阅读说明：本技术 一种医疗神经内科用成药制片设备 (Medical treatment department of neurology is with patent medicine film-making equipment ) 是由 董贵军 于 2021-07-21 设计创作，主要内容包括：本发明涉及一种成药制片设备,更具体的说是一种医疗神经内科用成药制片设备,包括等量传送机构、压制机构、沾胶衣联动机构,设备能够将粉末状药品等量传送至输出腔体内,设备能够将输出腔体内的药输出至压制桶中,设备能够将压制桶内的粉末状成药压制成片,设备能够将压制成片的药沾胶衣并自动输出,等量传送机构与压制机构连接,压制机构与沾胶衣联动机构连接,沾胶衣联动机构与等量传送机构连接。(The invention relates to finished medicine tabletting equipment, in particular to finished medicine tabletting equipment for medical neurology, which comprises an equivalent conveying mechanism, a pressing mechanism and a gel coat linkage mechanism, wherein the equipment can convey powdered medicines into an output cavity in an equivalent manner, can output the medicines in the output cavity into a pressing barrel, can press the powdered finished medicines in the pressing barrel into tablets, can automatically output the tablets after being dipped in the gel coat, is connected with the pressing mechanism, is connected with the gel coat linkage mechanism, and is connected with the equivalent conveying mechanism.)

1. The utility model provides a medical treatment is patent medicine film-making equipment for department of neurology, includes equivalent transport mechanism (1), hold down mechanism (2), is stained with gel coat link gear (3), its characterized in that: equivalent transport mechanism (1) be connected with pressing mechanism (2), pressing mechanism (2) with be stained with the clothing link gear (3) and be connected, be stained with the clothing link gear (3) and be connected with equivalent transport mechanism (1).

2. A medical neurology patent medicine production apparatus as set forth in claim 1, wherein: the equivalent transmission mechanism (1) comprises a power shaft a (1-1), a belt a (1-2), a connecting shaft a (1-3), a friction wheel a (1-4), a connecting shaft b (1-5), friction plates a (1-6), hinged plates a (1-7), a sliding transmission block (1-8), a sliding connection plate (1-9), a belt b (1-10), a connecting shaft c (1-11), interval friction wheels (1-12), a transmission sleeve (1-13), a hose connection plate (1-14), a propeller with a shaft (1-15), an output plate (1-16), a special-shaped output hole (1-17), an equivalent output plate (1-18), an inclined plate a (1-19), an inclined plate b (1-20), The device comprises a feeding groove (1-21), a device installation box body (1-22), rubber hoses (1-23), input grooves (1-24) and a device installation plate (1-25), wherein a power shaft a (1-1) is in friction connection with a belt a (1-2), the power shaft a (1-1) is in bearing connection with the device installation box body (1-22), the belt a (1-2) is in friction connection with a connecting shaft a (1-3), the belt a (1-2) is in friction connection with a friction wheel a (1-4), the friction wheel a (1-4) is connected with a connecting shaft b (1-5), a connecting shaft b (1-5) is in friction connection with a friction plate a (1-6), the connecting shaft b (1-5) is connected with a hinged plate a (1-7), and b (1-5) is in sliding connection with the device installation box body (1-22), the friction plates a (1-6) are connected with the equipment installation box body (1-22), the friction plates a (1-6) are connected with the equipment installation plate (1-25), the hinged plates a (1-7) are hinged with the sliding transmission blocks (1-8), the sliding transmission blocks (1-8) are connected with the sliding connection plates (1-9) in a sliding mode, the sliding transmission blocks (1-8) are connected with the output plates (1-16), the sliding transmission blocks (1-8) are connected with the output plates (1-18) with the same quantity, the sliding transmission blocks (1-8) are connected with the equipment installation plate (1-25) in a sliding mode, the sliding connection plates (1-9) are connected with the equipment installation plate (1-25), one ends of the belts b (1-10) are connected with the connecting shafts a (1-3) in a friction mode, the other ends of the belts b (1-10) are connected with the connecting shafts c (1-11) in a friction mode, a connecting shaft c (1-11) is in bearing connection with an equipment installation box body (1-22), an interval friction wheel (1-12) is connected with a conveying sleeve (1-13), the conveying sleeve (1-13) is connected with a hose connecting plate (1-14), the conveying sleeve (1-13) is connected with a propeller (1-15) with a shaft, the conveying sleeve (1-13) is connected with an output plate (1-16), a hole on the hose connecting plate (1-14) is connected with a rubber hose (1-23), a special-shaped output hole (1-17) is formed in a sliding conveying block (1-8), an equivalent output plate (1-18) is in sliding connection with an inclined plate a (1-19), an equivalent output plate (1-18) is in sliding connection with an inclined plate b (1-20), an equivalent output plate (1-18) is in sliding connection with a feeding groove (1-21), equivalent output plates (1-18) are connected with input grooves (1-24) in a sliding mode, inclined plates a (1-19) are connected with inclined plates b (1-20), inclined plates a (1-19) are connected with feed grooves (1-21), inclined plates b (1-20) are connected with feed grooves (1-21), feed grooves (1-21) are connected with equipment mounting plates (1-25), equipment mounting boxes (1-22) are connected with equipment mounting plates (1-25), rubber hoses (1-23) are connected and communicated with holes in the feed grooves (1-21), and input grooves (1-24) are connected with the equipment mounting plates (1-25).

3. A medical neurology patent medicine production apparatus as set forth in claim 1, wherein: the pressing mechanism (2) comprises a linkage wheel a (2-1), a linkage shaft a (2-2), a steel wire (2-3), a steel wire connecting plate (2-4), a torsion spring (2-5), a connecting column (2-6), a threaded shaft a (2-7), an extrusion plate (2-8), a linkage wheel b (2-9), a linkage shaft b (2-10), a belt wheel a (2-11), a belt I (2-12), a belt wheel b (2-13), a threaded shaft b (2-14), a pressure bearing block (2-15), an internal threaded connecting plate (2-16), a supporting spring (2-17), a supporting sleeve (2-18) and a connecting shaft c (2-19), wherein the linkage wheel a (2-1) is connected with the linkage shaft a (2-2), the universal driving shaft a (2-2) is in bearing connection with the equipment installation box body (1-22), the universal driving shaft a (2-2) is in bearing connection with the equipment installation box body (1-25), the steel wire (2-3) is sleeved on the universal driving shaft a (2-2) and one end of the steel wire is connected with the universal driving shaft a (2-2), the steel wire (2-3) is in friction connection with the friction plate a (1-6), the other end of the steel wire (2-3) is wound on the connecting shaft c (2-19) and is connected with the steel wire connecting plate (2-4), the steel wire connecting plate (2-4) is connected with the connecting shaft c (2-19), the torsion spring (2-5) is sleeved on the connecting shaft c (2-19) and one end of the torsion spring is connected with the steel wire (2-4) and the other end of the torsion spring is connected with the equipment installation box body (1-22), the connecting column (2-6) is connected with a threaded shaft a (2-7), the threaded shaft a (2-7) is connected with an extrusion plate (2-8), the threaded shaft a (2-7) is connected with an equipment installation box body (1-22) in a threaded manner, a linkage wheel b (2-9) is connected with a linkage shaft b (2-10), the linkage shaft b (2-10) is connected with a belt wheel a (2-11), the linkage shaft b (2-10) is connected with an equipment installation plate (1-25) in a bearing manner, the belt wheel a (2-11) is connected with a belt I (2-12) in a friction manner, the belt I (2-12) is connected with a belt wheel b (2-13) in a friction manner, a key groove on the belt wheel b (2-13) is connected with a key on the threaded shaft b (2-14) in a sliding manner, the threaded shaft b (2-14) is connected with a bearing block (2-15), the threaded shaft b (2-14) is in threaded connection with the internal thread connecting plate (2-16), the bearing block (2-15) is in sliding connection with the support sleeve (2-18), the internal thread connecting plate (2-16) is connected with the support sleeve (2-18), the support spring (2-17) is sleeved on the threaded shaft b (2-14) and limited on the bearing block (2-15) and the internal thread connecting plate (2-16), the support sleeve (2-18) is connected with the equipment mounting plate (1-25), and the connecting shaft c (2-19) is in bearing connection with the equipment mounting plate (1-25).

4. A medical neurology patent medicine production apparatus as set forth in claim 1, wherein: the linkage mechanism (3) for dipping the gel coats comprises a first hinged plate connecting block (3-1), a first special-shaped hinged plate (3-2), a bearing column (3-3) of the special-shaped hinged plate, a bearing plate (3-4), a first hinged plate (3-5), a dipping material output groove (3-6), a first sliding plate (3-7), a second sliding plate (3-8) and a first inclined plate (3-9), wherein the first hinged plate connecting block (3-1) is connected with a threaded shaft a (2-7), the first hinged plate connecting block (3-1) is hinged with the first special-shaped hinged plate (3-2), the first special-shaped hinged plate (3-2) is connected with the bearing column (3-3) of the special-shaped hinged plate, the first special-shaped hinged plate (3-2) is hinged with the first hinged plate (3-5), and the first special-shaped hinged plate (3-2) is connected with the bearing plate (3-4), the special-shaped hinged plate bearing column (3-3) is in bearing connection with the bearing plate (3-4), the bearing plate (3-4) is connected with the equipment installation box body (1-22), the hinged plate I (3-5) is connected with the stained material output groove (3-6), the stained material output groove (3-6) is connected with the sliding plate I (3-7), the stained material output groove (3-6) is connected with the sliding plate II (3-8), the sliding plate I (3-7) is in sliding connection with the equipment installation box body (1-22), the sliding plate II (3-8) is in sliding connection with the equipment installation box body (1-22), and the inclined plate I (3-9) is connected with the equipment installation box body (1-22).

5. A medical neurology patent medicine production apparatus as set forth in claim 1, wherein: a power source is arranged on the power shaft a (1-1) and can rotate.

Technical Field

The invention relates to finished medicine tabletting equipment, in particular to finished medicine tabletting equipment for medical neurology.

Background

In the neurology medicine application, due to the fact that requirements for the medicine content and the tablet weight are high, most of existing devices cannot accurately control the medicine content, such as: application number is CN201720180839.7 utility model patent, and this equipment is only can be quick and is pressed into the piece with powdered patent medicine, can not control the weight of powdered patent medicine, and does not possess the function that tablet medicine is stained with the gel coat, so designed this kind of medical treatment is medicine film-making equipment for department of neurology.

Disclosure of Invention

The invention mainly solves the technical problem of providing finished medicine tabletting equipment for medical neurology, which can equally convey powdered medicines into an output cavity, output the medicines in the output cavity into a pressing barrel, compress the powdered finished medicines in the pressing barrel into tablets, and dip the tabletted medicines in gel coats and automatically output the tabletted medicines.

In order to solve the technical problem, the invention relates to finished medicine tabletting equipment, in particular to finished medicine tabletting equipment for medical neurology, which comprises an equivalent conveying mechanism, a pressing mechanism and a gel coat sticking linkage mechanism, wherein the equipment can convey powdery medicines to an output cavity in an equivalent manner, output the medicines in the output cavity to a pressing barrel, press the powdery finished medicines in the pressing barrel into tablets by the equipment, and stick the prepared medicines pressed into tablets to a gel coat and automatically output the tablets by the equipment.

The equivalent conveying mechanism is connected with the pressing mechanism, the pressing mechanism is connected with the glue coating linkage mechanism, and the glue coating linkage mechanism is connected with the equivalent conveying mechanism.

As a further optimization of the technical scheme, the invention relates to a patent medicine tabletting device for medical neurology, which comprises an equivalent conveying mechanism, a power shaft a, a belt a, a connecting shaft a, a friction wheel a, a connecting shaft b, a friction plate a, a hinged plate a, a sliding conveying block, a sliding connecting plate, a belt b, a connecting shaft c, an interval friction wheel, a conveying sleeve, a hose connecting plate, a belt shaft propeller, an output plate, a special-shaped output hole, an equivalent output plate, an inclined plate a, an inclined plate b, a feeding groove, a device mounting box body, a rubber hose, an input groove and a device mounting plate, wherein the power shaft a is in friction connection with the belt a, the power shaft a is connected with a bearing of the device mounting box body, the belt a is in friction connection with the connecting shaft a, the belt a is in friction connection with the friction wheel a, the friction wheel a is connected with the connecting shaft b, the connecting shaft b is connected with the hinged plate a, the connecting shaft b is connected with the equipment installation box body in a sliding way, the friction plate a is connected with the equipment installation box body, the friction plate a is connected with the equipment installation plate, the hinged plate a is hinged with the sliding transmission block, the sliding transmission block is connected with the sliding connection plate in a sliding way, the sliding transmission block is connected with the output plate, the sliding transmission block is connected with the equipment installation plate in a sliding way, the sliding connection plate is connected with the equipment installation plate, one end of the belt b is connected with the connecting shaft a in a friction way, the other end of the belt b is connected with the connecting shaft c in a friction way, the connecting shaft c is connected with the equipment installation box body bearing, the interval friction wheel is connected with the transmission sleeve, the transmission sleeve is connected with the hose connection plate, the transmission sleeve is connected with the screw propeller with the shaft, the transmission sleeve is connected with the output plate, a hole in the hose connection plate is connected with a rubber hose, the special-shaped output hole is formed in the sliding transmission block, and the output plate is connected with the inclined plate a in a sliding way in an equal amount, equivalent output board and hang plate b sliding connection, equivalent output board and feed chute sliding connection, equivalent output board and input slot sliding connection, hang plate an and hang plate b are connected, hang plate an and feed chute are connected, hang plate b and feed chute are connected, the feed chute is connected with the equipment fixing board, the equipment fixing box is connected with the equipment fixing board, rubber hose is connected and is linked together with the hole on the feed chute, the input slot is connected with the equipment fixing board.

As a further optimization of the technical scheme, the patent medicine tabletting equipment for the medical neurology department comprises a pressing mechanism, a linkage wheel a, a linkage shaft a, a steel wire connecting plate, a torsion spring, a connecting column, a threaded shaft a, an extrusion plate, a linkage wheel b, a linkage shaft b, a belt wheel a, a belt wheel I, a belt wheel B, a threaded shaft b, a pressure bearing block, an internal thread connecting plate, a supporting spring, a supporting sleeve and a connecting shaft c, wherein the linkage wheel a is connected with the linkage shaft a, the linkage shaft a is connected with an equipment mounting box body bearing, the linkage shaft a is connected with an equipment mounting plate bearing, the steel wire is sleeved on the linkage shaft a, one end of the steel wire is connected with the linkage shaft a, the steel wire is in friction connection with the friction plate a, the other end of the steel wire is wound on the connecting shaft c and is connected with the steel wire connecting plate, the torsion spring is sleeved on the connecting shaft c, one end of the torsion spring is connected with the steel wire connecting plate, the other end of the torsion spring is connected with the equipment mounting box body, the connecting column is connected with a threaded shaft a, the threaded shaft a is connected with the extrusion plate, the threaded shaft a is in threaded connection with the equipment mounting box body, the linkage wheel b is connected with the linkage shaft b, the linkage shaft b is connected with the belt wheel a, the linkage shaft b is connected with the equipment mounting plate bearing, the belt wheel a is in friction connection with the belt wheel a, the belt wheel a is in friction connection with the belt wheel b, a key groove in the belt wheel b is in sliding connection with a key in the threaded shaft b, the threaded shaft b is connected with the bearing block, the threaded shaft b is in threaded connection with the internal thread connecting plate, the bearing block is in sliding connection with the supporting sleeve, the internal thread connecting plate is connected with the supporting sleeve, the supporting spring is sleeved on the threaded shaft b and limited on the bearing block and the internal thread connecting plate, the supporting sleeve is connected with the equipment mounting plate, and the connecting shaft c is connected with the equipment mounting plate bearing.

As a further optimization of the technical scheme, the invention relates to a medical neurology patent medicine tabletting device, wherein the gel coat sticking linkage mechanism comprises a first hinge plate connecting block, a first special-shaped hinge plate, a bearing column of the special-shaped hinge plate, a bearing plate, a first hinge plate, a material sticking output groove, a first sliding plate, a second sliding plate and a first inclined plate, the first hinge plate connecting block is connected with a threaded shaft a, the first hinge plate connecting block is hinged with the first special-shaped hinge plate, the first special-shaped hinge plate is connected with the bearing column of the special-shaped hinge plate, the first special-shaped hinge plate is hinged with the first hinge plate, the first special-shaped hinge plate is connected with the bearing plate, the bearing plate is connected with a device mounting box body, the first hinge plate is connected with the material sticking output groove, the material sticking output groove is connected with the first sliding plate, the material sticking output groove is connected with the second sliding plate, and the first sliding plate is connected with the device mounting box body in a sliding manner, the sliding plate II is connected with the equipment installation box body in a sliding mode, and the inclined plate I is connected with the equipment installation box body.

As a further optimization of the technical scheme, the patent medicine tabletting equipment for the medical neurology department is characterized in that a power source is arranged on the power shaft a and can rotate.

The patent refers to the field of 'pharmaceutical preparations'.

According to the finished medicine tabletting equipment for the medical neurology, disclosed by the invention, powdered medicines can be equivalently conveyed into the output cavity, the medicine in the output cavity can be output into the pressing barrel by the equipment, the powdered finished medicine in the pressing barrel can be pressed into tablets by the equipment, and the medicine pressed into tablets can be stained with gel coats and automatically output by the equipment.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of a patent medicine tabletting device for medical neurology in the invention.

Fig. 2 is a schematic structural diagram of a patent medicine tabletting device for medical neurology in the invention.

Fig. 3 is a first structural schematic diagram of an equivalent conveying mechanism 1 of a patent medicine tabletting equipment for medical neurology in the invention.

Fig. 4 is a structural schematic diagram of an equivalent conveying mechanism 1 of a patent medicine tabletting equipment for medical neurology in the invention.

Fig. 5 is a schematic structural diagram three of an equivalent conveying mechanism 1 of a patent medicine tabletting equipment for medical neurology in the invention.

Fig. 6 is a fourth schematic structural diagram of the equivalent conveying mechanism 1 of the patent medicine tabletting equipment for the medical neurology department.

Fig. 7 is a fifth structural schematic diagram of the equivalent conveying mechanism 1 of the patent medicine tabletting equipment for the medical neurology department.

Fig. 8 is a sixth schematic structural view of the equivalent conveying mechanism 1 of the patent medicine tabletting equipment for the medical neurology department.

Fig. 9 is a seventh structural schematic diagram of the equivalent conveying mechanism 1 of the patent medicine tabletting equipment for the medical neurology department.

Fig. 10 is an eighth schematic structural view of the equivalent conveying mechanism 1 of the patent medicine tabletting equipment for the medical neurology department.

Fig. 11 is a first structural schematic diagram of the equipment installation box 1-22 of the patent medicine tabletting equipment for the medical neurology department.

FIG. 12 is a second schematic structural view of the apparatus mounting case 1-22 of the patent medicine tabletting apparatus for medical neurology of the present invention.

Fig. 13 is a first structural schematic diagram of a pressing mechanism 2 of a patent medicine tabletting equipment for medical neurology of the invention.

Fig. 14 is a structural schematic diagram of a second pressing mechanism 2 of the patent medicine tabletting equipment for the medical neurology department.

Fig. 15 is a third schematic structural diagram of the pressing mechanism 2 of the patent medicine tabletting equipment for the medical neurology department.

Fig. 16 is a first structural schematic diagram of a gel coat sticking linkage mechanism 3 of a finished medicine tabletting device for medical neurology in the invention.

Fig. 17 is a second structural schematic view of a gel coat sticking linkage mechanism 3 of a patent medicine tabletting device for medical neurology in the invention.

In the figure: an equivalent transfer mechanism 1; power shaft a 1-1; belt a 1-2; connecting shaft a 1-3; friction wheel a 1-4; connecting shaft b 1-5; friction plate a 1-6; hinge plate a 1-7; sliding the transfer blocks 1-8; sliding connection plates 1-9; belt b 1-10; connecting shaft c 1-11; 1-12 of interval friction wheel; 1-13 of a conveying sleeve; hose connection plates 1-14; 1-15 of a propeller with a shaft; output plates 1-16; 1-17 of special-shaped output holes; equivalent output plates 1-18; the inclined plates a 1-19; inclined plates b 1-20; 1-21 of a feed chute; equipment installation boxes 1-22; 1-23 parts of rubber hose; input slots 1-24; equipment mounting plates 1-25; a pressing mechanism 2; a linkage wheel a 2-1; linkage shaft a 2-2; 2-3 parts of steel wire; 2-4 of a steel wire connecting plate; 2-5 parts of a torsion spring; connecting columns 2-6; a threaded shaft a 2-7; 2-8 parts of an extrusion plate; linkage wheel b 2-9; linkage shaft b 2-10; pulley a 2-11; 2-12 parts of a first belt; pulley b 2-13; a threaded shaft b 2-14; 2-15 parts of a pressure bearing block; internal thread connecting plates 2-16; support springs 2-17; 2-18 parts of a support sleeve; connecting shafts c 2-19; a linkage mechanism 3 for dipping the gel coat; a first hinge plate connecting block 3-1; 3-2 of a special-shaped hinge plate I; 3-3 of a special-shaped hinged plate bearing column; 3-4 parts of bearing plates; 3-5 of a first hinge plate; a sticky material output groove 3-6; a first sliding plate 3-7; a second sliding plate 3-8; and 3-9 inclined plates.

Detailed Description

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, and fig. 17, the invention relates to a finished medicine tabletting device, and more specifically, to a finished medicine tabletting device for medical neurology, which includes an equivalent conveying mechanism 1, a pressing mechanism 2, and a gel coat adhering linkage mechanism 3, the device can convey equivalent powdered medicines into an output cavity, the device can output the medicines in the output cavity into a pressing barrel, the device can press the powdered finished medicines in the pressing barrel into tablets, and the device can adhere the pressed tablets with gel coats and automatically output the same.

The equivalent conveying mechanism 1 is connected with the pressing mechanism 2, the pressing mechanism 2 is connected with the glue coating linkage mechanism 3, and the glue coating linkage mechanism 3 is connected with the equivalent conveying mechanism 1.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes that the equivalent transmission mechanism 1 comprises a power shaft a1-1, a belt a1-2, a connecting shaft a1-3, a friction wheel a1-4, a connecting shaft b1-5, a friction plate a1-6, a hinge plate a1-7, a sliding transmission block 1-8, a sliding connection plate 1-9, a belt b1-10, a connecting shaft c1-11, a section friction wheel 1-12, a transmission sleeve 1-13, a hose connection plate 1-14, a belt shaft propeller 1-15, an output plate 1-16, a special-shaped output hole 1-17, an equivalent output plate 1-18, a belt shaft propeller 1-15, an output plate 1-16, a special-shaped transmission plate 1-9, a special-shaped transmission plate, Inclined plates a1-19, inclined plates b1-20, feeding grooves 1-21, equipment mounting boxes 1-22, rubber hoses 1-23, input grooves 1-24 and equipment mounting plates 1-25, a power shaft a1-1 is in frictional connection with a belt a1-2, the power shaft a1-1 is in bearing connection with the equipment mounting boxes 1-22, the belt a1-2 is in frictional connection with a connecting shaft a1-3, the belt a1-2 is in frictional connection with a friction wheel a1-4, the friction wheel a1-4 is connected with a connecting shaft b1-5, a connecting shaft b1-5 is in frictional connection with a friction plate a1-6, a connecting shaft b1-5 is connected with a hinge plate a1-7, a connecting shaft b1-5 is in sliding connection with the equipment mounting boxes 1-22, a friction plate a1-6 is connected with the equipment mounting boxes 1-22, the friction plate a1-6 is connected with the equipment mounting plate 1-25, the hinge plate a1-7 is hinged with the sliding transmission block 1-8, the sliding transmission block 1-8 is connected with the sliding connection plate 1-9 in a sliding way, the sliding transmission block 1-8 is connected with the output plate 1-16, the sliding transmission block 1-8 is connected with the output plate 1-18 with equal quantity, the sliding transmission block 1-8 is connected with the equipment mounting plate 1-25 in a sliding way, the sliding connection plate 1-9 is connected with the equipment mounting plate 1-25, one end of the belt b1-10 is connected with the connecting shaft a1-3 in a friction way, the other end is connected with the connecting shaft c1-11 in a friction way, the connecting shaft c1-11 is connected with the bearing of the equipment mounting box body 1-22, the interval friction wheel 1-12 is connected with the transmission sleeve 1-13, the transmission sleeve 1-13 is connected with the hose connection plate 1-14, the conveying sleeves 1-13 are connected with the screw propellers 1-15 with shafts, the conveying sleeves 1-13 are connected with the output plates 1-16, the holes on the hose connecting plates 1-14 are connected with the rubber hoses 1-23, the special-shaped output holes 1-17 are opened on the sliding conveying blocks 1-8, the equal output plates 1-18 are slidably connected with the inclined plates a1-19, the equal output plates 1-18 are slidably connected with the inclined plates b1-20, the equal output plates 1-18 are slidably connected with the feed chutes 1-21, the equal output plates 1-18 are slidably connected with the feed chutes 1-24, the inclined plates a1-19 are connected with the inclined plates b1-20, the inclined plates a1-19 are connected with the feed chutes 1-21, the inclined plates b1-20 are connected with the feed chutes 1-21, the feed chutes 1-21 are connected with the equipment mounting plates 1-25, the equipment mounting box body 1-22 is connected with the equipment mounting plate 1-25, the rubber hose 1-23 is connected and communicated with the hole on the feeding groove 1-21, the input groove 1-24 is connected with the equipment mounting plate 1-25, the equipment can convey powdered medicines into the output cavity in equal quantity, the equipment can output the medicines in the output cavity into the pressing barrel, the power shaft a1-1 rotates, the power shaft a1-1 rotates to drive the connecting shaft a1-3 to rotate through the belt a1-2, the belt a1-2 also drives the friction wheel a1-4 to rotate during movement, the friction wheel a1-4 rotates to drive the connecting shaft b1-5 to ascend or descend under the limitation of the friction plate a1-6, and as the friction wheel a1-4 is connected with the connecting shaft b1-5 through a bearing, when the b1-5 descends, the connecting shaft b1-5 drives the sliding conveying block 1-8 to slide under the limitation of the sliding connecting plate 1-9 and the equipment mounting plate 1-25 through the hinge plate a1-7, the sliding conveying block 1-8 drives the output plate 1-16 to move synchronously when sliding, the output plate 1-16 drives the interval friction wheel 1-12 through the conveying sleeve 1-13, the interval friction wheel 1-12 moves to be contacted with the belt b1-10, the connecting shaft a1-3 rotates and drives the connecting shaft c1-11 to rotate through the belt b1-10, the belt b1-10 drives the interval friction wheel 1-12 to rotate when moving, the conveying sleeve 1-13 is connected with the output plate 1-16 through the bearing, so the output plate 1-16 rotates when the interval friction wheel 1-12 rotates, the output plate 1-16 rotates and drives the driving shaft propeller 1-15 to rotate, when the screw propeller 1-15 with shaft rotates, air is blown to one side of the output plate 1-16, air is sucked to the other side, at the moment, the suction force acts in the rubber hose 1-23, namely, the powder medicine in the space formed by the feed chute 1-21 and the input chute 1-24 is absorbed into the special-shaped output hole 1-17 on the sliding conveying block 1-8, the sliding transmission blocks 1-8 also drive the equivalent output plates 1-18 to move when moving, namely, the medicine can be separated from the rest powder medicine in equal amount during the movement of the equal amount output plates 1-18, when the sliding conveying block 1-8 moves towards the direction far away from the feeding chute 1-21, the special-shaped output holes 1-17 on the sliding conveying block 1-8 are matched with the supporting sleeves 2-18, and the traditional Chinese medicine in the special-shaped output holes 1-17 can be conveyed into the pressing barrel formed by the supporting sleeves 2-18 under the action of the shafted screw 1-15.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes the embodiment, where the pressing mechanism 2 includes a linkage wheel a2-1, a linkage shaft a2-2, a steel wire 2-3, a steel wire connecting plate 2-4, a torsion spring 2-5, a connecting column 2-6, a threaded shaft a2-7, a pressing plate 2-8, a linkage wheel b2-9, a linkage shaft b2-10, a pulley a2-11, a belt one 2-12, a pulley b2-13, a threaded shaft b2-14, a bearing block 2-15, an internal thread connecting plate 2-16, a support spring 2-17, a support sleeve 2-18, and a c2-19, the linkage wheel a2-1 is connected with a linkage shaft a2-2, the linkage shaft a2-2 is connected with a bearing of an equipment installation box body 1-22, the linkage shaft a2-2 is connected with a bearing of an equipment installation plate 1-25, a steel wire 2-3 is sleeved on the linkage shaft a2-2, one end of the steel wire is connected with a linkage shaft a2-2, the steel wire 2-3 is in friction connection with a friction plate a1-6, the other end of the steel wire 2-3 is wound on a connecting shaft c2-19 and is connected with a steel wire connecting plate 2-4, the steel wire connecting plate 2-4 is connected with a connecting shaft c2-19, a torsion spring 2-5 is sleeved on the connecting shaft c2-19, one end of the torsion spring is connected with the steel wire connecting plate 2-4, the other end of the torsion spring is connected with the equipment installation box body 1-22, a connecting column 2-6 is connected with a threaded shaft a2-7, the threaded shaft a2-7 is connected with the extrusion plate 2-8, the threaded shaft a2-7 is in threaded connection with the equipment installation box 1-22, the linkage wheel b2-9 is connected with the linkage shaft b2-10, the linkage shaft b2-10 is connected with the belt wheel a2-11, the linkage shaft b2-10 is in bearing connection with the equipment installation plate 1-25, the belt wheel a2-11 is in frictional connection with the belt I2-12, the belt I2-12 is in frictional connection with the belt wheel b2-13, a key groove on the belt wheel b2-13 is in sliding connection with a key on the threaded shaft b2-14, the threaded shaft b2-14 is connected with the bearing block 2-15, the threaded shaft b2-14 is in threaded connection with the internal threaded connecting plate 2-16, the bearing block 2-15 is in sliding connection with the support sleeve 2-18, the internal threaded connecting plate 2-16 is connected with the support sleeve 2-18, the supporting springs 2-17 are sleeved on the threaded shafts b2-14 and limited on the pressure bearing blocks 2-15 and the internal thread connecting plates 2-16, the supporting sleeves 2-18 are connected with the equipment mounting plates 1-25, the connecting shafts c2-19 are connected with the equipment mounting plates 1-25 in a bearing mode, the equipment can press powdery finished medicine in a pressing barrel into tablets, when the sliding conveying blocks 1-8 are in contact with the linkage wheels a2-1, the friction connection relationship is generated between the sliding conveying blocks 1-8 and the linkage wheels a2-1, namely the linkage wheels a2-1 can be driven to rotate in the process that the sliding conveying blocks 1-8 move towards the direction far away from the feeding grooves 1-21, the linkage wheels a2-1 rotate to drive the linkage shafts a2-2 to rotate, when the linkage shafts a2-2 rotate, the steel wires 2-3 are gradually released from winding on the linkage shafts a2-2, and under the action of the torsion springs 2-5, the steel wires 2-3 continue to wind on the steel wire connecting plates 2-4 Winding on a connecting shaft c2-19, wherein a steel wire 2-3 drives a connecting column 2-6 to rotate, the connecting column 2-6 drives a threaded shaft a2-7 to ascend when rotating, a sliding conveying block 1-8 can be contacted with a supporting sleeve 2-18 when the threaded shaft a2-7 ascends, the threaded shaft a2-7 can move downwards and press the medicine in the supporting sleeve 2-18 through an extrusion plate 2-8 when the sliding conveying block 1-8 moves, a linkage wheel b2-9 is also driven to rotate when the sliding conveying block 1-8 moves, the linkage wheel b2-9 rotates to drive a belt wheel a2-11 to rotate through a linkage shaft b2-10, the belt wheel a2-11 rotates and drives a belt wheel b2-13 to rotate through a belt one 2-12, the belt wheel b2-13 rotates to drive a threaded shaft b2-14 to rotate, when the threaded shaft b2-14 rotates, the threaded shaft b2-14 can ascend or descend under the action of the internal threaded connecting plate 2-16, the threaded shaft b2-14 moves to transfer the pressure bearing blocks 2-15 to move, and the pressure bearing blocks 2-15 can automatically reset under the action of the supporting springs 2-17, at this time, the pressure bearing blocks 2-15 and the extrusion plates 2-8 can simultaneously move in opposite directions, namely when the sliding transmission block 1-8 moves in the direction away from the feeding chute 1-21, the pressure bearing blocks 2-15 move the extrusion plates 2-8 upwards, the effective cavities in the supporting sleeves 2-18 become larger, the medicine transmitted from the special-shaped output holes 1-17 can be transmitted to the effective cavities in the supporting sleeves 2-18, when the sliding transmission block 1-8 moves in the direction of the feeding chute 1-21, the pressure bearing blocks 2-15 move the extrusion plates 2-8 downwards, the pressure blocks 2-15 and the pressing plates 2-8 can press the powdered medicine into tablets, and can push the pressed tablets away from the feeding grooves 1-21 when the sliding conveying blocks 1-8 move.

The fourth concrete implementation mode:

the embodiment is described below by combining with fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes the first embodiment, the linkage mechanism 3 for dipping the gel coat comprises a first hinge plate connecting block 3-1, a first profiled hinge plate 3-2, a first profiled hinge plate bearing column 3-3, a bearing plate 3-4, a first hinge plate 3-5, a dipping material output groove 3-6, a first sliding plate 3-7, a second sliding plate 3-8, and a first inclined plate 3-9, the first hinge plate connecting block 3-1 is connected with a threaded shaft a2-7, the first connecting block 3-1 is hinged with the first profiled hinge plate 3-2, the first profiled hinge plate 3-2 is connected with a bearing column 3-3 of the hinge plate, the special-shaped hinged plate I3-2 is hinged with the hinged plate I3-5, the special-shaped hinged plate I3-2 is connected with the bearing plate 3-4, the special-shaped hinged plate bearing column 3-3 is connected with the bearing plate 3-4 through a bearing, the bearing plate 3-4 is connected with the equipment installation box body 1-22, the hinged plate I3-5 is connected with the dipping material output groove 3-6, the dipping material output groove 3-6 is connected with the sliding plate I3-7, the dipping material output groove 3-6 is connected with the sliding plate II 3-8, the sliding plate I3-7 is connected with the equipment installation box body 1-22 through a sliding way, the sliding plate II 3-8 is connected with the equipment installation box body 1-22 through a sliding way, the inclined plate I3-9 is connected with the equipment installation box body 1-22 through a sliding way, and the equipment can dip the pressed medicine into the gel coat and automatically output the medicine, when the threaded shaft a2-7 moves upwards, the threaded shaft a2-7 moves to drive the hinged plate connecting block I3-1 in a special shape to drive the hinged plate I3-5 to move downwards under the action of the hinged plate bearing column 3-3 and the bearing plate 3-4, when the hinged plate I3-5 moves downwards, the moving sliding conveying block 1-8 pushes the tablet pressing medicine into the stain output groove 3-6, the stain output groove 3-6 attaches the liquid gel coat in the gel coat box formed by the square cavity of the equipment installation box body 1-22 to the pressed tablet through the micropores on the hinged plate I3-5, when the threaded shaft a2-7 moves in the reverse direction, the hinged plate I3-5 drives the stain output groove 3-6 to move in the reverse direction, and conveys the tablet dipped with the gel coat to the inclined plate I3-9 under the action of the sliding plate I3-7 and the sliding plate II 3-8, and is tilted out of the apparatus by means of the tilting plates one 3-9.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and further described with reference to the first embodiment, in which a power source is rotatably disposed on the power shaft a 1-1.

The working principle of the device is as follows: the equipment can equally convey powdered medicines into the output cavity, the equipment can output the medicines in the output cavity into the pressing barrel, the power shaft a1-1 rotates, the power shaft a1-1 rotates to drive the connecting shaft a1-3 to rotate through the belt a1-2, the belt a1-2 also drives the friction wheel a1-4 to rotate when moving, the friction wheel a1-4 rotates to drive the connecting shaft b1-5 to ascend or descend under the limitation of the friction plate a1-6, as the friction wheel a1-4 is connected with the connecting shaft b1-5 through a bearing, when the connecting shaft b1-5 descends, the connecting shaft b1-5 drives the sliding conveying block 1-8 to slide under the limitation of the sliding connecting plate 1-9 and the equipment mounting plate 1-25 through the hinge plate a1-7, and drives the output plate 1-16 to synchronously move when the sliding conveying block 1-8 slides, the output plate 1-16 moves to drive the interval friction wheel 1-12 through the transmission sleeve 1-13, when the interval friction wheel 1-12 moves to be contacted with the belt b1-10, the connecting shaft a1-3 rotates to drive the connecting shaft c1-11 to rotate through the belt b1-10, the belt b1-10 moves to drive the interval friction wheel 1-12 to rotate, the transmission sleeve 1-13 is connected with the output plate 1-16 through a bearing, the output plate 1-16 rotates when the interval friction wheel 1-12 rotates, the output plate 1-16 rotates to drive the shaft propeller 1-15 to rotate, the shaft propeller 1-15 rotates to blow air to one side of the output plate 1-16 and suck air to the other side, and the adsorption force acts in the rubber hose 1-23, namely, the powdery patent medicine with the space formed by the feeding groove 1-21 and the feeding groove 1-24 is adsorbed to the sliding transmission block 1- In the special-shaped output holes 1-17 on the sliding conveying block 8, the equal-amount output plates 1-18 are also driven to move when the sliding conveying block 1-8 moves, namely, the equal-amount output plates 1-18 can separate medicines from residual powder medicines in equal amount, when the sliding conveying block 1-8 moves towards the direction far away from the feeding groove 1-21, the special-shaped output holes 1-17 on the sliding conveying block 1-8 are matched with the supporting sleeves 2-18, the traditional Chinese medicines in the special-shaped output holes 1-17 can be conveyed into a pressing barrel formed by the supporting sleeves 2-18 under the action of the belt shaft propeller 1-15, the equipment can press the powdery finished medicines in the pressing barrel into tablets, when the sliding conveying block 1-8 is contacted with the linkage wheel a2-1, namely, the linkage wheel a2-1 can be driven to rotate when the sliding conveying block 1-8 moves towards the direction far away from the feeding groove 1-21, the linkage wheel a2-1 rotates to drive the linkage shaft a2-2 to rotate, the linkage shaft a2-2 rotates to enable the steel wire 2-3 to gradually release winding on the linkage shaft a2-2, the steel wire 2-3 is continuously wound on the connecting shaft c2-19 through the steel wire connecting plate 2-4 under the action of the torsion spring 2-5, at the moment, the steel wire 2-3 drives the connecting column 2-6 to rotate, the connecting column 2-6 rotates to drive the threaded shaft a2-7 to ascend, the threaded shaft a2-7 ascends to drive the sliding conveying block 1-8 to contact with the supporting sleeve 2-18 when moving, the threaded shaft a2-7 can move downwards and press the medicine in the supporting sleeve 2-18 through the extrusion plate 2-8 when the sliding conveying block 1-8 moves, the linkage wheel b2-9 is also driven to rotate when the sliding conveying block 1-8 moves, the linkage wheel b2-9 rotates to drive the belt wheel a2-11 to rotate through the linkage shaft b2-10, the belt wheel a2-11 rotates and drives the belt wheel b2-13 to rotate through the belt I2-12, the belt wheel b2-13 rotates to drive the threaded shaft b2-14 to rotate, the threaded shaft b2-14 can ascend or descend under the action of the internal threaded connecting plate 2-16 when rotating, the threaded shaft b2-14 moves to move the pressure bearing blocks 2-15, the pressure bearing blocks 2-15 can automatically reset under the action of the supporting springs 2-17, at the moment, the pressure bearing blocks 2-15 and the extrusion plates 2-8 can simultaneously move in opposite directions, namely when the sliding transmission blocks 1-8 move in the direction far away from the feeding grooves 1-21, the pressure bearing blocks 2-15 move the extrusion plates 2-8 upwards, the extrusion plates 2-8 move downwards, and the effective cavity in the supporting sleeve 2-18 is enlarged, the medicine conveyed from the special-shaped output holes 1-17 can be conveyed into an effective cavity in the supporting sleeves 2-18, when the sliding conveying blocks 1-8 move towards the feeding grooves 1-21, the pressure-bearing blocks 2-15 move downwards to move the extrusion plates 2-8 upwards, the pressure-bearing blocks 2-15 and the extrusion plates 2-8 can press the powdery medicine into tablets, the pressed tablets can be pushed towards the direction far away from the feeding grooves 1-21 when the sliding conveying blocks 1-8 move, the equipment can dip the pressed tablets into gel coat and automatically output the gel coat, when the threaded shaft a2-7 moves upwards, the threaded shaft a2-7 moves to drive the hinge plate connecting block I3-1 to move downwards under the action of the hinge plate bearing columns 3-3 and the bearing plates 3-4, when the hinged plate I3-5 moves downwards, the moving sliding conveying block 1-8 pushes the medicine pressed into tablets to the sticky material output groove 3-6, the sticky material output groove 3-6 attaches the liquid gel coat in the gel coat box formed by the square cavity of the equipment installation box body 1-22 to the pressed tablets through the micropores on the hinged plate I3-6, when the threaded shaft a2-7 moves in the reverse direction, the hinged plate I3-5 drives the sticky material output groove 3-6 to move in the reverse direction, and the tablet dipped with the gel coat is conveyed to the inclined plate I3-9 under the action of the sliding plate I3-7 and the sliding plate II 3-8 and is inclined out of the equipment through the inclined plate I3-9.

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.