CN116609129A

CN116609129A - Water source sampling detection device for animal husbandry

Info

Publication number: CN116609129A
Application number: CN202310513202.5A
Authority: CN
Inventors: 程春霞; 任敬博; 姚丽娟; 牛蒿; 王徐民
Original assignee: Individual
Current assignee: Individual
Priority date: 2023-05-09
Filing date: 2023-05-09
Publication date: 2023-08-18

Abstract

The invention discloses a water source sampling detection device for animal husbandry, which comprises a shell, wherein a rectangular accommodating block is fixedly connected to the shell, a suction barrel for extracting water source is arranged in the rectangular accommodating block, a sampling assembly swinging along a semicircular track in the horizontal direction is arranged in the rectangular accommodating block, the sampling assembly comprises a swinging column arranged in the rectangular accommodating block, the swinging column reciprocates vertically when in a semicircular track terminal, the suction barrel is fixedly connected to the shell, a piston plate is fixedly connected to the bottom of the swinging column, a water absorbing assembly for enabling the water source to enter the suction barrel is arranged at the bottom of the suction barrel, a placing seat swinging at fixed time is arranged at one side of the rectangular accommodating block, and the single swinging angle of the placing seat is a fan-shaped included angle between two adjacent open beakers.

Description

Water source sampling detection device for animal husbandry

Technical Field

The invention relates to the technical field of water source detection devices for animal husbandry, in particular to a water source sampling detection device for animal husbandry.

Background

Animal husbandry is a production department of animal products such as meat, eggs, milk, wool, cashmere, skin, silk and medicinal materials by utilizing the physiological functions of animals such as livestock and poultry which are domesticated by human beings or wild animals such as deer, musk, fox, marten, otter, quail and the like, and converting plant energy such as pasture and feed into animal energy through artificial feeding and reproduction.

In the livestock raising process, water sources are prevented from being searched near chemical plants, pesticide plants, slaughterhouses and the like as much as possible, if ground water is selected as a drinking water source, necessary purification, precipitation and disinfection are carried out according to the actual condition of water quality, if well water is selected as the drinking water source, a well cover is required to be covered again, birds and other substances which possibly cause water quality pollution are prevented from entering, therefore, in the using process of the livestock water source, the used water source is required to be detected at regular time, but the conventional sampling and detecting device for the livestock water source is inconvenient to sample and detect the water source for multiple times, and therefore, certain improvement exists.

Disclosure of Invention

The invention aims to provide a water source sampling and detecting device for animal husbandry, which has the advantages of realizing continuous sampling of an animal husbandry water source, ensuring diversification of detection data and reducing the workload of multiple sampling, and solves the problem of inconvenience in multiple sampling operation of the animal husbandry water source.

In order to achieve the above purpose, the present invention provides the following technical solutions: the water source sampling and detecting device for the animal husbandry comprises a shell, wherein a rectangular accommodating block is fixedly connected to the shell, and a suction cylinder for extracting a water source is arranged in the rectangular accommodating block;

the sampling assembly swings in a semicircular track in the horizontal direction and comprises a swinging column arranged in a rectangular accommodating block, the swinging column vertically reciprocates when being positioned above a suction cylinder body when being positioned at the terminal end of the semicircular track, the suction cylinder body is fixedly connected to a shell, a piston plate is fixedly connected to the bottom of the swinging column, the peripheral surface of the piston plate is in sliding contact with the suction cylinder body, and a water absorbing assembly for enabling a water source to enter the suction cylinder body is arranged at the bottom of the suction cylinder body;

one side of the rectangular containing block is provided with a placing seat which swings regularly, a plurality of groups of open beakers which are distributed at equal intervals are arranged on the placing seat, a water outlet pipeline in the sampling assembly synchronously rotates with the swing column, the water outlet end of the water outlet pipeline corresponds to the position of the open beakers, and the single swinging angle of the placing seat is a fan-shaped included angle between two adjacent open beakers.

Preferably, the rectangle holds the piece in have the rotary drum through circular channel body sliding connection, is equipped with the reciprocating pivoted crank assembly of drive rotary drum in the casing, is in the rotary drum inside toward pendulum post and rotary drum coaxial and toward pendulum post, toward the epaxial spacing post of fixedly connected with of pendulum, spacing post is through seting up the spacing groove sliding contact rotary drum on the rotary drum, and spacing groove shape is the reverse V-arrangement.

Preferably, the rectangular accommodating block is fixedly connected with a positioning column, the positioning column is connected with the swing column in a sliding manner through a positioning groove formed in the swing column, the positioning groove is U-shaped, and the positioning groove comprises two groups of vertical sliding parts and one group of horizontal sliding parts which are integrally formed.

Preferably, the water absorbing assembly comprises a water inlet pipeline fixedly penetrating through the bottom of the suction cylinder, a water outlet pipeline fixedly penetrating through the piston plate, the water outlet pipeline penetrates through the swing column, and one-way valves are fixedly connected to the water inlet pipeline and the water outlet pipeline and limit water sources to enter the suction cylinder from the water inlet pipeline and be discharged out of the suction cylinder from the water outlet pipeline.

Preferably, a water inlet nozzle is fixedly communicated with one water inlet end of the water inlet pipeline, and a filter screen is fixedly connected to the water inlet nozzle.

Preferably, the crank assembly comprises a rotating shaft which is driven by a motor to freely rotate in the shell, the rotating shaft is fixedly connected with a third gear, the third gear is rotationally connected with one end of a swinging rod through a rotating pin, the other end of the swinging rod is fixedly connected to a second gear, the second gear is meshed with a first gear, the first gear is fixedly sleeved on the rotary drum, the second gear is fixedly sleeved on the shell, the second gear is rotationally fixed on the shell, and a rectangular accommodating block is provided with a channel corresponding to the second gear.

Preferably, the rotation shaft is provided with a driving placement seat directional swinging intermittent swing assembly, the intermittent swing assembly comprises a cross rod and an arc plate which are fixedly connected to the rotation shaft, an adjusting column is fixedly connected to the cross rod, the bottom of the placement seat is fixedly connected with a positioning seat, the positioning seat is fixedly pivoted on the shell, a plurality of groups of yielding through grooves for sliding of the adjusting column are formed in the positioning seat at equal intervals, a plurality of groups of arc grooves are formed in the edge of the positioning seat at equal intervals, and the arc plate is in sliding contact with the arc grooves.

Preferably, a plurality of groups of placing grooves for placing the open beakers are formed in the placing seats at equal intervals, the placing seats are connected with the shell in a sliding mode through the through grooves, and the number of the placing grooves is consistent with the number of the yielding through grooves.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, by arranging the sampling assembly and the intermittent assembly, continuous multi-group sampling of the water source can be realized when the livestock water source is sampled and detected, so that the diversity and the accuracy of the detected samples are ensured, the workload of multi-group sub-sampling of the livestock water source can be reduced, and the convenience is brought to staff.

2. According to the invention, the crank assembly is arranged, so that the rotary drum can rotate in a sector manner in the horizontal direction, the orientation of the water outlet pipeline can be adjusted through the mutual matching among the limit groove, the locating groove, the limit column and the locating column, the piston plate can be driven by the swing column in the horizontal direction to realize the release process of sucking the livestock water source, and then the water sample operation of the water livestock water source is completed.

Drawings

FIG. 1 is a perspective view of the overall structure of the present invention;

FIG. 2 is a schematic view of the position of the water inlet pipeline according to the present invention;

FIG. 3 is a schematic diagram of the positions of gears II and I according to the present invention;

FIG. 4 is a schematic illustration of the position of a piston plate of the present invention;

FIG. 5 is a schematic diagram of a pendulum assembly according to the present invention;

FIG. 6 is a schematic view of a crank assembly of the present invention;

FIG. 7 is a schematic view of the orientation of the water outlet pipe of the present invention;

FIG. 8 is an expanded view of the limiting groove and the positioning groove of the present invention.

In the figure: 1. a rectangular accommodation block; 2. a rotating drum; 3. swing column; 4. a limit groove; 5. a positioning groove; 51. a vertical sliding portion; 52. a horizontal sliding portion; 6. a limit column; 7. positioning columns; 8. a piston plate; 9. a suction cylinder; 10. a water outlet pipe; 11. a water inlet pipe; 12. a water inlet nozzle; 13. a first gear; 14. a second gear; 15. a rotating shaft; 16. a third gear; 17. swing rod; 18. a cross bar; 19. an adjusting column; 20. an arc-shaped plate; 21. a fixed swinging seat; 22. a yielding through groove; 23. an arc-shaped groove; 24. a placement seat; 25. a placement groove; 26. an open beaker; 27. and a channel groove.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 8, the present invention provides a technical solution: the water source sampling and detecting device for the animal husbandry comprises a shell, wherein a rectangular accommodating block 1 is fixedly connected to the shell, and a suction cylinder 9 for extracting a water source is arranged in the rectangular accommodating block 1;

the sampling assembly swings in a semicircular track in the horizontal direction, the sampling assembly comprises a swinging column 3 arranged in a rectangular accommodating block 1, the swinging column 3 reciprocates vertically when in a semicircular track terminal, the swinging column 3 is positioned above a suction cylinder 9, the suction cylinder 9 is fixedly connected to a shell, a piston plate 8 is fixedly connected to the bottom of the swinging column 3, the outer peripheral surface of the piston plate 8 is in sliding contact with the suction cylinder 9, and a water absorbing assembly for enabling a water source to enter the suction cylinder 9 is arranged at the bottom of the suction cylinder 9;

one side of the rectangular containing block 1 is provided with a placing seat 24 which swings regularly, a plurality of groups of open beakers 26 which are distributed at equal intervals are arranged on the placing seat 24, a water outlet pipeline 10 in the sampling assembly rotates synchronously with the swinging column 3, the water outlet end of the water outlet pipeline 10 corresponds to the position of the open beakers 26, and the single swinging angle of the placing seat 24 is a sector included angle between two adjacent open beakers 26.

As shown in fig. 1, 2 and 4, when sampling and detecting water sources for animal husbandry, since the detection result of a single set of samples is single, and when detecting water sources for animal husbandry, the detection items are more, including PH value of water source, hardness, soluble solids and escherichia coli detection in microbiological detection, etc., multiple sets of samples are needed for water source during sampling and detection to meet the diversity of detection types and ensure accuracy of detection data.

When the water source is used for sampling in the animal husbandry, the piston plate 8 moves in the suction cylinder 9 to complete the sucking and releasing process of the water source, so that the water source flows out of the water outlet pipeline 10 through the suction cylinder 9, the sampled water source flows into the open beakers 26, when the water source is continuously sampled, a plurality of groups of open beakers 26 are placed on the placement seat 24 at equal intervals, during the continuous sampling process, the placement seat 24 rotates in the time interval of single sampling, and the single swinging angle is the sector included angle between two adjacent open beakers 26, therefore, the sample water source can fall into different open beakers 26 respectively during multiple sampling, the water source sample capacity of each sampling is consistent, and the multiple sampling process is carried out continuously without manually adjusting the positions of the open beakers 26 to connect the sampled water source.

One of them preferred embodiment has rotary drum 2 through circular groove body sliding connection in the rectangle accommodation piece 1, is equipped with the reciprocating pivoted crank assembly of drive rotary drum 2 in the casing, toward pendulum post 3 and rotary drum 2 coaxial and toward pendulum post 3 be in rotary drum 2 inside, toward pendulum post 3 on fixedly connected with spacing post 6, spacing post 6 is through seting up spacing groove 4 sliding contact rotary drum 2 on rotary drum 2, and spacing groove 4 shape is the reverse V-arrangement.

As shown in fig. 3 and 4, the drum 2 is driven by the crank assembly to swing in the horizontal direction, when the drum 2 rotates, since the limit post 6 provided on the swing post 3 is in sliding contact with the drum 2 through the limit slot 4, and the shape structure of the limit slot 4 is inverted V-shaped, when the drum 2 swings horizontally, the limit post 6 slides on the limit slot 4 under the limit action of the limit post 6, and moves in the vertical direction due to the influence of the shape characteristic of the limit slot 4, and therefore, when the drum 2 swings horizontally, the limit post 6 can move in the vertical direction.

Further, the rectangular accommodating block 1 is fixedly connected with a positioning column 7, the positioning column 7 is connected with the swing column 3 in a sliding manner through a positioning groove 5 formed in the swing column 3, the positioning groove 5 is U-shaped, and the positioning groove 5 comprises two groups of vertical sliding parts 51 and one group of horizontal sliding parts 52 which are integrally formed.

As shown in fig. 3, 4 and 8, when the limit post 6 is at the point D (as shown in fig. 8), the positioning post 7 is at the section B, that is, the section B of the horizontal sliding portion 52, and when the drum 2 rotates horizontally, the swing post 3 cannot move in the vertical direction under the limiting action of the positioning post 7, so that the swing post 3 follows the drum 2 and rotates synchronously.

Similarly, when the swing column 3 moves horizontally along with the rotary drum 2 until the positioning column 7 is located at the lowest position of the end a, the swing column 3 is not limited by the positioning column 7, so that the limiting column 6 moves at the end C in the limiting groove 4 and the positioning column 7 slides on the section a of the positioning groove 5, i.e. the vertical sliding portion 51, when the rotary drum 2 continues to rotate.

To sum up, when the positioning column 6 is at the point D, the positioning column 7 is at the point B (as shown in fig. 8), the swing column 3 moves synchronously along with the drum 2, and changes the direction of the water outlet pipe 10 synchronously, when the positioning column 7 moves to the point a, the positioning column 6 slides on the section C in the positioning slot 4, and at this time, the swing column 3 moves vertically, so that in the horizontal swing process of the drum 2, the movement mode of the swing column 3 is as follows: one set of vertically reciprocating motion-following the synchronous horizontal rotation of the drum 2-the other set of vertically reciprocating motion.

When the rotary drum 2 rotates in a swinging way, the piston plate 8 is driven by the swinging column 3 to do two vertical reciprocating motions, and then the sampling process of the water source can be realized twice, and it is worth to say that in the two sampling processes, only the water source in one sampling process can fall into the open beaker 26, wherein the water source in one sampling process falls into the water source again, the purpose of two sampling is achieved by disturbing the water source at the water inlet end of the water inlet pipeline 11, and the repeatability of the sample in the sampling process is avoided.

On the basis of the sampling assembly embodiment, the water absorbing assembly comprises a water inlet pipeline 11 fixedly penetrating through the bottom of the suction barrel 9, a water outlet pipeline 10 fixedly penetrating through the piston plate 8, the water outlet pipeline 10 penetrating through the swing post 3, one-way valves fixedly connected to the water inlet pipeline 11 and the water outlet pipeline 10, and the one-way valves limit water sources to enter the suction barrel 9 from the water inlet pipeline 11 and to be discharged out of the suction barrel 9 from the water outlet pipeline 10.

When the limit column 6 moves up and down in the vertical direction, the bottom of the limit column 6 is fixedly connected with the piston plate 8, so that the piston plate 8 and the piston plate are driven to move synchronously, when the piston plate 8 moves upwards in the suction cylinder 9, a detection water source enters the suction cylinder 9 through the water inlet pipeline 11, and when the piston plate 8 moves downwards in the suction cylinder 9, a sample water source in the suction cylinder 9 flows out through the water outlet pipeline 10 and falls into the open beaker 26 right below the water outlet pipeline 10.

In order to avoid solid sundries from blocking the water inlet pipeline 11, one water inlet end of the water inlet pipeline 11 is fixedly communicated with a water inlet nozzle 12, a filter screen is fixedly connected to the water inlet nozzle 12, and the filter screen is arranged on the water inlet nozzle 12 to intercept the solid sundries in a water source and avoid the solid sundries from blocking the water inlet pipeline 11.

On the basis of the embodiment of the water absorption assembly, the crank assembly comprises a rotating shaft 15 which is driven by a motor to freely rotate in a shell, a third gear 16 is fixedly connected with the rotating shaft 15, one end of a swing rod 17 is connected with the third gear 16 through a rotating pin shaft in a rotating mode, the other end of the swing rod 17 is fixedly connected to a second gear 14, a first gear 13 is meshed with the second gear 14, the first gear 13 is fixedly sleeved on the rotary drum 2, the second gear 14 is fixedly rotated on the shell in a shaft fixing mode, and a channel 27 is formed in the position, corresponding to the second gear 14, of the rectangular accommodating block 1.

As shown in fig. 1, 3 and 6, the motor drives the rotation shaft 15 and the third gear 16 disposed thereon to rotate horizontally in synchronization, and the horizontal cross-sectional dimension of the third gear 16 is smaller than that of the second gear 14, so that when the third gear 16 rotates horizontally, the second gear 14 is driven to rotate in a sector manner in the horizontal direction, and the second gear 14 engages with the first gear 13, so that the first gear 13 and the drum 2 disposed thereon are driven to rotate in a sector manner in synchronization.

On the basis of the crank assembly embodiment, a driving placement seat 24 is arranged on a rotating shaft 15 to directionally swing a swaying assembly, the swaying assembly comprises a cross rod 18 and an arc plate 20 which are fixedly connected to the rotating shaft 15, an adjusting column 19 is fixedly connected to the cross rod 18, a placement seat 24 is fixedly connected to the bottom of the placement seat 24, a positioning seat 21 is fixedly connected to a shell, a plurality of groups of giving-up through grooves 22 for sliding of the adjusting column 19 are formed in the positioning seat 21 at equal intervals, a plurality of groups of arc grooves 23 are formed in the edge of the positioning seat 21 at equal intervals, and the arc plate 20 is in sliding contact with the arc grooves 23.

As shown in fig. 1, 3 and 5, the rotation shaft 15 drives the cross rod 18 and the arc plate 20 to synchronously and horizontally rotate, the cross rod 18 drives the adjusting column 19 arranged on the cross rod 18 to synchronously and horizontally rotate with the cross rod, the cross rod 18 and the arc plate 20 are distributed in a staggered manner in the vertical direction, the adjusting column 19 gradually enters the yielding through groove 22 during horizontal rotation and drives the fixed swinging seat 21 to rotate until the adjusting column 19 is separated from the yielding through groove 22, the arc plate 20 contacts with the arc groove 23 during horizontal rotation, and further, the position of the fixed swinging seat 21 is ensured not to deviate, and the adjusting column 19 can enter the yielding through groove 22 during horizontal rotation.

The adjusting column 19 is driven to rotate through the rotating shaft 15, and then the fixed swinging seat 21 is driven to be consistent with the single rotating angle of the placing seat 24 on the fixed swinging seat, so that when sampling is carried out for multiple times, the open beaker 26 at different positions on the fixed swinging seat can face to one side of the swinging column 3, and then water source samples are added into multiple groups of open beakers 26.

Further, a plurality of groups of placing grooves 25 for placing open beakers 26 are formed in the placing seat 24 at equal intervals, the placing seat 24 is connected with the shell in a sliding mode through the grooves, and the number of the placing grooves 25 is consistent with that of the yielding grooves 22.

As shown in fig. 2 and 5, in order to ensure that the single horizontal rotation angle of the placement base 24 can enable the adjacent open beaker 26 to be located right below the water outlet pipeline 10, the number of the placement grooves 25 is identical to the number of the yielding through grooves 22 in the present invention, for example, when the number of the yielding through grooves 22 and the number of the placement grooves 25 are five, the number of the open beaker 26 is five, so that the single rotation angle of the placement base 24 is 360 °/5, and therefore, after the single rotation of the placement base 24, the adjacent open beaker 26 can be located right below the water outlet pipeline 10, and then the sampling process of the livestock water source is continuously completed.

The shell is made of plastic or metal and other materials with specific certain strength, the shell is used for protecting the swing rod 17, the plurality of groups of gears and other parts in the shell, the shell is provided with a groove body corresponding to the position of the placing seat 24, so that the movement process of the shell is not influenced, and the shell is provided with a through groove corresponding to the position of the water inlet pipeline 11, so that the water inlet pipeline 11 can extend into a livestock water source.

Working principle: the invention relates to a water source sampling and detecting device for animal husbandry, which is characterized in that when in use, the piston plate 8 is used for making piston movement in the suction cylinder 9 to complete the sucking and releasing process of a water source, so that the water source flows out of the water outlet pipeline 10 through the suction cylinder 9, and the sampled samples flow into the open beakers 26, when the water source is continuously sampled, a plurality of groups of open beakers 26 are equidistantly placed on the placement seat 24, and when in continuous sampling process, the placement seat 24 rotates in the time interval of single sampling, the single rotation angle is the sector included angle between two adjacent open beakers 26, therefore, the sample water source can respectively fall into different open beakers 26 during multiple sampling, the water source sample capacity of each sampling is consistent, the multiple sampling process is carried out without manually adjusting the position of the open beakers 26 to connect the sample water source.

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

Claims

1. The utility model provides a water source sampling detection device for animal husbandry, includes casing, its characterized in that: a rectangular accommodating block (1) is fixedly connected to the shell, and a suction cylinder (9) for extracting a water source is arranged in the rectangular accommodating block (1);

the sampling assembly swings in a semicircular track in the horizontal direction, and the sampling assembly comprises a swinging column (3) arranged in the rectangular accommodating block (1), and the swinging column (3) vertically reciprocates when in a semicircular track terminal.

2. The water source sampling and detecting device for animal husbandry according to claim 1, wherein: the swing column (3) is positioned above the suction cylinder body (9), the suction cylinder body (9) is fixedly connected to the shell, the piston plate (8) is fixedly connected to the bottom of the swing column (3), the outer circumferential surface of the piston plate (8) is in sliding contact with the suction cylinder body (9), and a water absorption component which enables a water source to enter the suction cylinder body (9) is arranged at the bottom of the suction cylinder body (9).

3. The water source sampling and detecting device for animal husbandry according to claim 2, wherein: one side of the rectangular accommodating block (1) is provided with a placing seat (24) which swings regularly, a plurality of groups of open beakers (26) which are distributed at equal intervals are arranged on the placing seat (24), a water outlet pipeline (10) in the sampling assembly synchronously rotates with the swing column (3), the water outlet end of the water outlet pipeline (10) corresponds to the position of the open beakers (26), and the single swinging angle of the placing seat (24) is a sector included angle between two adjacent open beakers (26);

the rectangular accommodating block (1) is internally connected with the rotary drum (2) through a circular groove body in a sliding manner, a crank assembly for driving the rotary drum (2) to rotate in a reciprocating manner is arranged in the shell, the swing column (3) is coaxial with the rotary drum (2) and is positioned in the rotary drum (2), the swing column (3) is fixedly connected with a limit column (6), the limit column (6) is in sliding contact with the rotary drum (2) through a limit groove (4) formed in the rotary drum (2), and the limit groove (4) is in an inverted V shape; the rectangular accommodating block (1) is fixedly connected with a positioning column (7), the positioning column (7) is connected with the swinging column (3) in a sliding manner through a positioning groove (5) formed in the swinging column (3), the positioning groove (5) is U-shaped, and the positioning groove (5) comprises two groups of vertical sliding parts (51) and one group of horizontal sliding parts (52) which are integrally formed;

the water absorption assembly comprises a water inlet pipeline (11) fixedly penetrating through the bottom of the suction cylinder (9), a water outlet pipeline (10) is fixedly penetrating through the piston plate (8), the water outlet pipeline (10) penetrates through the swing column (3), one-way valves are fixedly connected to the water inlet pipeline (11) and the water outlet pipeline (10), and the one-way valves limit a water source to enter the suction cylinder (9) from the water inlet pipeline (11) and discharge the suction cylinder (9) from the water outlet pipeline (10);

the crank assembly comprises a rotating shaft (15) which is driven by a motor to freely rotate in a shell, the rotating shaft (15) is fixedly connected with a third gear (16), the third gear (16) is rotationally connected with one end of a swinging rod (17) through a rotating pin shaft, the other end of the swinging rod (17) is fixedly connected to a second gear (14), the second gear (14) is meshed with a first gear (13), the first gear (13) is fixedly sleeved on the rotary drum (2), the second gear (14) is fixedly axially rotated on the shell, and a channel groove (27) is formed in the position of the rectangular accommodating block (1) corresponding to the second gear (14);

the rotary shaft (15) is provided with a swaying component for driving the placing seat (24) to directionally swing, the swaying component comprises a cross rod (18) and an arc-shaped plate (20) which are fixedly connected to the rotary shaft (15), an adjusting column (19) is fixedly connected to the cross rod (18), and a fixed swaying seat (21) is fixedly connected to the bottom of the placing seat (24).

4. A water source sampling and testing device for animal husbandry according to claim 3, wherein: one water inlet end of the water inlet pipeline (11) is fixedly communicated with a water inlet nozzle (12), and a filter screen is fixedly connected to the water inlet nozzle (12).

5. The water source sampling and detecting device for animal husbandry according to claim 4, wherein: the fixed swinging seat (21) rotates on the shell in a fixed shaft way, and a plurality of groups of yielding through grooves (22) for sliding of the adjusting column (19) are formed in the fixed swinging seat (21) at equal intervals.

6. The water source sampling and detecting device for animal husbandry according to claim 2, wherein: a plurality of groups of arc grooves (23) are formed in the edge of the fixed swing seat (21) at equal intervals, and the arc plates (20) are in sliding contact with the arc grooves (23).

7. The water source sampling and detecting device for animal husbandry according to claim 6, wherein: a plurality of groups of placing grooves (25) for placing open beakers (26) are formed in the placing seat (24) at equal intervals.

8. The water source sampling and detecting device for animal husbandry according to claim 7, wherein: the placing seats (24) are in sliding connection with the shell through the through grooves, and the number of the placing grooves (25) is consistent with the number of the yielding through grooves (22).