NL2034387B1 - A detection device for the prevention and control of African swine fever - Google Patents

Abstract

The present invention discloses an detection device for the prevention and control of African swine fever, comprising a storage box, a top part of the storage box is provided 5 with a top cover, an inner wall of the storage box is fixedly connected with a place plate, and the place plate is provided with a plurality of place tanks, each of the place tanks is placed with an African swine fever sample test tube , each of the place tanks is provided with a rotating mechanism, each of the place tanks is provided with a disinfection mechanism, and each of the place tanks is provided with a drying 10 mechanism. In the present invention, the outer wall of the upper port of the test tube is uniformly sterilized and dried through the rotation of the test tubes and the up and down movement of the annular block, so as to avoid the bacteria being attached to the port on the test tube and affecting the subsequent detection, and ensure the accuracy of the detection.

Description

A detection device for the prevention and control of African swine fever

Technical Field

The present invention relates to the field of African swine fever prevention and control detection, more specifically, to a detection device for the prevention and control of

African swine fever.

Background

In the prior art, the patent application number CN202123175861.8 discloses a detection device for the prevention and control of African swine fever, wherein a good buffering role is played when the incubator is transported and moved, the specimens placed inside the incubator can be effectively protected, strong protection is done with good use effect. By setting the adjustment component, when the specimens placed on the place plate are taken out, the motor is started to drive the gear to rotate forward and reverse, and then the rack plate moves up and down, in the meanwhile, the telescopic rod moves telescopically, thereby moving the place plate up and down, so that the specimens on the place plate can be moved to the top of the incubator to take out the sample.

In the above-mentioned patent, the samples in the test tube can be stored in the incubator, but the incubator will breed bacteria during long-term use, and the bacteria will adhere to the outer wall of the upper port of the test tubes during the placement process and storage of the test tubes; when the samples are taken out, impurities such as bacteria on the outer wall of the upper port will contaminate the samples and affect the accuracy of subsequent detection; therefore, the present invention designs a detection device for the prevention and control of African swine fever to solve the above problems.

Summary of the invention

The purpose of the present invention is to solve the shortcomings in the prior art, and proposes a detection device for the prevention and control of African swine fever by which the outer walls of the upper ports of the test tubes can be uniformly sterilized and dried through the rotation of the test tubes and the up and down movement of the annular block, so as to avoid the attachment of bacteria to the ports of the test tubes and affect the subsequent detection, and ensure the accuracy of the detection.

In order to achieve above object, the present invention adopts the following technical solutions:

A detection device for the prevention and control of African swine fever, comprising a storage box, a top part of the storage box is provided with a top cover, an inner wall of the storage box is fixedly connected with a place plate, and the place plate is provided with a plurality of place tanks, each of the place tanks is placed with an African swine fever sample test tube, each of the place tanks is provided with a rotating mechanism, each of the rotating mechanisms comprising a mounting cavity provided in the place plate, each of the mounting cavities is provided with a motor, an output end of each of the motors is fixedly connected with a worm shaft, each of the worm shafts is meshed with a worm gear, each of the worm gears is penetrated and provided with a rotating rod which is fixedly connected therewith, each of the rotating rods is rotationally connected with the place plate, top parts of the rotating rods are fixedly connected with

U-shaped test tube seats, outer walls of the worm shafts are fixedly provided with two drive bevel gears, each of the drive bevel gears is meshed with a driven bevel gear, each of the driven bevel gears is fixedly connected with a reciprocating screw, each of the reciprocating screws is fixedly connected with a fixed block, each of the fixed blocks is fixedly connected with the place plate, each of the fixed blocks is sleeved with a lift block, an annular block is fixedly connected with the two lifting blocks, each of the place tanks is provided with a disinfection mechanism, and each of the place tanks is provided with a drying mechanism.

Preferably, the disinfection mechanism comprises a piston cavity provided in the place plate, an inner wall of the piston cavity is connected with a piston, the piston is rotatably connected with a deflection rod, a port is provided between the piston cavity and the place tank, the deflection rod penetrates through the port, and the deflection rod is rotatably connected with a rotating plate, the rotating plate is fixedly connected with the reciprocating screw on a right side thereof, a disinfectant solution cavity is set between the storage box and the place plate, a water inlet pipe penetrates through the place plate and is fixedly connected thereto, the water inlet pipe extends into the disinfectant solution cavity, and the water inlet pipe communicates with the piston cavity.

Preferably, the drying mechanism comprises a heating cavity provided in the place plate, at least one electric heating wire is installed in the heating cavity, and a plurality of air inlet holes are penetrated on the place plate, an inner wall of each of the plurality of the air inlet holes is fixedly connected with a dust-proof net , and each of the inner walls of the plurality of air inlet holes is fixedly connected with a first one-way valve, the place plate is penetrated with an air inlet pipe fixedly connected thereto, and two ends of the air inlet pipe communicate with the piston cavity and the heating cavity respectively, an outer wall of the water inlet pipe and an outer wall of the air inlet pipe are provided with a second one-way valve and an electromagnetic valve respectively, the place plate is penetrated with a connection pipe fixedly connected thereto, an outer wall of the connection pipe is fixedly connected with a third one-way valve, the connection pipe is fixedly connected with the annular block, the annular block is provided with a plurality of conveying holes, and a plurality of conveying holes are all communicated with a cavity.

Preferably, the storage box is bolted to the top cover, an outer wall of the storage box and an inner wall of the top cover are respectively provided with matching external threads and internal threads, a U-shaped handle is fixedly connected to a top part of the top cover, and a rubber protective layer is provided on an outer wall of the

U-shaped handle.

Preferably, the African swine fever sample test tubes are placed on the U-shaped test tube seats, and the U-shaped test tube seats are provided with a plurality of first drainage holes.

Preferably, a plurality of second drainage holes penetrate through the place plate, two ends of each of the second drainage holes is separately communicated with the place tank and the disinfectant solution cavity.

Preferably, an inner wall of the annular block is provided with a plurality of soft brushes, and the soft brushes are provided against the outer walls of the African swine fever sample test tubes, and the African swine fever sample test tubes are provided through the annular block.

Preferably, a cross section of the piston is rectangular, and the piston is sealed with an inner wall of the piston cavity.

Preferably, the connection pipe comprises a flexible hose, and two ends of the connection pipe communicate with the piston cavity and the cavity respectively.

Compared with the prior art, the present invention has the beneficial effects of: 1. An output end of the motor drives the worm shaft, the worm gear, the rotating rod, the U-shaped test tube seat and the African swine fever sample test tubes to rotate slowly, rotation of the worm shaft drives the two driving bevel gears, the driven bevel gears and the reciprocating screws to rotate synchronously, the lift block and the annular block move up and down, the outer walls at the port positions of the African swine fever sample test tubes can be sterilized, the disinfectant evenly disinfects the outer walls of the African swine fever sample test tubes by the soft brushes. 2. The heated air can be injected into the piston cavity through the air inlet pipe via the reciprocal left and right movement of the piston in the piston cavity, the heated air is injected into the annular block through the connection pipe, and finally ejected through the conveying hole, the rotating African swine fever sample test tubes are heated, the

African swine fever sample test tube is heated evenly, and the drying effect is good. 3. By disinfecting and drying the port positions of the African swine fever sample test tubes the bacterial impurities at the port positions of the African swine fever sample test tubes can be prevented from contaminating the sample during the subsequent detection of the African swine fever samples, thereby ensuring the accuracy of the detection.

To sum up, in the present invention, the outer walls of the upper ports of the test tubes are uniformly sterilized and dried through the rotation of the test tubes and the up and down movement of the annular block, so as to avoid the bacteria attached to the ports on the test tubes and affect the subsequent detection, and ensure the accuracy of the 5 detection.

Description of drawings

Figure 1 is a sectional view of the present invention;

Figure 2 is an enlarged view of the structure at A in figure 1;

Figure 3 is an enlarged view of the structure at B in figure 2;

Figure 4 is an enlarged view of the structure at C in figure 3;

Fig. 5 is a top view of the present invention when the top cover is removed.

In the figures: 1. storage box; 2. top cover; 3. place plate; 4. place tank; 5. African swine fever sample test tube; 6. motor; 7. Worm shaft; 8, worm gear; 9. rotating rod; 10.

U-shaped test tube seat; 11. first drainage hole; 12. drive bevel gear; 13. driven bevel gear; 14. reciprocating screw; 15. fixed block; 16. lift block; 17. annular block; 18. second drainage hole; 19. disinfectant solution cavity ; 20. piston cavity; 21. piston; 22. deflection rod; 23. rotating plate; 24. water inlet pipe; 25. air inlet pipe; 26. heating cavity; 27. electric heating wire; 28. air inlet hole; 29. dust-proof net; 30. first one-way valve; 31. second one-way valve; 32. electromagnetic valve; 33. connection pipe; 34. third one-way valve; 35. conveying hole.

Embodiments

Please refer to figures 1-5, a detection device for the prevention and control of African swine fever, comprising a storage box 1, a top part of the storage box 1 is provided with a top cover 2, a U-shaped handle is fixedly connected to a top part of the top cover 2, and a rubber protective layer is provided on an outer wall of the U-shaped handle, so that the device can be carried.

An inner wall of the storage box 1 is fixedly connected with a place plate 3, and the place plate 3 is provided with a plurality of place tanks 4, each of the place tanks 4 is placed with an African swine fever sample test tube 5, each of the place tanks 4 is provided with a rotating mechanism, each of the rotating mechanisms comprising a mounting cavity provided in the place plate 3, each of the mounting cavities is provided with a motor 6, an output end of each of the motors 6 is fixedly connected with a worm shaft 7, each of the worm shafts 7 is meshed with a worm gear 8, each of the worm gears 8 is penetrated and provided with a rotating rod 9 which is fixedly connected therewith, each of the rotating rods 9 is rotationally connected with the place plate 3, top parts of the rotating rods 9 are fixedly connected with U-shaped test tube seata 10, the U-shaped test tube seats 10 are provided with a plurality of first drainage holes 11, with which the disinfectant can be discharged, the African swine fever sample test tubes 5 are placed on the U-shaped test tube seats 10, the rotation of the U-shaped test tube seats 10 and the African swine fever sample test tubes 5 can have the test tubes evenly sterilized and dried.

Outer walls of the worm shafts 7 are fixedly provided with two drive bevel gears 12 respectively, each of the drive bevel gears 12 is meshed with a driven bevel gear 13, each of the driven bevel gears 13 is fixedly connected with a reciprocating screw 14, each of the reciprocating screws 14 is fixedly connected with a fixed block 15, each of the fixed blocks 15 is fixedly connected with the place plate 3, each of the two fixed blocks 15 is sleeved with a lift block 16, an annular block 17 is fixedly connected with the two lifting blocks 16 respectively; inner walls of the annular blocks 17 is provided with a plurality of soft brushes, and the soft brushes are provided against the outer walls of the African swine fever sample test tubes 5, and the African swine fever sample test tubes 5 penetrate through the annular blocks 17; the range of disinfection and drying of the African swine fever sample test tubes 5 can be expanded by moving the annular blocks 17 up and down, and the bacterial impurities at the upper ports of the African swine fever sample test tubes 5 can be removed to ensure the accuracy of subsequent detection.

Each of the place tanks 4 is provided with a disinfection mechanism, the disinfection mechanism comprises a piston cavity 20 provided in the place plate 3, an inner wall of the piston cavity 20 is sealed and connected with a piston 21, a cross section of the piston 21 is arranged in a rectangular shape, so that the piston 21 can only move left and right; the piston 21 is rotatably connected with a deflection rod 22, a port is provided between the piston cavity 20 and the place tank 4, the deflection rod 22 is provided in the port, and the deflection rod 22 is rotatably connected with a rotating plate 23, the rotating plate 23 is fixedly connected with the reciprocating screw 14 on a right side thereof, a disinfectant solution cavity 19 is set between the storage box 1 and the place plate 3, a plurality of second drainage holes 18 penetrate through the place plate 3, two ends of each of the second drainage holes 18 is separately communicated with the place tank 4 and the disinfectant solution cavity 19; a water inlet pipe 24 penetrates through the place plate 3 and is fixedly connected thereto, the water inlet pipe 24 extends into the disinfectant solution cavity 19, and the water inlet pipe 24 communicates with the piston cavity 20; disinfectant in the disinfectant cavities 19 can be sprayed on outer walls of the African swine fever sample test tubes 5 by a reciprocating movement of the piston 21, and the disinfectant can be recovered through the second drainage hole 18 to avoid waste of the disinfectant, and the disinfectant is regularly replaced (the storage box 1 is provided with a feeding port for replenishing the disinfectant and a discharge port for discharging the disinfectant, not shown) to ensure the effect of disinfection.

Each of the place tanks 4 is provided with a drying mechanism, the drying mechanism comprises a heating cavity 26 provided in the place plate 3, an electric heating wire 27 is installed in the heating cavity 26, the electric heating wire 27 energizes and generates heat to heat the air, and a plurality of air inlet holes 28 are penetrated on the place plate 3, an inner wall of each of a plurality of the air inlet holes 28 is fixedly connected with an dust-proof net 29 to remove dust in the air, each of the inner walls of a plurality of air inlet holes 28 is fixedly connected with a first one-way valve 30 to prevent the heated air in the heating cavity 26 from being discharged through the air intake holes 28, the place plate 3 is penetrated with an air inlet pipe 25 fixedly connected thereto, and two ends of the air inlet pipe 25 communicate with the piston cavity 20 and the heating cavity 26 respectively, an outer wall of the water inlet pipe 24 and an outer wall of the air inlet pipe 25 are all provided with a second one-way valve 31 and an electromagnetic valve 32, the second one-way valve 31 can prevent the medium in the piston cavity 20 from flowing back into the disinfectant solution cavity 19 or the heating cavity 26, the place plate 3 is penetrated with a connection pipe 33 fixedly connected thereto, the connection pipe 33 is a flexible hose, the connection pipe 33 communicates with the piston cavity 20, an outer wall of the connection pipe 33 is fixedly connected with a third one-way valve 34, the third one-way valve 34 can prevent the medium in the air inlet pipe 25 from flowing back into the piston cavity 20, the connection pipe 33 is fixedly connected with the annular block 17, the annular block 17 is provided with a cavity, the connection pipe 33 communicates with the cavity, the annular block 17 is provided with a plurality of conveying holes 35, and the plurality of conveying holes 35 are all communicated with the cavity, disinfectant is sprayed through the conveying hole 35 for disinfection, and hot air is sprayed out through the conveying hole 35 for drying.

In the present invention, one or more test tubes can be placed in for keeping, sterilization and drying, hereinafter the test tubes are provided to be more than one, specifically, operations of the device is as following: first detach the top cover 2, and place the African swine fever sample test tubes 5 containing the African swine fever samples in the place tanks 4, the African swine fever sample test tubes 5 are inserted into the U-shaped test tube seats 10, and the African swine fever sample test tubes 5 are fitted against the U-shaped test tube seats 10, at this time, the motors 6 are started, and output ends of the motors 6 drive the worm shafts 7, the worm gears 8, the rotating rods 9, the U-shaped test tube seats 10 and the African swine fever sample test tubes 5 to rotate, and through the cooperation of the worm gears 8 and the worm shafts 7, the African swine fever sample test tubes 5 can be slowly rotated to ensure the stability of the African swine fever sample test tubes 5 when rotating and avoid sample overflow.

The rotation of the worm shafts 7 drives the two driving bevel gears 12, the driven bevel gears 13, and the reciprocating screws 14 to rotate synchronously, so that the lift blocks 16 and the annular blocks 17 move up and down. Now open the electromagnetic valves 32 on the water inlet pipes 24 and close the electromagnetic valves 32 on the air inlet pipes 25, and the reciprocating screw rods 14 on the right side rotate to drive the rotating plates 23 to rotate, so that the deflection rods 22 are deflected to drive the pistons 21 reciprocates left and right in the piston cavities 20, when the pistons 21 move to the left, the space on the right sides of the pistons 21 becomes larger to form negative pressure, and the disinfectant in the disinfectant cavities 19 are injected into the piston cavities 20 through the water inlet pipes 24, when the pistons 21 move to the right, the disinfectant in the piston cavities 20 can be injected into the connection pipes 33 and the annular blocks 17, and finally sprayed out through the conveying holes 35, and through the continuous reciprocating movement of the pistons 21, the disinfectant can be continuously sprayed, by the rotation of the

African swine fever sample test tubes 5 and the up and down movement of the annular blocks 17, the outer walls at the port positions of the African swine fever sample test tubes 5 can be sterilized, the disinfectant evenly disinfects the outer walls of the

African swine fever sample test tubes 5 by the set soft brushes.

After disinfection is finished, close the electromagnetic valves 32 on the water inlet pipes 24 and open the electromagnetic valves 32 on the air inlet pipes 25, and energize electric heating wires 27, the electric heating wires 27 can heat the air in the heating cavities 26, and the heated air can be injected into the piston cavities 20 through the air inlet pipes 25 via the reciprocating left and right movement of the pistons 21 in the piston cavities 20, the heated air is injected into the annular blocks 17 through the connection pipes 33, and finally ejected through the conveying holes 35, the rotating African swine fever sample test tubes 5 are heated, the African swine fever sample test tubes 5 are heated evenly, the drying effect is good, by disinfecting and drying the port positions of the African swine fever sample test tubes 5 the bacterial impurities at the African swine fever sample test tube 5 can be prevented from contaminating the samples during the subsequent detection of the African swine fever samples, thereby ensuring the accuracy of the detect

Claims (9)

S11 - Conclusions 1. Detection device for the prevention and control of African swine fever, comprising a storage bin (1), an upper part of the storage bin (1) having a top cover (2), an inner wall of the storage bin (1) with a placement plate (3) is fixedly connected, and the placement plate (3) is provided with a plurality of placement reservoirs (4), each of the placement reservoirs (4) being provided with a sampling tube for African swine fever (5), each of the placement reservoirs (4) is provided with a rotation mechanism, each of the placement reservoirs (4) is provided with a disinfection mechanism, and each of the placement reservoirs (4) is provided with a drying reservoir; each of the rotation mechanisms comprising a mounting cavity provided in the locating plate (3), each of the mounting cavities being provided with a motor (6), an output end of each of the motors (6) being rigidly connected to a worm shaft, each of the worm shafts (7) is interlocked with a worm gear (8), each of the worm gears (8) being pierced through and provided with a rotating rod (9) fixedly connected thereto, each of the rotating rods (9) ) is rotatably connected to the positioning plate (3), an upper part of the rotating rod (9) is firmly connected to a U-shaped test tube location (10), the outer walls of the worm shafts (7) are permanently provided with two driven bevel gears (12), each of the two driven bevel gears (12) being meshed with a driven bevel gear (13), each of the two driven bevel gears (13) being rigidly connected to a reciprocating screw (14) 1s, each of the two reciprocating screws (14) is firmly connected to a fixed block (15), each of the two fixed blocks (15) is firmly connected to the positioning plate (3), each of the two fixed blocks (15) is surrounded by a lifting block (16) 1s , wherein an annular block (17) is rigidly connected to the two lifting blocks (16). A detection device for the prevention and control of African swine fever according to claim 1, wherein the disinfection mechanism comprises at least one piston cavity (20) provided in the locating plate (3), an inner wall of each of the at least one piston cavity ( 20) is connected to at least one piston (21), each of the at least one piston (21) being rotatably connected to a deflection rod (22), a port between each of the at least one piston cavity (20) and the placement reservoir (4) provided 1s, wherein the at least one deflection bar (22) is adjusted by the gate, and the at least one deflection bar (22) is rotatably connected to at least one rotating plate (23), wherein the at least one rotating plate (23) is connected to the reciprocating screws (14) on a right side thereof is firmly connected, at least one cavity with disinfectant solution (19) is set between the storage container (1) and the placing plate (3), at least one water inlet pipe (24) through the placing plate ( 3) penetrates and is firmly connected thereto, wherein the at least one water inlet pipe (24) extends into the at least one cavity with disinfectant solution (19), and the at least one water inlet pipe (24) extends with the at least one piston cavity (20 ) communicates. A detection device for the prevention and control of African swine fever according to claim 2, wherein the drying mechanism comprises at least one heating cavity (26) provided in the locating plate (3), at least one electric heating wire (27) in the at least one heating cavity (26) is installed, and a plurality of air inlet openings (28) on the locating plate (3) are penetrated, an inner wall of each of the plurality of air inlet openings (28) being fixedly connected with at least one dust-proof net (29) , and each of the inner walls of the plurality of air inlet openings (28) is firmly connected to at least one first one-way valve (3), the locating plate (3) is penetrated by at least one air inlet pipe (25) and is firmly connected thereto, and ends of the at least one air inlet pipe (25) communicate with the at least one piston cavity (20) and the at least one heating cavity (26), respectively, wherein an outer wall of the at least one water inlet pipe (24) and an outer wall of the at least one air inlet pipe (25) is each provided with at least one second one-way valve (31) and at least one solenoid valve (32), the mounting plate (3) is penetrated by at least one connecting pipe (33) and is firmly connected thereto, wherein an outer wall of the at least one connecting line (33) is firmly connected to at least one third one-way valve (34), the at least one connecting line (33) is firmly connected to the at least one annular block (17), the at least at least one annular block (17) is provided with a plurality of transport holes (35), and the plurality of transport holes (35) all communicate with at least one cavity. A detection device for the prevention and control of African swine fever according to claim 1, wherein the storage bin (1) is screwed to the top cover (2), an outer wall of the storage bin (1) and an inner wall of the top cover (2 ) are respectively provided with equal external threads and internal threads, a U-shaped handle is fixedly connected to an upper part of the top cover (2), and a rubber protective layer is provided on an outer wall of the U-shaped handle. A detection device for the prevention and control of African swine fever according to claim 1, wherein the at least one African swine fever sampling tube (5) is placed on the at least one U-shaped test tube location (10), and the at least one U -shaped test tube location (10) is provided with a plurality of first drainage holes (11). A detection device for the prevention and control of African swine fever according to claim 1, wherein a plurality of second drainage holes (18) penetrate through the locating plate (3), two ends of the second drainage holes (18) separately with the at least one locating reservoir (4) and the at least one cavity communicate with disinfectant solution (19). A detection device for the prevention and control of African swine fever according to claim 1, wherein an inner wall of the at least one annular block (17) is provided with a plurality of soft brushes, and the soft brushes rest against the outer wall of the at least one African swine fever sampling tube (5) are provided, and the at least one African swine fever sampling tube (5) penetrates the at least one annular block (17). A detection device for the prevention and control of African swine fever according to claim 2, wherein a cross-section of the at least one piston (21) is rectangular, and the at least one piston (21) is sealed in connection with an inner wall of the at least one piston cavity (20). 9. Detection device for the prevention and control of African swine fever according to claim 3, wherein the at least one connecting line (33) comprises a flexible hose, and ends of the at least one connecting line (33) respectively with the at least one piston cavity ( 20) and the at least one cavity communicate.