groove 13, the six guide grooves 13 drive the pressing block 15 to move upwards, the soft plug 30 is pushed down to between the pressing block 15 and the sample bottle 24 by the second conveying device 89, after the sample bottle 24 stops moving, the second sliding block 57 moves downwards along the six guide grooves 13 under the action of the fourth spring 14, the guide groove six 13 pushes the cork 30 into the sample bottle 24 through the press block 15 for sealing, and when the nut 55 moves to the left, due to the disc-shaped ratchet wheel 78, the rack 54 is meshed with the bevel gear 70, so that the auxiliary wheel 80 cannot be driven to rotate.

In addition, in one embodiment, the collecting device 91 includes a guide groove eight 16 formed in the rear side wall of the working chamber 21 and communicated with the transmission chamber 56, a guide block 18 is slidably disposed in the guide groove eight 16, an auxiliary block 65 is fixedly disposed on the rear side wall of the guide block 18, a guide groove nine 87 is formed in the auxiliary block 65, a transmission shaft two 60 is rotatably disposed on the lower side wall of the transmission chamber 56, a circular disc 58 and a bevel gear two 59 engaged with the rack 54 are sequentially and fixedly disposed on the transmission shaft two 60 from top to bottom, a sliding block three 76 is fixedly disposed on the upper side wall of the circular disc 58, the sliding block three 76 is slidably disposed in the guide groove nine 87, a guide groove ten 71 is formed in the guide block 18, a stopper two 31 is slidably disposed in the guide groove ten 71, and a spring five 77 is fixedly disposed between the rear side wall of the stopper two 31 and the rear side wall of the guide, a push rod 17 extending out of the guide block 18 is fixedly arranged on the front side wall of the second limiting block 31; the rack 54 moves leftwards, the bevel gear 59 is meshed with the transmission shaft II 60 to drive the transmission shaft II 60 to rotate, the transmission shaft II 60 drives the disc 58 to rotate, the disc 58 is in sliding fit with the guide groove nine 87 through the sliding block III 76 to drive the guide block 18 to move back and forth along the guide groove eight 16, and the guide block 18 pushes the sample bottle 24 into the sample bottle collecting cavity 67 through the push rod 17.

In addition, in one embodiment, a partition plate 34 is disposed on the front side of the machine body 10, support blocks two 66 are symmetrically and fixedly disposed on the left and right sides of the rear side wall of the partition plate 34, guide grooves eleven 73 are symmetrically disposed on the left and right walls of the sample bottle collection cavity 67, slide blocks four 74 are slidably disposed in the guide grooves eleven 73, the slide blocks four 74 are fixedly disposed on the support blocks two 66, guide grooves twelve 47 are disposed on the support blocks two 66 in an array manner, limit blocks three 68 are slidably disposed in the guide grooves twelve 47, springs six 72 are fixedly disposed between the limit blocks three 68 and the guide grooves twelve 47, and handles three 33 are fixedly disposed on the front side wall of the partition plate 34.

In an initial state, the second spring 85, the first spring 51, the fourth spring 14, the third spring 62, the fifth spring 77 and the sixth spring 72 are all in a relaxed state, so that the right side wall of the stopper 82 is in contact with the right side wall of the sample bottle cavity 49, the first sliding block 52 is in contact with the rear side wall of the first guide groove 50, the press block 15 blocks the cork cavity 37, the third push block 61 is in contact with the rear side wall of the fifth guide groove 32, the second limit block 31 is in contact with the front side wall of the tenth guide groove 71, and the third limit block 68 is half in the twelfth guide groove 47.

Before the sample bottle starts to work, the first handle 35 is shaken to drive the first rotating shaft 39 to rotate, the first rotating shaft 39 drives the first sliding block 52 and the third pushing block 61 to move forwards through the first rope 40 and the second rope 41 respectively, an empty sample bottle 24 is placed into the sample bottle cavity 49 from the bottle inlet 48, the first handle 35 is released after the cork 30 is placed into the cork cavity 37 from the cork inlet 63, the sample bottle 24 moves towards the working cavity 21 under the pushing of the first sliding block 52, and the cork 30 moves towards the working cavity 21 in a reverse direction under the pushing of the third pushing block 61.

When a sewage sample is collected, the third water pipe 42 is pulled, the third water pipe 42 is placed in the sewage, the water pump 12 is started, and the sewage is pumped into the sewage collecting cavity 11 along the third water pipe 42, the second water pipe 27 and the first water pipe 44.

The motor 19 is started to drive the screw rod 22 to rotate, the nut 55 moves leftwards through spiral fit with the screw rod 22, the block 82 is pushed away through the left support block I23, and the sample bottle 24 is pushed to move between the two support blocks I23 on the two sides through the sliding block I52.

The quantitative valve 26 is opened, a certain amount of sewage is sprayed into the sample bottle 24 through the spray head 25, the motor 19 is started to drive the screw 22 to rotate, the screw 22 drives the sample bottle 24 to move rightwards through screw fit with the nut 55 and then stops after moving to the lower part of the pressing block 15, the sample bottle 24 is sealed through the sealing device 90 while moving, after the sample bottle 24 is sealed, the nut 55 continuously drives the sample bottle 24 to move rightwards and then stops after moving to the right back of the sample bottle collecting cavity 67, the sample bottle 24 is pushed into the sample bottle collecting cavity 67 through the collecting device 91 while moving, and the motor 19 reversely rotates to drive the nut 55 to move leftwards and return to the original position.

After the sewage sample is collected, the third handle 33 is pulled to draw the second supporting block 66 out of the sample bottle collecting cavity 67, the second handle 28 is shaken to drive the second rotating shaft 29 to rotate, and the third water pipe 42 is retracted into the water pipe accommodating cavity 46.

The invention has the beneficial effects that: the sample bottle sealing device is simple and convenient to operate and low in manufacturing cost, the pressing block can be driven to move up and down through the sliding fit of the guide groove seven and the sliding block II, the sample bottle is sealed through the soft plug, the push rod can be driven to move back and forth through the sliding fit of the sliding block III and the guide groove nine, and the sealed sample bottle is collected.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (7)

1. The utility model provides a contactless sewage detection sample collecting device, includes the organism, its characterized in that: the machine body is internally provided with a sewage collecting cavity, the lower side of the sewage collecting cavity is provided with a working cavity, the front side of the working cavity is provided with a sample bottle cavity communicated with the working cavity, the sample bottle cavity is internally provided with a first conveying device for conveying a sample bottle into the working cavity, the first conveying device comprises a bottle inlet communicated with the outside of the machine body, which is formed in the upper side wall of the sample bottle cavity, the left and right walls of the sample bottle cavity are symmetrically provided with first guide grooves, a first sliding block is slidably arranged between the first guide grooves at the two sides, a first push block is fixedly arranged on the rear side wall of the first sliding block, a first spring is fixedly arranged between the front side wall of the first sliding block and the front side wall of the first guide groove, the front side wall of the sample bottle cavity is provided with a first auxiliary hole communicated with the outside of the machine body, the front side wall of the machine body is rotatably provided with a first rotating shaft, the tail, a first rope is fixedly arranged on the front side wall of the first sliding block, the first rope penetrates through the first auxiliary hole and is wound on the first rotating shaft, a transmission cavity is arranged on the rear side of the working cavity, a second guide groove communicated with the transmission cavity is formed in the rear side wall of the working cavity, a motor is fixedly arranged on the right side wall of the second guide groove, a screw rod is rotatably arranged on the left side wall of the motor, a nut in spiral fit with the screw rod is arranged in the second guide groove in a sliding manner, first supporting blocks are symmetrically and fixedly arranged on the left and right positions of the front side wall of the nut, a third guide groove communicated with the working cavity is formed in the left side wall of the sample bottle cavity, a fourth guide groove is formed in the left side wall of the third guide groove, a stop block is arranged in the fourth guide groove in a sliding manner, a first limiting block is fixedly arranged on the front side wall of the stop block, a second spring, the two push blocks are positioned on the left side of the supporting block on the left side; the first handle is shaken to drive the first rotating shaft to rotate, the first rotating shaft drives the first sliding block to move forwards through the rope, a sample bottle is placed into the sample bottle cavity from the bottle inlet, the first handle is released, the sample bottle is pushed by the first push block to move towards the working cavity, the second push block is pushed by the first support block on the left side to drive the stop block to move leftwards, and after the second push block is completely placed in the third guide groove, the sample bottle is pushed by the first push block to move to the position between the first support blocks on the two sides.

2. The non-contact sewage detection sample collection apparatus according to claim 1, wherein: sewage is collected chamber downside wall and is set firmly the proportional valve, the shower nozzle is installed to proportional valve downside wall, lateral wall fixed mounting has the water pump on the organism, water pump downside wall install water pipe one with the intracavity intercommunication is collected to sewage, water pipe two is installed to the lateral wall before the water pump, sewage is collected the chamber front side and is equipped with the water pipe and accomodates the chamber, the water pipe is accomodate the intracavity and is rotated and be equipped with and extend forward outside the organism rotation axis two, the intracavity is accomodate to the water pipe around being equipped with water pipe three on the rotation axis two, three one end of water pipe with the water pipe dual-purpose connector is connected, the three other ends of water pipe extend to outside the organism, two front side ends of rotation axis have set firmly connecting rod two, set firmly handle two on the.

3. The non-contact sewage detection sample collection apparatus according to claim 1, wherein: the utility model discloses a sample bottle is including working chamber, sample bottle chamber, soft stopper chamber, sealing device, sample bottle collection chamber, the sample bottle chamber right side be equipped with the soft stopper chamber of working chamber intercommunication, the soft stopper intracavity is equipped with and pushes the soft stopper into conveyor two in the working chamber, be equipped with the closing device that seals the soft stopper for the sample bottle that will irritate sewage in the working chamber, soft stopper chamber right side be equipped with the sample bottle collection chamber of working chamber intercommunication, sample bottle collection chamber front side with the outer intercommunication of organism, be equipped with in the working chamber and push the sample bottle after sealing into the collection device of sample bottle collection intracavity.

4. The non-contact sewage detection sample collection apparatus according to claim 3, wherein: the conveying device II comprises a plug inlet which is formed in the side wall of the soft plug cavity and communicated with the outside of the machine body, a guide groove V is symmetrically formed in the left wall and the right wall of the soft plug cavity, a pushing block III is arranged in the guide groove V on two sides in a sliding mode, a spring III is fixedly arranged between the front side wall of the pushing block III and the front side wall of the guide groove V, an auxiliary hole II communicated with the outside of the machine body is formed in the front side wall of the soft plug cavity, a rope II is fixedly arranged on the front side wall of the pushing block III, and the rope II penetrates through the auxiliary hole II and is wound on the rotating shaft I.

5. The non-contact sewage detection sample collection apparatus according to claim 3, wherein: the sealing device comprises a pressing block arranged in the working cavity, six guide grooves are symmetrically formed in the front wall and the rear wall of the transmission cavity, the six guide grooves on the front side are communicated with the working cavity, sliding rods extending into the working cavity are slidably arranged in the six guide grooves on the front side and the rear side, a spring IV is fixedly arranged between the sliding rod and the upper side wall of the guide groove VI, the tail end of the front side of the sliding rod is fixedly arranged on the pressing block, a rack is fixedly arranged on the rear side wall of the nut, a first transmission shaft is rotatably arranged between the upper wall and the lower wall of the transmission cavity, the transmission shaft I is positioned on the left side of the sliding rod, an auxiliary wheel, a disk-shaped ratchet wheel and a bevel gear I meshed with the rack are fixedly arranged on the transmission shaft I from top to bottom in sequence, the auxiliary wheel is provided with a guide groove seven, and the left side wall of the sliding rod is fixedly provided with a sliding block II in sliding fit with the guide groove seven.

6. The non-contact sewage detection sample collection apparatus according to claim 5, wherein: the collecting device comprises eight guide grooves which are formed in the rear side wall of the working cavity and communicated with the transmission cavity, guide blocks are arranged in the eight guide grooves in a sliding mode, auxiliary blocks are fixedly arranged on the rear side wall of each guide block, nine guide grooves are formed in the auxiliary blocks, a second transmission shaft is arranged on the lower side wall of the transmission cavity in a rotating mode, a disc and a second bevel gear meshed with the rack are sequentially arranged on the second transmission shaft from top to bottom, a third sliding block is fixedly arranged on the upper side wall of the disc, the third sliding block is slidably arranged in the nine guide grooves, ten guide grooves are formed in the guide blocks, a second limiting block is arranged in the ten guide grooves in a sliding mode, a fifth spring is fixedly arranged between the two rear side walls of the limiting block and the ten rear side walls of the guide grooves, and a push rod extending to the outside.

7. The non-contact sewage detection sample collection apparatus according to claim 3, wherein: the sample bottle collecting device is characterized in that a partition plate is arranged on the front side of the machine body, supporting blocks II are symmetrically and fixedly arranged on the left side and the right side of the rear side wall of the partition plate, guide grooves eleven are symmetrically formed in the left side and the right side of the sample bottle collecting cavity, sliding blocks IV are arranged in the guide grooves eleven in a sliding mode, the sliding blocks IV are fixedly arranged on the supporting blocks II, guide grooves twelve are formed in the supporting blocks II in an array mode, limiting blocks III are arranged in the guide grooves twelve in a sliding mode, springs six are fixedly arranged between the limiting blocks III and the guide grooves twelve, and handles III.

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