CN113208907A - Half-molding pre-embedded production device and production method for sandwiched moxa cone - Google Patents

Abstract

The invention relates to the field of moxibustion, in particular to a half-molding pre-embedded production device and a half-molding pre-embedded production method for sandwiched moxa cones. The technical problem to be solved by the invention is as follows: provides a half-molding pre-buried production device and a production method of a sandwiched moxa cone. The technical scheme is as follows: a half-forming pre-buried production device for sandwich moxa cones comprises an underframe, a first supporting plate, a bearing and rotating mechanism, a control screen, a dust-free decompression half-forming mechanism and a scraping mechanism; the underframe is fixedly connected with the first supporting plate; the underframe is connected with the rotation bearing mechanism; the rotation bearing mechanism is fixedly connected with the control screen; the bearing mechanism is connected with the dust-free type pressure reduction semi-forming mechanism. The invention realizes the molding and filling of spices and medicines to the moxa cone, and can be produced in batch; the moxa powder, the spice and the medicine can not fly in disorder during integral extrusion forming, and the equipment is not easy to have the problem of dust accumulation and hungry.

Description

Half-molding pre-embedded production device and production method for sandwiched moxa cone

Technical Field

The invention relates to the field of moxibustion, in particular to a half-molding pre-embedded production device and a half-molding pre-embedded production method for sandwiched moxa cones.

Background

The moxa cone, a relatively short moxa stick, is a variety produced by moxibustion instruments such as portable moxibustion instruments, joint moxibustion instruments, single-column double-column moxibustion instruments and dragon pots. Typically 15mm in diameter and 25mm in length. Warming channels, dredging collaterals, invigorating qi, dispelling pathogenic wind, promoting blood circulation, relieving pain, improving local circulation, and enhancing immunity. Warming channel, dispelling cold, expelling pathogenic wind, promoting qi circulation, activating collateral flow, promoting blood circulation, relieving pain, invigorating yang, and tonifying deficiency.

The existing moxa cone is generally a monotonous moxa cone during production, and the smell and the effect of the moxa cone are single during use; in order to increase more smell and efficacy based on the use of the moxa cone, spices and medicaments are added into the core of the moxa cone; however, the existing moxa cone forming device is simple in function and only can meet basic forming of the moxa cone, the moxa powder is placed in the bottom die and is directly pressed by the upper die for extrusion forming, due to the requirement of extrusion force, air pressure is generated due to the stress of stamping during forming, and a large amount of moxa powder flies upward; meanwhile, when the hollow column is pressed, the bottom of the hollow column is prone to cracking, and the hollow column is prone to scattering.

In summary, a half-molding pre-embedded production device for sandwiched moxa cones and a production method thereof are needed to solve the problems.

Disclosure of Invention

In order to overcome the defect that the existing moxa cone is generally a monotonous moxa cone during production, the smell and the effect of the moxa cone are single during use; in order to increase more smell and efficacy based on the use of the moxa cone, spices and medicaments are added into the core of the moxa cone; however, the existing moxa cone forming device is simple in function and only can meet basic forming of the moxa cone, the moxa powder is placed in the bottom die and is directly pressed by the upper die for extrusion forming, due to the requirement of extrusion force, air pressure is generated due to the stress of stamping during forming, and a large amount of moxa powder flies upward; when the suppression of hollow post is being carried out simultaneously, often the bottom can produce the problem that bursts apart, leads to the scattered shortcoming of hollow post, and the technical problem that solve is: provides a half-molding pre-buried production device and a production method of a sandwiched moxa cone.

The technical scheme is as follows: a half-forming pre-buried production device for sandwich moxa cones comprises an underframe, a first supporting plate, a bearing and rotating mechanism, a control screen, a dust-free decompression half-forming mechanism and a scraping mechanism; the underframe is fixedly connected with the first supporting plate; the underframe is connected with the rotation bearing mechanism; the rotation bearing mechanism is fixedly connected with the control screen; the bearing mechanism is connected with the dust-free type pressure reduction semi-forming mechanism; the bearing mechanism is connected with the strickling mechanism; the dust-free type pressure reduction semi-forming mechanism is connected with the strickling mechanism.

Further, the rotation bearing mechanism comprises a first outer frame, a first spray head, a first electric slide rail, a second support plate, a third electric slide rail, a fourth electric slide rail, a U-shaped connecting frame, a limiting cylinder, a combined plate, a first electric push rod, a second electric push rod, a third support plate, a pressing plate and a second spray head; the first outer frame is inserted with a plurality of groups of first nozzles at equal intervals; the first outer frame is inserted with a plurality of groups of second nozzles at equal intervals; one side of the inside of the first outer frame is fixedly connected with the first electric slide rail; the other side of the interior of the first outer frame is fixedly connected with a second electric slide rail; the first outer frame is fixedly connected with the underframe; the first outer frame is connected with a dust-free type pressure reduction semi-forming mechanism; the first outer frame is connected with the strickle mechanism; the first electric slide rail and the second electric slide rail are fixedly connected with the second support plate through slide blocks; the inner part of the second supporting plate is fixedly connected with a plurality of limiting cylinders; one side of the bottom of the second supporting plate is fixedly connected with a third electric slide rail; the other side of the bottom of the second supporting plate is fixedly connected with a fourth electric sliding rail; the third electric slide rail and the fourth electric slide rail are fixedly connected with the U-shaped connecting frame through the slide block; the bottoms of the limiting cylinders are inserted into the combination plates; the bottoms of the plurality of combined plates are fixedly connected with the U-shaped connecting frame; the first outer frame is fixedly connected with the first electric push rod; the first outer frame is fixedly connected with the second electric push rod; the bottoms of the first electric push rod and the second electric push rod are fixedly connected with the third supporting plate at the same time; the bottom of the third supporting plate is fixedly connected with a plurality of groups of pressing plates.

Further explaining, the dust-free type pressure reduction semi-forming mechanism comprises a fourth supporting plate, a third electric push rod, a fourth electric push rod, a first bevel gear, a first transmission rod, a first connecting rod, a second connecting rod, a third connecting rod, a coupling block, a net frame plate, a salient point tamping rod, a fifth electric push rod, a sixth electric push rod and a fifth supporting plate; one side above the fourth supporting plate is fixedly connected with a third electric push rod; the other side of the upper part of the fourth supporting plate is fixedly connected with a fourth electric push rod; the fourth supporting plate is rotationally connected with the first transmission rod; the upper parts of the third electric push rod and the fourth electric push rod are fixedly connected with the first outer frame at the same time; one side of the first transmission rod is fixedly connected with the first bevel gear; the first bevel gear is selectively meshed with the fourth bevel gear; the other side of the first transmission rod is fixedly connected with the first connecting rod; the first connecting rod is simultaneously in rotating connection with the second connecting rod and the third connecting rod through a rotating shaft; the second connecting rod is rotatably connected with the connecting shaft block through a rotating shaft; the bottom of the coupling block is fixedly connected with the salient point tamping rod; the outer surface of the salient point tamping rod is contacted with the net frame plate; one side below the fourth supporting plate is fixedly connected with a fifth electric push rod; the other side of the lower part of the fourth supporting plate is fixedly connected with a sixth electric push rod; the lower parts of the fifth electric push rod and the sixth electric push rod are fixedly connected with the fifth supporting plate at the same time; the fifth supporting plate is fixedly connected with the net frame plate.

Further explaining, the strickle mechanism comprises a motor, a second bevel gear, a third bevel gear, a second transmission rod, a support frame, a first gear, a first transmission wheel, a second transmission wheel, a fourth bevel gear, a sixth support plate, a seventh electric push rod, an eighth electric push rod, a second gear, a third transmission wheel, a fourth transmission wheel and a scraper; the output shaft of the motor is fixedly connected with the second bevel gear; the bottom of the motor is fixedly connected with the first outer frame; the second bevel gear is meshed with the third bevel gear; the axle center of the third bevel gear is fixedly connected with the second transmission rod; the outer surface of the second transmission rod is fixedly connected with the first gear and the first transmission wheel simultaneously; the outer surface of the second transmission rod is rotationally connected with the first outer frame; the outer surface of the second transmission rod is rotatably connected with the support frame; the support frame is fixedly connected with the first outer frame; the outer ring surface of the first driving wheel is in transmission connection with the second driving wheel through a belt; the axle center of the second driving wheel is rotationally connected with the supporting frame through a rotating shaft; the axle center of the second driving wheel is fixedly connected with a fourth bevel gear through a rotating shaft; when the fourth bevel gear is meshed with the first bevel gear, the first bevel gear rotates, otherwise, the fourth bevel gear does not rotate; a second gear is arranged on the side surface of the first gear; when the first gear is meshed with the second gear, the second gear rotates, otherwise, the second gear does not rotate; the second gear hub is rotationally connected with the sixth supporting plate through a rotating shaft; the axle center of the second gear is fixedly connected with the third transmission wheel through a rotating shaft; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the axle center of the fourth transmission wheel is rotationally connected with the sixth supporting plate through a rotating shaft; the axle center of the fourth driving wheel is fixedly connected with the scraper through a rotating shaft; one side above the sixth supporting plate is fixedly connected with a seventh electric push rod; the other side of the upper part of the sixth supporting plate is fixedly connected with an eighth electric push rod; the upper parts of the seventh electric push rod and the eighth electric push rod are fixedly connected with the first outer frame at the same time.

Further, the fourth driving wheels and the scrapers are provided with multiple groups, and the multiple groups of the fourth driving wheels are mutually driven.

Further, the first transmission rod, the first connecting rod, the second connecting rod, the third connecting rod, the coupling block, the net frame plate and the salient point tamping rod are provided with a plurality of groups, and each group of the first transmission rod and the third connecting rod except the two sides are mutually connected.

Further, the bottom of the convex point tamping rod is provided with a bellied bulge.

A half-molding pre-buried production method of a sandwich moxa cone comprises the following working steps:

s1: semi-molding, namely injecting the folium artemisiae argyi powder into a limiting cylinder at one side of a rotation bearing mechanism, and then extruding the injected folium artemisiae argyi powder by a scraping mechanism and a dust-free decompression semi-molding mechanism in linkage to form the folium artemisiae argyi powder into a concave-shaped section;

s2: filling spices and medicines, moving the semi-formed moxa cone to the other side of the rotation bearing mechanism by the rotation bearing mechanism, and filling the spices and the medicines into the semi-formed moxa cone;

s3: basically molding, moving the semi-molded moxa cone filled with the spices and the medicines by a bearing mechanism, and extruding the filled spices and the medicines by a scraping mechanism and a dust-free decompression semi-molding mechanism in linkage; substantially shaping it;

s4: completely molding, repeating the first step in S1, and filling a small gap in the middle of the top of the basically molded moxa cone with folium Artemisiae Argyi powder; then the molded moxa cone is moved to the position of the scraping mechanism through the bearing mechanism to scrape the moxa cone on the upper surface; then moving to the extrusion area of the rotation bearing mechanism to extrude the top surface of the moxa cone;

s5: collecting, namely uniformly collecting the moxa cones.

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

firstly, when the moxa cone extruding machine is used, the bottom frame is placed on the horizontal ground, then is externally connected with a power supply and is connected with a powder feeding pipeline, and meanwhile, a conveyor belt is placed in the moxa cone extruding area to be matched with the transfer of moxa cones; then the control screen control device operates, the moxa powder is injected into the limiting cylinder at one side of the bearing mechanism during operation, then the injected moxa powder is extruded by the scraping mechanism and the dust-free pressure reduction semi-forming mechanism linked with the scraping mechanism, and the first support plate is matched with the bottom of the limiting cylinder for bearing and supporting during extrusion, so that the moxa powder is formed into a concave-shaped section; then the bearing mechanism moves the semi-formed moxa cone to the other side of the bearing mechanism to fill spices and medicines into the semi-formed moxa cone; then moving the semi-formed moxa cone filled with the spices and the medicines through a bearing mechanism, and extruding the filled spices and the medicines through a scraping mechanism and a dust-free decompression semi-forming mechanism in linkage; substantially shaping it; after the basic molding, the moxa column is moved to the moxa powder filling position again through the rotation bearing mechanism, and a small gap in the middle of the top of the basically molded moxa column is filled with the moxa powder; then the molded moxa cone is moved to the position of the scraping mechanism through the bearing mechanism to scrape the moxa cone on the upper surface; then moving to the extrusion area of the rotation bearing mechanism to extrude the top surface of the moxa cone; uniformly collecting moxa cones after extrusion forming;

secondly, the invention realizes the molding and filling of the spice and the medicine to the moxa cone and can realize batch production; the moxa powder, the spice and the medicine can not fly in disorder during integral extrusion forming, and the equipment is not easy to have the problem of dust accumulation and hungry.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic perspective view of a second embodiment of the present invention;

FIG. 3 is a third perspective view of the present invention;

FIG. 4 is a schematic perspective view of a first embodiment of the rotation bearing mechanism of the present invention;

FIG. 5 is a schematic perspective view of a second embodiment of the rotation bearing mechanism of the present invention;

FIG. 6 is a schematic perspective view of a third embodiment of the rotation bearing mechanism of the present invention;

FIG. 7 is a schematic perspective view of a dust-free type pressure-reducing semi-forming mechanism according to the present invention;

FIG. 8 is a schematic view of a first partial body structure of a dust-free type decompression semi-molding mechanism according to the present invention;

FIG. 9 is a schematic view of a second partial structure of the vacuum forming apparatus of the present invention;

fig. 10 is a schematic perspective view of the strickle mechanism of the present invention.

Reference numerals: 1_ chassis, 2_ first support plate, 3_ rotation support mechanism, 4_ control panel, 5_ dust-free pressure-reducing semi-forming mechanism, 6_ strickle mechanism, 301_ first outer frame, 302_ first nozzle, 303_ first electric slide rail, 304_ second electric slide rail, 305_ second support plate, 306_ third electric slide rail, 307_ fourth electric slide rail, 308_ U-shaped link, 309_ limit cylinder, 3010_ combination plate, 3011_ first electric push rod, 3012_ second electric push rod, 3013_ third support plate, 3014_ press plate, 3015_ second nozzle, 501_ fourth support plate, 502_ third electric push rod, 3010_ fourth electric push rod, 504_ first bevel gear, 505_ first drive rod, 506_ first link, 507_ second link, 508_ third link, 509_ link block, 5010_ net frame plate, 5011_ salient point rod, 5012_ fifth electric push rod, 503_ sixth electric push rod, 5014_ fifth supporting plate, 601_ motor, 602_ second bevel gear, 603_ third bevel gear, 604_ second driving rod, 605_ supporting frame, 606_ first gear, 607_ first driving wheel, 608_ second driving wheel, 609_ fourth bevel gear, 6010_ sixth supporting plate, 6011_ seventh electric push rod, 6012_ eighth electric push rod, 6013_ second gear, 6014_ third driving wheel, 6015_ fourth driving wheel, 6016_ scraper.

Detailed Description

The technical scheme of the invention is further explained by combining the attached drawings.

Example 1

A half-forming pre-buried production device for sandwich moxa cones is shown in figures 1-10 and comprises an underframe 1, a first supporting plate 2, a bearing and rotating mechanism 3, a control screen 4, a dust-free decompression half-forming mechanism 5 and a strickling mechanism 6; the underframe 1 is fixedly connected with the first supporting plate 2; the underframe 1 is connected with the rotation bearing mechanism 3; the rotation bearing mechanism 3 is fixedly connected with the control screen 4; the bearing mechanism 3 is connected with the dust-free type pressure reduction semi-forming mechanism 5; the rotation bearing mechanism 3 is connected with the strickle mechanism 6; the dust-free type pressure reduction semi-forming mechanism 5 is connected with the strickling mechanism 6.

The working principle is as follows: when in use, the underframe 1 is firstly placed on a horizontal ground, then is externally connected with a power supply and is connected with a powder feeding pipeline, and meanwhile, a conveyor belt is placed in a moxa column extrusion area to be matched with the transfer of the moxa column; the device is controlled to operate by the control screen 4, the folium artemisiae argyi powder is injected into the limiting cylinder 309 at one side of the bearing mechanism 3 during operation, then the injected folium artemisiae argyi powder is extruded by the striking-off mechanism 6 in linkage with the dust-free type pressure reduction semi-forming mechanism 5, and the first support plate 2 is matched with the bottom to bear force during extrusion, so that the folium artemisiae argyi powder is formed into a concave-shaped section; then the bearing mechanism 3 moves the semi-formed moxa cone to the other side of the bearing mechanism 3 to fill spices and medicines into the semi-formed moxa cone; then moving the semi-formed moxa cone filled with the spices and the medicines through a bearing mechanism 3, and extruding the filled spices and the medicines through a scraping mechanism 6 in linkage with a dust-free decompression semi-forming mechanism 5; substantially shaping it; after the basic molding, the moxa column is moved to the moxa powder filling position again through the rotation bearing mechanism 3, and a small gap in the middle of the top of the basically molded moxa column is filled with the moxa powder; then the formed moxa cone is moved to the position of the strickling mechanism 6 through the bearing mechanism 3 to strickling the moxa cone on the upper surface; then moving to the extrusion area of the rotation bearing mechanism 3 to extrude the top surface of the moxa cone; uniformly collecting moxa cones after extrusion forming; the invention realizes the molding and filling of spices and medicines to the moxa cone, and can be produced in batch; the moxa powder, the spice and the medicine can not fly in disorder during integral extrusion forming, and the equipment is not easy to have the problem of dust accumulation and hungry.

The rotation bearing mechanism 3 comprises a first outer frame 301, a first nozzle 302, a first electric slide rail 303, a second electric slide rail 304, a second support plate 305, a third electric slide rail 306, a fourth electric slide rail 307, a U-shaped connecting frame 308, a limiting barrel 309, a combined plate 3010, a first electric push rod 3011, a second electric push rod 3012, a third support plate 3013, a press plate 3014 and a second nozzle 3015; the first outer frame 301 is inserted with a plurality of groups of first nozzles 302 at equal intervals; the first outer frame 301 is inserted with a plurality of groups of second nozzles 3015 at equal intervals; one side inside the first outer frame 301 is fixedly connected with a first electric slide rail 303; the other side inside the first outer frame 301 is fixedly connected with a second electric slide rail 304; the first outer frame 301 is fixedly connected with the underframe 1; the first outer frame 301 is connected with the dust-free type pressure reduction semi-forming mechanism 5; the first outer frame 301 is connected with the strickle mechanism 6; the first electric slide rail 303 and the second electric slide rail 304 are fixedly connected with the second support plate 305 through slide blocks; the interior of the second supporting plate 305 is fixedly connected with a plurality of limiting cylinders 309; one side of the bottom of the second supporting plate 305 is fixedly connected with a third electric slide rail 306; the other side of the bottom of the second supporting plate 305 is fixedly connected with a fourth electric slide rail 307; the third electric slide rail 306 and the fourth electric slide rail 307 are fixedly connected with the U-shaped connecting frame 308 through slide blocks; the bottoms of the limiting cylinders 309 are inserted into the combination plates 3010; the bottoms of the multiple combined plates 3010 are all fixedly connected with the U-shaped connecting frame 308; the first outer frame 301 is fixedly connected with the first electric push rod 3011; the first outer frame 301 is fixedly connected with the second electric push rod 3012; the bottoms of the first electric push rod 3011 and the second electric push rod 3012 are fixedly connected with the third support plate 3013 at the same time; the bottom of the third support plate 3013 is fixedly connected to a plurality of pressing plates 3014.

Firstly, controlling a first electric slide rail 303 and a second electric slide rail 304 in a first outer frame 301 to simultaneously drive a second support plate 305 to move so as to drive a plurality of groups of limiting cylinders 309 and connected components to move, when the first support plate moves to the lower part of the plurality of groups of first spray heads 302, the plurality of groups of first spray heads 302 quantitatively fill the moxa powder into the plurality of groups of limiting cylinders 309, and then the plurality of groups of limiting cylinders 309 are driven to move to the lower part of a dust-free type pressure reduction half-forming mechanism 5 for half-forming; after the process, when the plurality of groups of limiting cylinders 309 are driven to move to the positions below the plurality of groups of second nozzles 3015, the plurality of groups of second nozzles 3015 quantitatively fill the moxa powder into the plurality of groups of limiting cylinders 309, and then the plurality of groups of limiting cylinders 309 are moved to the positions below the dust-free pressure reduction semi-forming mechanism 5 again to perform basic forming; then when the plurality of groups of limiting cylinders 309 are driven to move to the positions below the plurality of groups of first nozzles 302, the plurality of groups of first nozzles 302 quantitatively fill the moxa powder into the plurality of groups of limiting cylinders 309 to make the moxa powder basically in a full state, and then the plurality of groups of limiting cylinders 309 move to the position of the strickling mechanism 6 to strickle the moxa cone on the upper surface; after being strickleed, the plurality of groups of limiting cylinders 309 move to the position below the pressing plate 3014, the pressing plate 3014 below the third supporting plate 3013 is driven to be pressed downwards by the simultaneous stretching of the first electric push rod 3011 and the second electric push rod 3012, and the moxa cone is extruded and completely molded; after molding, the third electric slide rail 306 and the fourth electric slide rail 307 simultaneously drive the plurality of groups of combination plates 3010 on the U-shaped connecting frame 308 to translate, so that openings appear at the bottoms of the plurality of groups of limiting cylinders 309, and then the moxa cones are extruded out through the plurality of groups of pressing plates 3014; the mechanism realizes the matching of driving the moxa column to be molded and simultaneously matching of taking out and transferring the moxa column after being molded.

The dust-free type pressure reduction semi-forming mechanism 5 comprises a fourth supporting plate 501, a third electric push rod 502, a fourth electric push rod 503, a first bevel gear 504, a first transmission rod 505, a first connecting rod 506, a second connecting rod 507, a third connecting rod 508, a connecting shaft block 509, a screen frame plate 5010, a salient point tamping rod 5011, a fifth electric push rod 5012, a sixth electric push rod 5013 and a fifth supporting plate 5014; one side above the fourth supporting plate 501 is fixedly connected with a third electric push rod 502; the other side above the fourth supporting plate 501 is fixedly connected with a fourth electric push rod 503; the fourth supporting plate 501 is rotatably connected with the first driving rod 505; the upper parts of the third electric push rod 502 and the fourth electric push rod 503 are fixedly connected with the first outer frame 301 at the same time; one side of the first transmission rod 505 is fixedly connected with the first bevel gear 504; the first bevel gear 504 is selectively meshed with the fourth bevel gear 609; the other side of the first transmission rod 505 is fixedly connected with a first connecting rod 506; the first connecting rod 506 is simultaneously connected with the second connecting rod 507 and the third connecting rod 508 in a rotating way through a rotating shaft; the second connecting rod 507 is rotatably connected with the connecting shaft block 509 through a rotating shaft; the bottom of the coupling block 509 is fixedly connected with the salient point tamping rod 5011; the outer surface of the salient point tamping rod 5011 is contacted with the screen frame plate 5010; one side below the fourth supporting plate 501 is fixedly connected with a fifth electric push rod 5012; the other side below the fourth supporting plate 501 is fixedly connected with a sixth electric push rod 5013; the lower parts of the fifth electric push rod 5012 and the sixth electric push rod 5013 are fixedly connected with the fifth supporting plate 5014 at the same time; the fifth support plate 5014 is fixedly connected to the mesh frame plate 5010.

During half forming and basic forming, the third electric push rod 502 and the fourth electric push rod 503 simultaneously drive the fourth support plate 501 to descend, so that the first bevel gear 504 connected with the fourth support plate descends to be meshed with the fourth bevel gear 609, the first bevel gear 504 drives the first transmission rod 505 to transmit the first connecting rod 506 when rotating, the first connecting rod 506 drives the second connecting rod 507 to drive the third connecting rod 508 to rotate when rotating, the second connecting rod 507 drives the bump tamping rod 5011 connected with the connecting shaft block 509 to reciprocate under the limit of the screen frame plate 5010 when rotating, and the fifth electric push rod 5012 and the sixth electric push rod 5013 descend to drive the screen frame plate 5010 at the bottom of the fifth support plate 5014 to be attached to the limit cylinder 309 when extruding; the corresponding multiple sets of screen frame plates 5010 are mutually attached to the limiting cylinder 309, then when the salient point tamping rod 5011 reciprocates, because the bottom is arranged to be a shape with a convex arc surface at the middle part, when the salient point tamping rod 5011 descends in the reciprocating motion, the powder can be deposited by utilizing impact compressed gas, then the wormwood powder right below the salient point tamping rod 5011 is extruded to the side of the salient point tamping rod 5011, when the salient point tamping rod 5011 descends to the lowest point and the bottom of the limiting cylinder 309 is reserved with a space with a pocket bottom, so that a concave cylinder space is formed by extrusion, when the salient point tamping rod 5011 descends, the compressed gas moves upwards along the inner wall of the punched concave cylinder space, thereby driving the wormwood powder to ascend from the bottom of the limiting cylinder 309, and after the bell-shaped bulge which contacts the bottom of the salient point tamping rod 5011, the air flow is guided to downwards from the axis, thereby forming vertical annular airflow, and further avoiding the situation that the ascending airflow cannot guide flow and impact the inner wall of the sunken cylinder space, so that the inner wall loses support and collapses, and the effect of effective plasticity of the sunken cylinder space cannot be achieved; this system has realized carrying out dustless formula shaping extrusion to the moxa cone.

The strickle mechanism 6 comprises a motor 601, a second bevel gear 602, a third bevel gear 603, a second transmission rod 604, a support frame 605, a first gear 606, a first transmission wheel 607, a second transmission wheel 608, a fourth bevel gear 609, a sixth support plate 6010, a seventh electric push rod 6011, an eighth electric push rod 6012, a second gear 6013, a third transmission wheel 6014, a fourth transmission wheel 6015 and a scraper 6016; an output shaft of the motor 601 is fixedly connected with the second bevel gear 602; the bottom of the motor 601 is fixedly connected with the first outer frame 301; the second bevel gear 602 is meshed with the third bevel gear 603; the axle center of the third bevel gear 603 is fixedly connected with the second transmission rod 604; the outer surface of the second transmission rod 604 is fixedly connected with the first gear 606 and the first transmission wheel 607; the outer surface of the second transmission rod 604 is rotatably connected with the first outer frame 301; the outer surface of the second transmission rod 604 is rotatably connected with the support frame 605; the support frame 605 is fixedly connected with the first outer frame 301; the outer ring surface of the first transmission wheel 607 is in transmission connection with a second transmission wheel 608 through a belt; the axle center of the second driving wheel 608 is rotationally connected with the supporting frame 605 through a rotating shaft; the axle center of the second driving wheel 608 is fixedly connected with a fourth bevel gear 609 through a rotating shaft; when the fourth bevel gear 609 is engaged with the first bevel gear 504, the first bevel gear 504 rotates, otherwise, the rotation is not performed; a second gear 6013 is arranged on the side of the first gear 606; when the first gear 606 is engaged with the second gear 6013, the second gear 6013 rotates, otherwise, the rotation is not performed; the axle center of the second gear 6013 is rotationally connected with the sixth supporting plate 6010 through a rotating shaft; the axle center of the second gear 6013 is fixedly connected with a third driving wheel 6014 through a rotating shaft; the outer ring surface of the third driving wheel 6014 is in transmission connection with a fourth driving wheel 6015 through a belt; the axle center of the fourth driving wheel 6015 is rotationally connected with the sixth supporting plate 6010 through a rotating shaft; the axle center of the fourth driving wheel 6015 is fixedly connected with the scraper 6016 through a rotating shaft; one side above the sixth supporting plate 6010 is fixedly connected with a seventh electric push rod 6011; the other side above the sixth supporting plate 6010 is fixedly connected with an eighth electric push rod 6012; the seventh electric push rod 6011 and the eighth electric push rod 6012 are fixed to the first outer frame 301 at the same time.

The motor 601 drives the second bevel gear 602 to engage with the third bevel gear 603, the third bevel gear 603 drives the second transmission rod 604 on the support frame 605 to rotate when rotating, the second transmission rod 604 drives the first gear 606 and the first transmission wheel 607 to rotate simultaneously when rotating, and the first transmission wheel 607 drives the second transmission wheel 608 to drive the fourth bevel gear 609 to engage with the first bevel gear 504 to rotate; during scraping, the seventh electric push rod 6011 and the eighth electric push rod 6012 simultaneously drive the sixth supporting plate 6010 to descend, the sixth supporting plate 6010 drives the second gear 6013 to engage with the first gear 606, and the second gear 6013 drives the third driving wheel 6014 to drive the fourth driving wheel 6015 to drive the scraper 6016 to rotate so as to scrape the upper surface of the moxa cone; this system has realized the dustless formula of linkage decompression half forming mechanism 5, and the cooperation is carried out strickleing of upper surface to the moxa cone simultaneously.

Multiple groups of fourth driving wheels 6015 and multiple groups of scrapers 6016 are arranged, and the multiple groups of fourth driving wheels 6015 are mutually driven.

Can simultaneously realize the strickling of a plurality of groups of folium artemisiae argyi powder after filling and injection.

Wherein, the first transmission rod 505, the first connecting rod 506, the second connecting rod 507, the third connecting rod 508, the coupling block 509, the screen frame plate 5010 and the bump tamping rod 5011 are provided with a plurality of groups, and each group of the first transmission rod 505 and the third connecting rod 508 between the two sides are mutually connected.

Can simultaneously realize the semi-molding of a plurality of groups of folium artemisiae argyi powder after injection.

Wherein, the bottom of the salient point tamping rod 5011 is provided with a bellied bulge.

The flying-out of the moxa powder caused by the previous plane stress during the forming can be reduced.

A half-molding pre-buried production method of a sandwich moxa cone comprises the following working steps:

s1: semi-molding, namely injecting the folium artemisiae argyi powder into a limiting cylinder 309 at one side of a rotation bearing mechanism 3, and then extruding the injected folium artemisiae argyi powder by a scraping mechanism 6 in linkage with a dust-free type pressure reduction semi-molding mechanism 5 to form the folium artemisiae argyi powder into a concave-shaped section;

s2: filling spices and medicines, moving the semi-formed moxa cone to the other side of the rotation bearing mechanism 3 by the rotation bearing mechanism 3, and filling the spices and the medicines into the semi-formed moxa cone;

s3: basically molding, moving the semi-molded moxa cone filled with the spices and the medicines by the rotation bearing mechanism 3, and extruding the filled spices and the medicines by the scraping mechanism 6 in linkage with the dust-free pressure reduction semi-molding mechanism 5; substantially shaping it;

s4: completely molding, repeating the first step in S1, and filling a small gap in the middle of the top of the basically molded moxa cone with folium Artemisiae Argyi powder; then the formed moxa cone is moved to the position of the strickling mechanism 6 through the bearing mechanism 3 to strickling the moxa cone on the upper surface; then moving to the extrusion area of the rotation bearing mechanism 3 to extrude the top surface of the moxa cone;

s5: collecting, namely uniformly collecting the moxa cones.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (8)

1. The utility model provides a pre-buried apparatus for producing of half-forming of sandwich moxa cone, includes chassis (1) and control panel (4), its characterized in that: the device also comprises a first supporting plate (2), a bearing and rotating mechanism (3), a dust-free type pressure reduction semi-forming mechanism (5) and a strickling mechanism (6); the underframe (1) is fixedly connected with the first supporting plate (2); the underframe (1) is connected with the rotation bearing mechanism (3); the rotation bearing mechanism (3) is fixedly connected with the control screen (4); the bearing mechanism (3) is connected with the dust-free type pressure reduction semi-forming mechanism (5); the bearing mechanism (3) is connected with the strickling mechanism (6); the dust-free type pressure reduction semi-forming mechanism (5) is connected with the strickling mechanism (6).

2. The semi-formed pre-buried production device of sandwich moxa cone of claim 1, characterized in that: the rotation bearing mechanism (3) comprises a first outer frame (301), a first spray head (302), a first electric slide rail (303), a second electric slide rail (304), a second support plate (305), a third electric slide rail (306), a fourth electric slide rail (307), a U-shaped connecting frame (308), a limiting cylinder (309), a combined plate (3010), a first electric push rod (3011), a second electric push rod (3012), a third support plate (3013), a pressure plate (3014) and a second spray head (3015); the first outer frame (301) is inserted with a plurality of groups of first nozzles (302) at equal intervals; the first outer frame (301) is inserted with a plurality of groups of second nozzles (3015) at equal intervals; one side of the inner part of the first outer frame (301) is fixedly connected with a first electric slide rail (303); the other side in the first outer frame (301) is fixedly connected with a second electric slide rail (304); the first outer frame (301) is fixedly connected with the underframe (1); the first outer frame (301) is connected with a dust-free decompression semi-forming mechanism (5); the first outer frame (301) is connected with the strickle mechanism (6); the first electric slide rail (303) and the second electric slide rail (304) are fixedly connected with the second support plate (305) through slide blocks; the interior of the second supporting plate (305) is fixedly connected with a plurality of limiting cylinders (309); one side of the bottom of the second support plate (305) is fixedly connected with a third electric slide rail (306); the other side of the bottom of the second supporting plate (305) is fixedly connected with a fourth electric sliding rail (307); the third electric slide rail (306) and the fourth electric slide rail (307) are fixedly connected with the U-shaped connecting frame (308) through slide blocks; the bottoms of the limiting cylinders (309) are inserted into the combination plates (3010); the bottoms of the combined plates (3010) are fixedly connected with the U-shaped connecting frame (308); the first outer frame (301) is fixedly connected with the first electric push rod (3011); the first outer frame (301) is fixedly connected with the second electric push rod (3012); the bottoms of the first electric push rod (3011) and the second electric push rod (3012) are fixedly connected with the third support plate (3013) at the same time; the bottom of the third supporting plate (3013) is fixedly connected with a plurality of groups of pressing plates (3014).

3. The semi-formed pre-buried production device of sandwich moxa cone of claim 2, characterized in that: the dust-free type pressure reduction semi-forming mechanism (5) comprises a fourth supporting plate (501), a third electric push rod (502), a fourth electric push rod (503), a first bevel gear (504), a first transmission rod (505), a first connecting rod (506), a second connecting rod (507), a third connecting rod (508), a connecting shaft block (509), a screen frame plate (5010), a salient point tamping rod (5011), a fifth electric push rod (5012), a sixth electric push rod (5013) and a fifth supporting plate (5014); one side above the fourth supporting plate (501) is fixedly connected with a third electric push rod (502); the other side above the fourth supporting plate (501) is fixedly connected with a fourth electric push rod (503); the fourth supporting plate (501) is rotatably connected with the first transmission rod (505); the upper parts of the third electric push rod (502) and the fourth electric push rod (503) are simultaneously and fixedly connected with the first outer frame (301); one side of the first transmission rod (505) is fixedly connected with the first bevel gear (504); the first bevel gear (504) is selectively meshed with the fourth bevel gear (609); the other side of the first transmission rod (505) is fixedly connected with a first connecting rod (506); the first connecting rod (506) is simultaneously and rotatably connected with the second connecting rod (507) and the third connecting rod (508) through a rotating shaft; the second connecting rod (507) is rotatably connected with the connecting shaft block (509) through a rotating shaft; the bottom of the coupling block (509) is fixedly connected with a salient point tamping rod (5011); the outer surface of the salient point tamping rod (5011) is contacted with the net frame plate (5010); one side of the lower part of the fourth supporting plate (501) is fixedly connected with a fifth electric push rod (5012); the other side of the lower part of the fourth supporting plate (501) is fixedly connected with a sixth electric push rod (5013); the lower parts of the fifth electric push rod (5012) and the sixth electric push rod (5013) are fixedly connected with the fifth supporting plate (5014) at the same time; the fifth supporting plate (5014) is fixedly connected with the net frame plate (5010).

4. The semi-formed pre-buried production device of sandwich moxa cone of claim 3, characterized in that: the strickle mechanism (6) comprises a motor (601), a second bevel gear (602), a third bevel gear (603), a second transmission rod (604), a support frame (605), a first gear (606), a first transmission wheel (607), a second transmission wheel (608), a fourth bevel gear (609), a sixth support plate (6010), a seventh electric push rod (6011), an eighth electric push rod (6012), a second gear (6013), a third transmission wheel (6014), a fourth transmission wheel (6015) and a scraper (6016); an output shaft of the motor (601) is fixedly connected with the second bevel gear (602); the bottom of the motor (601) is fixedly connected with the first outer frame (301); the second bevel gear (602) is meshed with the third bevel gear (603); the axle center of the third bevel gear (603) is fixedly connected with the second transmission rod (604); the outer surface of the second transmission rod (604) is fixedly connected with the first gear (606) and the first transmission wheel (607) at the same time; the outer surface of the second transmission rod (604) is rotationally connected with the first outer frame (301); the outer surface of the second transmission rod (604) is rotationally connected with the support frame (605); the support frame (605) is fixedly connected with the first outer frame (301); the outer ring surface of the first transmission wheel (607) is in transmission connection with a second transmission wheel (608) through a belt; the axle center of the second transmission wheel (608) is rotationally connected with the supporting frame (605) through a rotating shaft; the axle center of the second driving wheel (608) is fixedly connected with a fourth bevel gear (609) through a rotating shaft; when the fourth bevel gear (609) is meshed with the first bevel gear (504), the first bevel gear (504) rotates, otherwise, the first bevel gear does not rotate; a second gear (6013) is arranged on the side surface of the first gear (606); when the first gear (606) is meshed with the second gear (6013), the second gear (6013) rotates, otherwise, the second gear does not rotate; the axle center of the second gear (6013) is rotationally connected with the sixth supporting plate (6010) through a rotating shaft; the axle center of the second gear (6013) is fixedly connected with a third driving wheel (6014) through a rotating shaft; the outer ring surface of the third driving wheel (6014) is in transmission connection with a fourth driving wheel (6015) through a belt; the axle center of a fourth transmission wheel (6015) is rotationally connected with a sixth supporting plate (6010) through a rotating shaft; the axle center of a fourth driving wheel (6015) is fixedly connected with a scraper (6016) through a rotating shaft; one side above the sixth supporting plate (6010) is fixedly connected with a seventh electric push rod (6011); the other side above the sixth supporting plate (6010) is fixedly connected with an eighth electric push rod (6012); the upper parts of the seventh electric push rod (6011) and the eighth electric push rod (6012) are fixedly connected with the first outer frame (301) at the same time.

5. The semi-formed pre-buried production device of sandwich moxa cone of claim 4, characterized in that: the fourth driving wheel (6015) and the scraper (6016) are provided with multiple groups, and the multiple groups of fourth driving wheels (6015) are mutually driven.

6. The semi-formed pre-buried production device of sandwich moxa cone of claim 5, characterized in that: the first transmission rod (505), the first connecting rod (506), the second connecting rod (507), the third connecting rod (508), the connecting shaft block (509), the screen frame plate (5010) and the salient point tamping rod (5011) are provided with a plurality of groups, and each group of the first transmission rod (505) and the third connecting rod (508) except two sides are connected with each other.

7. The semi-formed pre-buried production device of sandwich moxa cone of claim 6, characterized in that: the bottom of the salient point tamping rod (5011) is provided with a bellied bulge.

8. A half-molding pre-buried production method of sandwiched moxa cones is characterized in that: the method comprises the following working steps:

s1: semi-molding, namely injecting the folium artemisiae argyi powder into a limiting cylinder (309) at one side of a bearing and rotating mechanism (3), and then extruding the injected folium artemisiae argyi powder by a scraping mechanism (6) in linkage with a dust-free type pressure reduction semi-molding mechanism (5) to form the folium artemisiae argyi powder into a concave-shaped section;

s2: filling spices and medicines, moving the semi-formed moxa cone to the other side of the rotation bearing mechanism (3) by the rotation bearing mechanism (3) and filling the spices and the medicines into the semi-formed moxa cone;

s3: basically molding, namely moving the semi-molded moxa cone filled with the spices and the medicines by the bearing mechanism (3), and extruding the filled spices and the medicines by the scraping mechanism (6) in linkage with the dust-free decompression semi-molding mechanism (5); substantially shaping it;

s4: completely molding, repeating the first step in S1, and filling a small gap in the middle of the top of the basically molded moxa cone with folium Artemisiae Argyi powder; then the formed moxa cone is moved to the position of the scraping mechanism (6) through the bearing mechanism (3) to scrape the moxa cone on the upper surface; then moving to the extrusion area of the rotation bearing mechanism (3) to extrude the top surface of the moxa cone;

s5: collecting, namely uniformly collecting the moxa cones.

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