Reagent mixing formula kit
Technical Field
The invention relates to a kit, in particular to a reagent mixing type kit.
Background
For example, patent No. CN201620137560.6, which belongs to the chemiluminescence measuring field. The utility model provides a kit includes bracket, magnetic bead cup, calibration liquid bottle, reagent bottle and spacer block, be equipped with magnetic bead cup hole, calibration liquid bottle hole and reagent bottle hole on the bracket in proper order, magnetic bead cup hole be used for placing the magnetic bead cup, calibration liquid bottle hole be used for placing the calibration liquid bottle, reagent bottle hole be used for placing the reagent bottle. The utility model has simple structure, can utilize the limited space of the reagent tray to the maximum extent and reach the requirement of multi-flux measurement; the utility model discloses a shortcoming can not be applicable to the teaching aid, can not carry out the mixing with the reagent in the reagent box and handle.
Disclosure of Invention
The invention aims to provide a reagent blending type kit which can be suitable for teaching aids, can blend reagents in the kit, can regulate the time for blending the reagents and the rotation speed for blending the reagents, and is suitable for students who are in contact with the reagents for the first time and dangerous reagents.
The purpose of the invention is realized by the following technical scheme:
a reagent mixing type kit comprises an integral support, a power mechanism, a transmission mechanism I, a timing mechanism, a pushing mechanism I, a pushing mechanism II, a connecting rod I, a connecting rod II, a speed change mechanism, a control mechanism, a transmission mechanism II, a phase change mechanism and a mixing mechanism, wherein the power mechanism I is fixedly connected to the integral support, the transmission mechanism I is rotatably connected to the integral support, the power mechanism and the transmission mechanism I are connected through belt transmission, the upper end of the timing mechanism is connected to the transmission mechanism I through transmission threads, the lower end of the timing mechanism is slidably connected to the integral support, the pushing mechanism I is slidably connected to the integral support, the lower end of the pushing mechanism I is rotatably connected to the power mechanism, the pushing mechanism II is slidably connected to the integral support, the lower end of the pushing mechanism II is hinged to the connecting rod I, the lower end of the connecting rod I is slidably connected to the integral support, the, the lower extreme of connecting rod II articulates on connecting rod I, speed change mechanism rotates and connects on the monolith support, control mechanism's rear end joint is on the monolith support, control mechanism's front end sliding connection is on the monolith support, control mechanism's middle-end rotates and connects on speed change mechanism, speed change mechanism and drive mechanism I are connected through the belt drive, drive mechanism II rotates and connects on the monolith support, speed change mechanism and drive mechanism II pass through the gear engagement transmission, phase change mechanism rotates and connects on the monolith support, drive mechanism II and phase change mechanism pass through the belt drive and connect, mixing mechanism rotates and connects on the monolith support, phase change mechanism and mixing mechanism pass through the gear engagement transmission.
As a further optimization of the technical scheme, the reagent mixing type kit comprises an integral support, a bottom plate, two side plates, two linear bearing holes I, two linear bearing holes II, a sliding lower plate, an intermediate plate and a top plate, wherein a vertical sliding groove is formed in the bottom plate, a transverse sliding groove is formed in the sliding lower plate, the intermediate plate comprises an intermediate plate body, two intermediate plate small plates, a clamping body and an intermediate plate sliding groove, the lower ends of the two intermediate plate small plates are respectively welded to the front side and the rear side of the intermediate plate body, the clamping body is welded to the intermediate plate small plate on the rear side, the intermediate plate sliding groove is transversely formed in the intermediate plate small plate on the front side, the two side plates are arranged, the linear bearing holes I and the linear bearing holes II are respectively formed in the two side plates, the left end and the right end of the bottom plate are respectively fixedly connected to the lower ends of the two side plates, the left end and the right end of the sliding lower, the left end and the right end of the middle plate are respectively and fixedly connected with the middle ends of the two side plates, and the left end and the right end of the top plate are respectively and fixedly connected with the upper ends of the two side plates.
As a further optimization of the technical scheme, the reagent blending type kit comprises a power mechanism, a motor, a power shaft, power side teeth, a power belt pulley, power sliding side teeth and a power connecting key, wherein the left end of the power shaft is rotatably connected to the right end of an output shaft of the motor, the power side teeth are fixedly connected to the right end of the output shaft of the motor, the power belt pulley is fixedly connected to the right end of the power shaft, the power sliding side teeth are circumferentially connected to the power shaft through the power connecting key, and the motor is fixedly connected to a bottom plate.
As the technical scheme is further optimized, the reagent mixing type kit comprises a transmission mechanism I and two transmission belt wheels I, wherein the two transmission belt wheels I are fixedly connected to two ends of the screw rod respectively, two ends of the screw rod are rotatably connected to two bottom plates respectively, and the transmission belt wheel I on the right side is in transmission connection with a power belt wheel through a belt.
As further optimization of the technical scheme, the reagent blending type kit comprises a timing mechanism and a timing handle, wherein the timing mechanism comprises a timing support body, a timing sliding body, a timing clamping body, a timing transmission threaded hole, a rectangular groove and a circular through hole, the upper end of the timing sliding body is fixedly connected to the lower end of the timing support body, the timing clamping body is fixedly connected to the rear end of the timing support body, the timing transmission threaded hole is formed in the upper end of the timing support body, the rectangular groove and the circular through hole are formed in the lower end of the timing support body, the rectangular groove is communicated with the circular through hole, the timing handle comprises a timing handle body, a triangular body I and a compression spring I, the triangular body I is slidably connected to the rear end of the handle body, the compression spring I is sleeved on the triangular body I and is located between the handle body and the triangular body I, the front end and the rear end of the handle body are slidably connected in the rectangular groove, the left end and the right end of the handle body are connected in the circular through hole in a sliding mode, the timing sliding body is connected in the transverse sliding groove in a sliding mode, and the timing support body is connected to the screw rod through the timing transmission threaded hole;
the pushing mechanism I comprises a pushing body I, a rotating screw rod I and a compression spring II, a transmission threaded hole I is formed in the upper end of the pushing body I, the rotating screw rod I is connected to the pushing body I through a transmission thread, the compression spring II is sleeved at the upper end of the pushing body I, the lower end of the pushing body I is rotatably connected to a power sliding side tooth, the middle end of the pushing body I is slidably connected into a transverse sliding groove, the pushing body I is slidably connected into a linear bearing hole II, and the compression spring II is located between a side plate on the right side and the pushing body I; the rotating screw rod I and the handle body are positioned at the same horizontal position;
pushing mechanism II is including promoting body II, rotating lead screw II and compression spring III, and the upper end that promotes body II is provided with transmission screw hole II, rotates lead screw II and passes through transmission threaded connection on promoting body II, and III suits of compression spring are on promoting body II, promote II sliding connection of body in sharp bearing hole I, and compression spring III is located left curb plate and promotes between the body II, and the middle-end sliding connection who promotes body II is in horizontal sliding tray, and it is in same horizontal position with the handle body to rotate lead screw II.
As a further optimization of the technical scheme, the reagent mixing type kit comprises a connecting rod I, wherein the upper end of the connecting rod I is hinged to the lower end of a pushing body II, the lower end of the connecting rod I is connected in a sliding mode in a vertical sliding groove, the lower end of the connecting rod I inclines rightwards, the upper end of the connecting rod II is hinged to the lower end of the pushing body I, the lower end of the connecting rod II is hinged to the lower end of the connecting rod I, and the lower end of the connecting rod II inclines leftwards.
As a further optimization of the technical scheme, the reagent mixing type kit comprises a speed change mechanism, a speed change belt pulley, a speed change gear wheel, a speed change pinion, speed change side teeth and a speed change connecting key, wherein the number of teeth of the speed change gear wheel is more than that of the speed change pinion, the speed change belt pulley is fixedly connected to the left end of the speed change shaft, the speed change gear wheel is fixedly connected to the middle end of the speed change shaft, the speed change pinion is fixedly connected to the middle end of the speed change shaft, the speed change side teeth are circumferentially connected to the speed change shaft through the speed change connecting key, the speed change side teeth are located between the speed change gear wheel and the speed change pinion, two ends of the speed change shaft are respectively and rotatably connected to two side plates, and the.
As further optimization of the technical scheme, the reagent mixing type kit comprises a control mechanism, a triangular body II and a compression spring IV, wherein the triangular body II is connected to the rear end of the control body in a sliding mode, the compression spring IV is sleeved on the triangular body II, the compression spring IV is located between the control body and the triangular body II, the middle end of the control body is connected to a speed change side tooth in a rotating mode, the front end of the control body is connected to a middle plate sliding groove in a sliding mode, and the triangular body II is clamped on a clamping body in a clamping mode.
As further optimization of the technical scheme, the reagent blending type kit comprises a transmission mechanism II, a transmission belt pulley II, a transmission large gear and a transmission small gear, wherein the number of teeth of the transmission large gear is more than that of the transmission small gear, the number of teeth of the transmission small gear is the same as that of the transmission large gear, the transmission belt pulley II is fixedly connected to the right end of the transmission shaft II, the transmission small gear is fixedly connected to the middle end of the transmission shaft II, the transmission large gear is fixedly connected to the transmission shaft II, the transmission small gear is meshed with the transmission large gear, the transmission large gear is meshed with the transmission small gear, and two ends of the transmission shaft II are respectively and rotatably connected.
As further optimization of the technical scheme, the reagent blending type kit comprises a phase change mechanism, a phase change belt wheel and a phase change bevel gear, wherein the phase change belt wheel is fixedly connected to the right end of the phase change shaft;
the mixing mechanism comprises a mixing shaft, a mixing supporting plate, mixing bevel gears and mixing boxes, the mixing boxes are arranged in a plurality of numbers, the mixing boxes are in circular shape and are fixedly connected to the mixing supporting plate, the mixing supporting plate and the mixing bevel gears are fixedly connected to the upper end and the lower end of the mixing shaft respectively, the mixing shaft is rotatably connected to a top plate, and the mixing bevel gears are meshed with the phase-changing bevel gears.
The reagent mixing type kit has the beneficial effects that:
the reagent mixing type kit provided by the invention can be suitable for teaching aids, can be used for uniformly mixing reagents in the kit, can be used for regulating the time for uniformly mixing the reagents and the rotating speed for uniformly mixing the reagents, and is suitable for mixing students who are in contact with the reagents for the first time and dangerous reagents.
Drawings
The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.
FIG. 1 is a schematic diagram of the overall structure of the reagent mixing type kit of the present invention;
FIG. 2 is a schematic diagram of a transmission structure of the reagent mixing type kit according to the present invention;
FIG. 3 is a schematic view of the overall stent structure of the present invention;
FIG. 4 is a schematic view of the base plate structure of the present invention;
FIG. 5 is a schematic view of the sliding lower plate structure of the present invention;
FIG. 6 is a schematic illustration of the construction of the intermediate plate of the present invention;
FIG. 7 is a schematic diagram of a power mechanism according to the present invention;
FIG. 8 is a schematic structural diagram of a transmission mechanism I of the invention;
FIG. 9 is a schematic view of the timing mechanism of the present invention;
FIG. 10 is a schematic view of the timing support structure of the present invention;
FIG. 11 is a schematic view of the timing handle structure of the present invention;
FIG. 12 is a schematic cross-sectional view of the timing handle of the present invention;
FIG. 13 is a schematic view of the structure of a pushing mechanism I of the present invention;
FIG. 14 is a schematic structural view of a pushing mechanism II of the present invention;
FIG. 15 is a schematic structural view of the shifting mechanism of the present invention;
FIG. 16 is a schematic view of the control mechanism of the present invention;
FIG. 17 is a schematic cross-sectional view of the control mechanism of the present invention;
FIG. 18 is a schematic structural diagram of a transmission mechanism II of the present invention;
FIG. 19 is a schematic view of the phase change mechanism of the present invention;
FIG. 20 is a schematic view of the mixing mechanism of the present invention.
In the figure: an integral support 1; a bottom plate 1-1; a vertical sliding groove 1-1-1; side plates 1-2; 1-3 linear bearing holes; linear bearing holes II 1-4; 1-5 of a sliding lower plate; a transverse sliding groove 1-5-1; intermediate plates 1-6; a middle plate body 1-6-1; 1-6-2 of middle plate small plate; 1-6-3 of a clamping body; 1-6-4 of a middle plate sliding groove; a top plate 1-7; a power mechanism 2; a motor 2-1; a power shaft 2-2; 2-3 of power side teeth; 2-4 of a power belt wheel; 2-5 of power sliding side teeth; power connecting keys 2-6; a transmission mechanism I3; 3-1 of a screw rod; a transmission belt wheel I3-2; a timing mechanism 4; a timing support 4-1; a timing support body 4-1-1; a timing sliding body 4-1-2; a timing clamping body 4-1-3; timing transmission threaded holes 4-1-4; 4-1-5 rectangular grooves; 4-1-6 of a circular through hole; a timing handle 4-2; a timing handle body 4-2-1; a triangular body I4-2-2; 4-2-3 of a compression spring; a pushing mechanism I5; a pushing body I5-1; rotating the screw rod I5-2; 5-3 of a compression spring; a pushing mechanism II 6; a pusher II 6-1; rotating the screw rod II 6-2; 6-3 of a compression spring; a connecting rod I7; a connecting rod II 8; a speed change mechanism 9; a speed change shaft 9-1; a variable speed pulley 9-2; a speed change gearwheel 9-3; shift pinions 9-4; the speed change side teeth 9-5; a variable speed connection key 9-6; a control mechanism 10; a control body 10-1; 10-2 of a triangular body II; 10-3 of a compression spring; a transmission mechanism II 11; a transmission shaft II 11-1; a transmission belt wheel II 11-2; a transmission gearwheel 11-3; a drive pinion 11-4; a phase change mechanism 12; phase change shaft 12-1; a phase change belt wheel 12-2; 12-3 of phase-change bevel gear; a blending mechanism 13; blending shaft 13-1; uniformly mixing the supporting plates 13-2; uniformly mixing the conical teeth 13-3; and 13-4, a blending box.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings.
The first embodiment is as follows:
the embodiment is described below with reference to fig. 1 to 20, and a reagent mixing type reagent kit includes a whole support 1, a power mechanism 2, a transmission mechanism i 3, a timing mechanism 4, a pushing mechanism i 5, a pushing mechanism ii 6, a connecting rod i 7, a connecting rod ii 8, a speed change mechanism 9, a control mechanism 10, a transmission mechanism ii 11, a phase change mechanism 12 and a mixing mechanism 13, wherein the power mechanism 2 is fixedly connected to the whole support 1, the transmission mechanism i 3 is rotatably connected to the whole support 1, the power mechanism 2 and the transmission mechanism i 3 are connected through belt transmission, the upper end of the timing mechanism 4 is connected to the transmission mechanism i 3 through transmission threads, the lower end of the timing mechanism 4 is slidably connected to the whole support 1, the pushing mechanism i 5 is slidably connected to the whole support 1, the lower end of the pushing mechanism i 5 is rotatably connected to the power mechanism 2, the pushing mechanism ii 6 is slidably connected to the whole support 1, the lower end of a pushing mechanism II 6 is hinged on a connecting rod I7, the lower end of the connecting rod I7 is connected on an integral support 1 in a sliding mode, the upper end of a connecting rod II 8 is hinged on a pushing mechanism I5, the lower end of the connecting rod II 8 is hinged on the connecting rod I7, a speed change mechanism 9 is connected on the integral support 1 in a rotating mode, the rear end of a control mechanism 10 is connected on the integral support 1 in a clamping mode, the front end of the control mechanism 10 is connected on the integral support 1 in a sliding mode, the middle end of the control mechanism 10 is connected on the speed change mechanism 9 in a rotating mode, the speed change mechanism 9 is connected with a transmission mechanism I3 in a belt transmission mode, a transmission mechanism II 11 is connected on the integral support 1 in a rotating mode, the speed change mechanism 9 and the transmission mechanism II 11 are in gear meshing transmission mode, a phase change mechanism 12 is connected on the integral support 1, the phase change mechanism 12 and the blending mechanism 13 are in meshing transmission through gears; when the reagent mixing machine is used, the power mechanism 2 is started, the power mechanism 2 drives the transmission mechanism I3 to rotate, the transmission mechanism I3 pushes the timing mechanism 4 to move in the transmission mechanism I3 through the transmission screw threads, when the timing mechanism 4 moves to the limit positions on the left side and the right side, the pushing mechanism II 6 and the pushing mechanism I5 are respectively pushed to move, when the pushing mechanism I5 moves rightwards, the pushing mechanism I5 cuts off the power in the power mechanism 2, when the timing mechanism 4 pushes the pushing mechanism II 6 to move leftwards, the pushing mechanism II 6 drives the connecting rod I7 and the connecting rod II 8 to move to push the pushing mechanism I5 to move rightwards to cut off the power in the power mechanism 2, the transmission mechanism I3 drives the speed change mechanism 9 to rotate, the speed change mechanism 9 adjusts the mixing speed of the driven phase change mechanism 12 through the control mechanism 10, the phase change mechanism 12 drives the mechanism 13 to process reagents, the timing mechanism 4 can time the mixing time, and the speed change mechanism 9 can change the rotating speed during mixing, so that the reagent mixing machine is suitable for mixing students who are in contact with the reagent for the first time and dangerous reagents.
The second embodiment is as follows:
the embodiment is described below with reference to fig. 1-20, and the embodiment further describes the first embodiment, where the integral support 1 includes a bottom plate 1-1, side plates 1-2, linear bearing holes i 1-3, linear bearing holes ii 1-4, sliding lower plates 1-5, intermediate plates 1-6 and top plates 1-7, a vertical sliding groove 1-1-1 is formed on the bottom plate 1-1, a horizontal sliding groove 1-5-1 is formed on the sliding lower plates 1-5, the intermediate plates 1-6 include intermediate plate bodies 1-6-1, intermediate plate small plates 1-6-2, clamping bodies 1-6-3 and intermediate plate sliding grooves 1-6-4, two intermediate plate small plates 1-6-2 are provided, and the lower ends of the two intermediate plate small plates 1-6-2 are respectively welded to the intermediate plate bodies 1-6-1, the clamping bodies 1-6-3 are welded on the middle plate small plate 1-6-2 at the rear side, the middle plate sliding grooves 1-6-4 are transversely arranged on the middle plate small plate 1-6-2 at the front side, two side plates 1-2 are arranged, the linear bearing holes I1-3 and the linear bearing holes II 1-4 are respectively arranged on the two side plates 1-2, the left and right ends of the bottom plate 1-1 are respectively and fixedly connected with the lower ends of the two side plates 1-2, the left and right ends of the sliding lower plate 1-5 are respectively and fixedly connected with the side plates 1-2, the left and right ends of the middle plate 1-6 are respectively and fixedly connected with the middle ends of the side plates 1-2, and the left and right ends of the top plate 1-7 are respectively and fixedly connected with the upper ends of the side plates 1-2.
The third concrete implementation mode:
the embodiment is described below with reference to fig. 1-20, and the embodiment further describes the second embodiment, where the power mechanism 2 includes a motor 2-1, a power shaft 2-2, power side teeth 2-3, a power pulley 2-4, power sliding side teeth 2-5, and a power connecting key 2-6, the left end of the power shaft 2-2 is rotatably connected to the right end of the output shaft of the motor 2-1, the power side teeth 2-3 are fixedly connected to the right end of the output shaft of the motor 2-1, the power pulley 2-4 is fixedly connected to the right end of the power shaft 2-2, the power sliding side teeth 2-5 are circumferentially connected to the power shaft 2-2 through the power connecting key 2-6, and the motor 2-1 is fixedly connected to the bottom plate 1-1; when the motor 2-1 starts to rotate, the output shaft of the motor 2-1 drives the power side teeth 2-3 to rotate, the output shaft of the motor 2-1 cannot drive the power shaft 2-2 to rotate, and when the power sliding side teeth 2-5 are meshed with the power side teeth 2-3 through pushing of the pushing mechanism I5 and the compression spring II 5-3 and the compression spring III 6-3 on the pushing mechanism II 6, the output shaft of the motor 2-1 drives the power shaft 2-2 to rotate.
The fourth concrete implementation mode:
the third embodiment is further described with reference to fig. 1-20, the transmission mechanism i 3 includes a screw rod 3-1 and two transmission pulleys i 3-2, the two transmission pulleys i 3-2 are provided, the two transmission pulleys i 3-2 are respectively and fixedly connected to two ends of the screw rod 3-1, two ends of the screw rod 3-1 are respectively and rotatably connected to two bottom plates 1-1, and the transmission pulley i 3-2 on the right side and the power pulley 2-4 are connected through belt transmission; the power belt wheel 2-4 drives the transmission belt wheel I3-2 on the right side to rotate, and the transmission belt wheel I3-2 on the right side drives the screw rod 3-1 to rotate.
The fifth concrete implementation mode:
the fourth embodiment is further described with reference to fig. 1-20, wherein the timing mechanism 4 comprises a timing support 4-1 and a timing handle 4-2, the timing support 4-1 comprises a timing support body 4-1-1, a timing sliding body 4-1-2, a timing clamping body 4-1-3, a timing transmission threaded hole 4-1-4, a rectangular groove 4-1-5 and a circular through hole 4-1-6, the upper end of the timing sliding body 4-1-2 is fixedly connected to the lower end of the timing support body 4-1-1, the timing clamping body 4-1-3 is fixedly connected to the rear end of the timing support body 4-1-1, the timing transmission threaded hole 4-1-4 is arranged at the upper end of the timing support body 4-1-1, the rectangular groove 4-1-5 and the circular through hole 4-1-6 are arranged at the lower end of the timing support body 4-1-1, the rectangular groove 4-1-5 is communicated with the circular through hole 4-1-6, the timing handle 4-2 comprises a timing handle body 4-2-1, a triangular body I4-2-2 and a compression spring I4-2-3, the triangular body I4-2-2 is connected to the rear end of the handle body 4-2-1 in a sliding manner, the compression spring I4-2-3 is sleeved on the triangular body I4-2-2, the compression spring I4-2-3 is positioned between the handle body 4-2-1 and the triangular body I4-2-2, the front end and the rear end of the handle body 4-2-1 are connected in the rectangular groove 4-1-5 in a sliding manner, the left end and the right end of the handle body 4-2-1 are connected in the circular through hole 4-1-6 in a sliding manner, the timing sliding body 4-1-2 is connected in the transverse sliding groove 1-5-1 in a sliding manner, and the timing support body 4-1-1 is connected on the screw rod 3-1 through the timing transmission threaded hole 4-1-4; the screw rod 3-1 pushes the timing support body 4-1-1 to slide in the transverse sliding groove 1-5-1 through the transmission screw thread, when the timing support body 4-1-1 moves to a left limit position and a right limit position, the timing handle 4-2 can push the pushing mechanism I5 and the pushing mechanism II 6 to move so as to cut off the power in the power mechanism 2, when the power of the power mechanism 2 is started next time, the timing handle 4-2 is pushed to slide in the timing support 4-1 to change the clamping position of the triangular body I4-2-2, the timing handle 4-2 does not squeeze the pushing mechanism I5 or the pushing mechanism II 6, and the power in the power mechanism 2 is switched on;
the pushing mechanism I5 comprises a pushing body I5-1, a rotating screw rod I5-2 and a compression spring II 5-3, a transmission threaded hole I is formed in the upper end of the pushing body I5-1, the rotating screw rod I5-2 is connected to the pushing body I5-1 through a transmission thread, the compression spring II 5-3 is sleeved on the upper end of the pushing body I5-1, the lower end of the pushing body I5-1 is rotatably connected to a power sliding side tooth 2-5, the middle end of the pushing body I5-1 is slidably connected into a transverse sliding groove 1-5-1, the pushing body I5-1 is slidably connected into a linear bearing hole II 1-4, and the compression spring II 5-3 is located between a side plate 1-2 on the right side and the pushing body I5-1; the rotary screw rod I5-2 and the handle body 4-2-1 are positioned at the same horizontal position; when the pushing handle 4-2 moves to the right limit position, the compression spring II 5-3 is extruded to enable the pushing body I5-1 to move rightwards so as to cut off the power in the power mechanism 2 to play a timing role;
the pushing mechanism II 6 comprises a pushing body II 6-1, a rotating screw rod II 6-2 and a compression spring III 6-3, a transmission threaded hole II is formed in the upper end of the pushing body II 6-1, the rotating screw rod II 6-2 is connected to the pushing body II 6-1 through a transmission thread, the compression spring III 6-3 is sleeved on the pushing body II 6-1, the pushing body II 6-1 is connected into a linear bearing hole I1-3 in a sliding mode, the compression spring III enables the rotating screw rod II 6-2 to be located between a side plate 1-2 on the left side and the pushing body II 6-1, the middle end of the pushing body II 6-1 is connected into a transverse sliding groove 1-5-1 in a sliding mode, and the rotating screw rod II 6-2 and the handle body 4-2-1 are located at the same horizontal; when the pushing handle 4-2 moves to the left limit position, the pushing body II 6-1 is extruded by the compression spring III 6-3 to move leftwards to drive the connecting rod I7 and the connecting rod II 8 to move to push the pushing mechanism I5 to move rightwards so as to cut off the power in the power mechanism 2 to play a timing role, and when the timing time is to be changed, the rotating screw rod II 6-2 or the rotating screw rod I5-2 is rotated to change the limit position of the left-right movement of the timing support 4-1.
The sixth specific implementation mode:
the embodiment is described below with reference to fig. 1-20, and the fifth embodiment is further described, wherein the upper end of the connecting rod i 7 is hinged to the lower end of the pushing body ii 6-1, the lower end of the connecting rod i 7 is slidably connected in the vertical sliding groove 1-1-1, the lower end of the connecting rod i 7 is inclined to the right, the upper end of the connecting rod ii 8 is hinged to the lower end of the pushing body i 5-1, the lower end of the connecting rod ii 8 is hinged to the lower end of the connecting rod i 7, and the lower end of the connecting rod ii 8 is inclined to the left.
The seventh embodiment:
referring to fig. 1-20, the present embodiment will be further described, wherein the shifting mechanism 9 includes a shifting shaft 9-1, a shifting pulley 9-2, a shifting gearwheel 9-3, a shifting pinion 9-4, shifting side teeth 9-5 and a shifting connecting key 9-6, the number of teeth of the shifting gearwheel 9-3 is greater than that of the shifting pinion 9-4, the shifting pulley 9-2 is fixedly connected to the left end of the shifting shaft 9-1, the shifting gearwheel 9-3 is fixedly connected to the middle end of the shifting shaft 9-1, the shifting pinion 9-4 is fixedly connected to the middle end of the shifting shaft 9-1, the shifting side teeth 9-5 are circumferentially connected to the shifting shaft 9-1 through the shifting connecting key 9-6, the shifting side teeth 9-5 are located between the shifting gearwheel 9-3 and the shifting pinion 9-4, two ends of a speed change shaft 9-1 are respectively and rotatably connected to the two side plates 1-2, the speed change belt wheel 9-2 is in belt transmission connection with a transmission belt wheel I3-2 on the left side, the transmission belt wheel I3-2 drives the speed change belt wheel 9-2 to rotate, and the speed change belt wheel 9-2 drives the speed change shaft 9-1 to rotate.
The specific implementation mode is eight:
the present embodiment is described below with reference to fig. 1-20, and the seventh embodiment is further described in the present embodiment, where the control mechanism 10 includes a control body 10-1, a triangular body ii 10-2 and a compression spring iv 10-3, the triangular body ii 10-2 is slidably connected to the rear end of the control body 10-1, the compression spring iv 10-3 is sleeved on the triangular body ii 10-2, the compression spring iv 10-3 is located between the control body 10-1 and the triangular body ii 10-2, the middle end of the control body 10-1 is rotatably connected to the speed-changing side teeth 9-5, the front end of the control body 10-1 is slidably connected to the middle plate sliding groove 1-6-4, and the triangular body ii 10-2 is connected to the clamping body 1-6-3; when the control body 10-1 is positioned at the left side, the speed change big gear 9-3 is meshed with the transmission small gear 11-4, when the control body 10-1 is positioned at the right side, the transmission big gear 11-3 is meshed with the speed change small gear 9-4, the number of teeth of the transmission big gear 11-3 is more than that of the transmission small gear 11-4, the number of teeth of the transmission small gear 11-4 is the same as that of the speed change big gear 9-3, and the number of teeth of the speed change big gear 9-3 is more than that of the speed change small gear 9-4.
The specific implementation method nine:
the present embodiment is described below with reference to fig. 1 to 20, and the present embodiment further describes an eighth embodiment, where the transmission mechanism ii 11 includes a transmission shaft ii 11-1, a transmission belt pulley ii 11-2, a transmission large gear 11-3 and a transmission small gear 11-4, the number of teeth of the transmission large gear 11-3 is greater than the number of teeth of the transmission small gear 11-4, the number of teeth of the transmission small gear 11-4 is the same as that of the transmission large gear 9-3, the transmission belt pulley ii 11-2 is fixedly connected to the right end of the transmission shaft ii 11-1, the transmission small gear 11-4 is fixedly connected to the middle end of the transmission shaft ii 11-1, the transmission large gear 11-3 is fixedly connected to the transmission shaft ii 11-1, the transmission small gear 11-4 is engaged with the transmission large gear 9-3, and the transmission, two ends of the transmission shaft II 11-1 are respectively and rotatably connected to the two side plates 1-2, and the speed of the transmission shaft II 11-1 is higher than the rotating speed of the transmission gear wheel 11-3 and the speed change gear wheel 9-4 when the transmission gear wheel 11-4 and the speed change gear wheel 9-3 are meshed.
The detailed implementation mode is ten:
the present embodiment is described below with reference to fig. 1 to 20, and the present embodiment further describes an embodiment nine, where the phase change mechanism 12 includes a phase change shaft 12-1, a phase change pulley 12-2, and a phase change bevel gear 12-3, the phase change pulley 12-2 is fixedly connected to a right end of the phase change shaft 12-1, the phase change bevel gear 12-3 is fixedly connected to a middle end of the phase change shaft 12-1, two ends of the phase change shaft 12-1 are respectively rotatably connected to two side plates 1-2, and the phase change pulley 12-2 and the transmission pulley ii 11-2 are connected by a belt transmission; the transmission belt wheel II 11-2 drives the phase change belt wheel 12-2 to rotate, the phase change belt wheel 12-2 drives the phase change shaft 12-1 to rotate, and the phase change shaft 12-1 drives the phase change bevel gear 12-3 to rotate.
The blending mechanism 13 comprises a blending shaft 13-1 and a blending supporting plate 13-2, the reagent mixing device comprises a mixing bevel gear 13-3 and a mixing box 13-4, wherein the mixing box 13-4 is provided with a plurality of mixing boxes 13-4, the mixing boxes 13-4 are uniformly and fixedly connected to a mixing supporting plate 13-2 in a circular shape, the mixing supporting plate 13-2 and the mixing bevel gear 13-3 are respectively and fixedly connected to the upper end and the lower end of a mixing shaft 13-1, the mixing shaft 13-1 is rotatably connected to a top plate 1-7, the mixing bevel gear 13-3 is meshed with a phase-change bevel gear 12-3, the phase-change bevel gear 12-3 drives the mixing bevel gear 13-3 to rotate, the mixing bevel gear 13-3 drives the mixing supporting plate 13-2 to rotate, the mixing supporting plate 13-2 drives the mixing box 13-4 to rotate, and the mixing box 13-4 rotates to.
The invention relates to a reagent mixing type kit, which has the working principle that:
when the motor 2-1 starts to rotate, the output shaft of the motor 2-1 drives the power side teeth 2-3 to rotate, the output shaft of the motor 2-1 cannot drive the power shaft 2-2 to rotate, and when the power sliding side teeth 2-5 are meshed with the power side teeth 2-3 through pushing of the pushing mechanism I5 and a compression spring II 5-3 and a compression spring III 6-3 on the pushing mechanism II 6, the output shaft of the motor 2-1 drives the power shaft 2-2 to rotate; the power belt wheel 2-4 drives the right transmission belt wheel I3-2 to rotate, and the right transmission belt wheel I3-2 drives the screw rod 3-1 to rotate; the screw rod 3-1 pushes the timing support body 4-1-1 to slide in the transverse sliding groove 1-5-1 through the transmission screw thread, when the timing support body 4-1-1 moves to a left limit position and a right limit position, the timing handle 4-2 can push the pushing mechanism I5 and the pushing mechanism II 6 to move so as to cut off the power in the power mechanism 2, when the power of the power mechanism 2 is started next time, the timing handle 4-2 is pushed to slide in the timing support 4-1 to change the clamping position of the triangular body I4-2-2, the timing handle 4-2 does not squeeze the pushing mechanism I5 or the pushing mechanism II 6, and the power in the power mechanism 2 is switched on; the rotary screw rod I5-2 and the handle body 4-2-1 are positioned at the same horizontal position; when the pushing handle 4-2 moves to the right limit position, the compression spring II 5-3 is extruded to ensure that the pushing body I5-1 moves to cut off the power in the power mechanism 2 to play a timing role; when the pushing handle 4-2 moves to the left limit position, the pushing body II 6-1 is extruded by the compression spring III 6-3 to move leftwards to drive the connecting rod I7 and the connecting rod II 8 to move to push the pushing mechanism I5 to move rightwards so as to cut off the power in the power mechanism 2 to play a timing role, and when the timing time is required to be changed, the rotating screw rod II 6-2 or the rotating screw rod I5-2 enables the limit position of the timing support 4-1 to move leftwards and rightwards to change; when the control body 10-1 is positioned at the left side, the speed change big gear 9-3 is meshed with the transmission small gear 11-4, when the control body 10-1 is positioned at the right side, the transmission big gear 11-3 is meshed with the speed change small gear 9-4, the number of teeth of the transmission big gear 11-3 is more than that of the transmission small gear 11-4, the number of teeth of the transmission small gear 11-4 is the same as that of the speed change big gear 9-3, and the number of teeth of the speed change big gear 9-3 is more than that of the speed change small gear 9-4; the transmission belt wheel II 11-2 drives the phase-change belt wheel 12-2 to rotate, the phase-change belt wheel 12-2 drives the phase-change shaft 12-1 to rotate, the phase-change shaft 12-1 drives the phase-change bevel gear 12-3 to rotate, the phase-change bevel gear 12-3 drives the blending bevel gear 13-3 to rotate, the blending bevel gear 13-3 drives the blending supporting plate 13-2 to rotate, the blending supporting plate 13-2 drives the blending box 13-4 to rotate, and the blending box 13-4 rotates to blend the reagents.
It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.