CN113401422B

CN113401422B - Biological macromolecule medicine split charging system

Info

Publication number: CN113401422B
Application number: CN202110821169.3A
Authority: CN
Inventors: 王伟
Original assignee: Lepu Biotechnology Co ltd
Current assignee: Lepu Biotechnology Co ltd
Priority date: 2021-07-20
Filing date: 2021-07-20
Publication date: 2023-07-07
Anticipated expiration: 2041-07-20
Also published as: CN113401422A

Abstract

The invention discloses a biological macromolecule medicine split charging system, which structurally comprises an operation panel, a hopper, a movable grip, a machine body, a power interface and a material guiding device, wherein when the biological macromolecule medicine split charging system is used, the biological macromolecule medicine split charging system is fixedly connected to the machine body through a material receiving groove, a worker holds a material discharging component to pull the material discharging component, a telescopic corrugated pipe can be outwards prolonged under the pulling force, a telescopic hose can be outwards extended along with the extension of the telescopic corrugated pipe, the material discharging component can be used for adjusting the angle position under the cooperation of the telescopic corrugated pipe and the telescopic hose, so that the material discharging component and a medicine bottle can be vertically sleeved together, medicines can be effectively and stably guided into the medicine bottle, and the working strength of the worker is further reduced.

Description

Biological macromolecule medicine split charging system

Technical Field

The invention relates to the technical field of research and development of biological macromolecular drugs, in particular to a split charging system of biological macromolecular drugs.

Background

The biological macromolecular drugs mainly exert the effects of stimulating the immune system of the organism to generate immune substances, generating humoral immunity, cellular immunity or cell-mediated immunity in the human body, and carrying out split charging treatment on the biological macromolecular drugs through split charging equipment so as to facilitate the patients to take the drugs, and adjusting a discharge hole through an adjusting element, wherein when the drugs are split charged, the parts needing improvement are as follows:

when carrying out the partial shipment to the medicine, place the medicine bottle on the discharge gate, inside leading-in medicine bottle of medicine output through the discharge gate, the medicine is in the output process from the discharge gate, because the discharge gate is mostly all in the tilt state for the medicine also needs to be tilt angle with the medicine bottle and connect on the discharge gate when the partial shipment, lead to the staff to need hold the medicine bottle always and carry out spacingly to it, thereby increased staff's working strength, otherwise the medicine bottle receives the impact force of medicine and rolls about, lead to the medicine that the partial shipment was derived to drop outside the medicine bottle.

Disclosure of Invention

Aiming at the defects existing in the prior art, the invention is realized by the following technical scheme: the utility model provides a bio-macromolecule medicine partial shipment system, its structure includes operating panel, hopper, removal handle, organism, power source, guider, operating panel is circular telegram with the organism, be equipped with the hopper that is linked together with it on the organism, the hopper is linked together with guider through the organism, organism one side is equipped with removal handle, power source.

As further optimization of the invention, the material guiding device comprises a material discharging component, a connecting piece, a telescopic hose, a first material receiving groove, a material conveying cavity, an auxiliary traction piece and a telescopic corrugated pipe, wherein the material discharging component is matched with the connecting piece, one end of the connecting piece, which is far away from the material discharging component, is connected with the telescopic corrugated pipe, the inner wall of the telescopic corrugated pipe is connected with the auxiliary traction piece, the telescopic hose and the material conveying cavity are arranged in the telescopic corrugated pipe, and one end of the telescopic corrugated pipe, which is far away from the connecting piece, is communicated with the first material receiving groove.

As a further optimization of the invention, the auxiliary traction piece comprises two fixing blocks, two connectors, screw braces, a positioning seat and an elastic steel plate, wherein the two fixing blocks are fixedly connected to the inner wall of the telescopic corrugated pipe, one end, far away from the telescopic corrugated pipe, of each fixing block is connected with the screw braces, the two screw braces are symmetrically inserted into the connectors, the connectors are fixedly connected with the positioning seat, the positioning seat is connected to the middle position of the elastic steel plate, and two ends of the elastic steel plate are connected to the telescopic corrugated pipe.

As further optimization of the invention, the telescopic corrugated pipe comprises a pipe body, a fiber reinforced layer and a spring, wherein the fiber reinforced layer connected with the pipe body is arranged in the pipe body, the spring is arranged between the fiber reinforced layer and the pipe body, one end of the pipe body is connected to the material receiving groove, the other end of the pipe body is connected to the connecting piece, a telescopic hose and a material conveying cavity are arranged in the pipe body, and the inner wall of the pipe body is connected with a fixed block and an elastic steel plate.

As a further optimization of the invention, the discharging component comprises two air bags, a main body, a connecting port, a second receiving groove, a protecting element and a rotary guide piece, wherein the two air bags are connected to two sides of the inner wall of the second receiving groove, one end of each air bag, which is far away from the second receiving groove, is contacted with the protecting element, the second receiving groove is arranged in the main body, one end of each second receiving groove is communicated with the connecting port, the other end of each second receiving groove is connected with the rotary guide piece, and the connecting port is matched with the connecting piece.

As a further optimization of the invention, the protection element comprises an energy-absorbing soft cushion, a non-sticky sheet and a rubber spacer, wherein the non-sticky sheet is attached to the energy-absorbing soft cushion, one end, far away from the non-sticky sheet, of the energy-absorbing soft cushion is connected to the rubber spacer, two ends of the rubber spacer are connected to the material receiving groove, and the rubber spacer is in contact with the air bag.

As further optimization of the invention, the rotary guide piece comprises a supporting block, a superposition blade, an anti-slip sheet, a butting elastic piece, buckling joints, a deformation port and a disc body, wherein the supporting block and the anti-slip sheet are connected to the outer wall of the disc body, eight buckling joints are arranged on the inner wall of the disc body and are fixedly connected with each other, one end of each buckling joint, which is far away from the disc body, is connected with the butting elastic piece, the butting elastic piece is connected inside the superposition blade in a penetrating way, the superposition blade is provided with eight pieces, the eight superposition blades are connected to the deformation port in an equidistant annular way, and the disc body is connected with the material receiving groove.

As further optimization of the invention, the two rubber spacers are arranged and are clung to two sides of the abutting elastic piece in a curved structure.

As further optimization of the invention, the supporting blocks are provided with a plurality of blocks, the two ends of the supporting blocks are connected with anti-slip sheets, and the anti-slip sheets and the supporting blocks are connected to form an annular structure.

Advantageous effects

The invention relates to a biological macromolecule medicine split charging system, which has the following beneficial effects:

1. according to the invention, through the combined arrangement of the discharging component, the connecting piece, the telescopic hose, the receiving groove, the material conveying cavity, the auxiliary traction piece and the telescopic corrugated pipe, the discharging component is fixedly connected to the machine body through the receiving groove, a worker holds the discharging component to carry out traction, the telescopic corrugated pipe is outwards prolonged by traction force, the telescopic hose is outwards extended along with the extension of the telescopic corrugated pipe, the discharging component can adjust the angle position under the cooperation of the telescopic corrugated pipe and the telescopic hose, the discharging component and the medicine bottle can be vertically sleeved together, and medicines are effectively and stably led into the medicine bottle, so that the working strength of the worker is reduced.

2. According to the invention, through the combination arrangement of the air bag, the main body, the connecting port, the material receiving groove, the protecting element and the rotary guide piece, the connecting port connecting pieces are connected together in an anastomotic way, the medicine bottle is connected to the rotary guide piece, the medicine is guided into the material receiving groove through the connecting port, the medicine can collide with the protecting element after falling into the material receiving groove, the collision force generated by the falling of the medicine is slowed down through the cooperation of the air bag and the protecting element, the medicine is effectively protected, the medicine is assisted to move downwards through the protecting element, and the medicine is effectively guided into the medicine bottle through the rotary guide piece.

Drawings

Other features, objects and advantages of the present invention will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of a system for packaging biological macromolecular drugs according to the present invention;

fig. 2 is a schematic diagram of the internal structure of the material guiding device of the present invention.

Fig. 3 is a schematic view of the internal structure of the auxiliary pulling member of the present invention.

Fig. 4 is a schematic cross-sectional view of the bellows of the present invention.

Fig. 5 is a schematic view of the internal structure of the discharging assembly of the present invention.

Fig. 6 is an enlarged schematic view of the structure of fig. 5 a.

Fig. 7 is a schematic bottom view of a rotary guide according to the present invention.

In the figure: the operation panel 1, the hopper 2, the movable grip 3, the machine body 4, the power interface 5, the material guiding device 6, the material discharging component 61, the connecting piece 62, the telescopic hose 63, the first material receiving groove 64, the material conveying cavity 65, the auxiliary traction piece 66, the telescopic bellows 67, the fixed block 661, the joint 662, the screw brace 663, the positioning seat 664, the elastic steel plate 665, the pipe body 671, the fiber reinforcement layer 672, the spring 673, the air bag 611, the main body 612, the connecting port 613, the second material receiving groove 614, the protection element 615, the rotary guide 616, the energy absorbing cushion 151, the non-stick piece 152, the rubber spacer 153, the supporting block 161, the overlapping blade 162, the non-stick piece 163, the butt joint elastic piece 164, the buckling joint 165, the deformation through hole 166 and the disk body 167.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

Example 1

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a biomacromolecule medicine partial shipment system, its structure includes operating panel 1, hopper 2, removes handle 3, organism 4, power source 5, guide device 6, operating panel 1 is electrified with organism 4 mutually, be equipped with the hopper 2 that is linked together with it on the organism 4, hopper 2 is linked together with guide device 6 through organism 4, organism 4 one side is equipped with removes handle 3, power source 5.

Referring to fig. 2, the material guiding device 6 includes a material discharging component 61, a connecting member 62, a flexible hose 63, a first material receiving groove 64, a material conveying cavity 65, an auxiliary pulling member 66, and a flexible bellows 67, wherein the material discharging component 61 is anastomotic with the connecting member 62, one end of the connecting member 62 away from the material discharging component 61 is connected with the flexible bellows 67, the inner wall of the flexible bellows 67 is connected with the auxiliary pulling member 66, the flexible hose 63 and the material conveying cavity 65 are arranged inside the flexible bellows 67, and one end of the flexible bellows 67 away from the connecting member 62 is communicated with the first material receiving groove 64.

The above-mentioned flexible hose 63 is used for cooperating flexible bellows 67, and flexible bellows 67 can outwards lengthen when receiving the holding-down force, and flexible hose 63 connects at flexible bellows 67, and flexible hose 63 can outwards extend along with the extension of flexible bellows 67 for the angular position of play material subassembly 61 can be adjusted under flexible bellows 67's effect.

Referring to fig. 3, the auxiliary pulling member 66 includes two fixing blocks 661, joints 662, screw braces 663, positioning seats 664 and elastic steel plates 665, the fixing blocks 661 are fixedly connected to the inner wall of the bellows 67, one end of the fixing block 661, far away from the bellows 67, is connected with the screw braces 663, the screw braces 663 are provided with two screw braces 663, the two screw braces 663 are symmetrically inserted into the joints 662, the joints 662 are fixedly connected with the positioning seats 664, the positioning seats 664 are connected to the middle positions of the elastic steel plates 665, and two ends of the elastic steel plates 665 are connected to the bellows 67.

The above-mentioned spiral brace 663 is used for cooperating bellows 67, and bellows 67 can outwards open when outwards extension, and the connection of spiral brace 663 is on bellows 67 for bellows 67 when the extension, spiral brace 663 can hold down bellows 67, and bellows 67 resumes of being convenient for.

Referring to fig. 4, the bellows 67 includes a tube 671, a fiber reinforced layer 672, and a spring 673, the fiber reinforced layer 672 connected to the tube 671 is disposed inside the tube 671, the spring 673 is disposed between the fiber reinforced layer 672 and the tube 671, one end of the tube 671 is connected to the first receiving slot 64, the other end is connected to the connecting member 62, a flexible tube 63 and a material conveying cavity 65 are disposed inside the tube 671, and a fixing block 661 and an elastic steel plate 665 are connected to the inner wall of the tube 671.

The fiber reinforced layer 672 is used for being matched with the pipe body 671, the fiber reinforced layer 672 is used for reinforcing the compact state of the inside of the pipe body 671, the fiber reinforced layer 672 and the spring 673 are mutually matched to support the inside of the pipe body 671, and the pipe body 671 is not easy to deform under the action of external force as a whole.

Example two

Referring to fig. 5, the discharging assembly 61 includes two air bags 611, a main body 612, a connecting port 613, a second receiving slot 614, a protecting element 615, and a rotating guide 616, wherein the two air bags 611 are connected to two sides of the inner wall of the second receiving slot 614, one end of the air bag 611 far away from the second receiving slot 614 is in contact with the protecting element 615, the second receiving slot 614 is disposed inside the main body 612, one end of the second receiving slot 614 is communicated with the connecting port 613, the other end is connected with the rotating guide 616, and the connecting port 613 is matched with the connecting piece 62.

The air bag 611 is used to cooperate with the protection element 615, the medicine falls into the second receiving groove 614, the protection element 615 is connected to the corner of the second receiving groove 614, so that the medicine can collide with the protection element 615 in the falling process, but not be blocked at the corner of the second receiving groove 614, and the air bag 611 cooperates with the protection element 615 to buffer the collision force generated by the falling of the medicine.

Referring to fig. 6, the protection element 615 includes an energy absorbing cushion 151, a non-stick sheet 152, and a rubber spacer 153, the non-stick sheet 152 is attached to the energy absorbing cushion 151, one end of the energy absorbing cushion 151 away from the non-stick sheet 152 is connected to the rubber spacer 153, two ends of the rubber spacer 153 are connected to the second receiving slot 614, and the rubber spacer 153 contacts with the air bag 611.

Referring to fig. 6, two rubber spacers 153 are provided, and the two rubber spacers 153 are tightly attached to two sides of the abutting elastic member 164 in a curved structure.

The non-stick sheet 152 is used to cooperate with the energy-absorbing cushion 151, the drug falls down to strike the non-stick sheet 152, the non-stick sheet 152 has a bionic lotus non-stick effect, so that the drug powder carried by the drug falls down is not easy to adhere to the non-stick sheet 152, and the drug is protected by cooperation of the energy-absorbing cushion 151 and the rubber spacer 153, so that the drug is prevented from being damaged due to collision force generated by falling.

Referring to fig. 7, the rotary guiding element 616 includes a supporting block 161, a lamination blade 162, an anti-slip sheet 163, a butt-joint elastic element 164, a buckling connector 165, a deformation opening 166, and a tray 167, wherein the supporting block 161 and the anti-slip sheet 163 are connected to the outer wall of the tray 167, eight buckling connectors 165 are fixedly connected to the inner wall of the tray 167, one end of the buckling connector 165 far away from the tray 167 is connected to the butt-joint elastic element 164, the butt-joint elastic element 164 is connected inside the lamination blade 162 in a penetrating manner, the lamination blade 162 is provided with eight pieces, the eight lamination blades 162 are connected to the deformation opening 166 in an equidistant annular manner, and the tray 167 is connected to the second receiving slot 614.

Referring to fig. 7, the supporting block 161 is provided with a plurality of supporting blocks, two ends of the plurality of supporting blocks 161 are connected with anti-slip sheets 163, and the two supporting blocks are connected to form an annular structure.

Foretell supporting shoe 161 is used for cooperating antiskid sheet 163, and supporting shoe 161 is triangle-shaped structure, has triangle-shaped's stability, effectively supports antiskid sheet 163, and staff's hand can direct contact rotate on antiskid sheet 163 to disk 167, and antiskid sheet 163 adopts rubber material to make, and the surface is rough state, effectively plays the antiskid effect for staff can not appear the hand phenomenon in rotating disk 167.

The working principle in the technical scheme is described as follows:

when the flexible pipe joint is used, the first receiving groove 64 is fixedly arranged on the machine body 4, the connecting piece 62 is vertically inserted and embedded on the connecting port 613, so that the flexible pipe 67 is communicated with the connecting port 613 under the action of the connecting piece 62, a worker holds the main body 612 by hand to pull out the main body 612, the pipe body 671 can be stretched out by the pulling force conducted by the main body 612, the inside of the pipe 671 is reinforced by the fiber reinforcement layer 672 in the extending process, the inside of the pipe 671 is supported by the mutual matching of the fiber reinforcement layer 672 and the spring 673, the pipe 671 is not easy to deform under the action of external force in the stretching action, after the pipe 671 is stretched out and opened by the stretching action of the pipe 671, the spiral brace 663 can be pulled by the fixing block 661, the joint 662 can drive the positioning seat to move upwards after being pulled by the two spiral braces 663, the elastic steel plate 665 can also move upwards along with the action of the positioning seat 664, the upward movement of the elastic steel plate can become a linear state, the pipe 671 can be effectively stretched out by the fiber reinforcement layer 672, the pipe 671 can be stretched out and the pipe 671 can be stretched out by the stretching force of the pipe 671 along with the stretching force of the pipe 673, and the pipe 671 can be prevented from being stretched out and deformed by the pipe 671 along with the stretching position of the pipe 673;

placing the medicine bottle on the working platform, holding the main body 612 to a certain position by a worker, holding the main body 612 on the tray body 167 to rotate, in the rotating process, enabling the worker to directly contact the anti-slip sheet 163, enabling the worker not to slide in the rotating tray body 167, enabling the worker to rotate the tray body 167 clockwise, enabling the buckling joint 165 to drive the abutting elastic member 164 to rotate along with the tray body 167, enabling the abutting elastic member 164 to pull the overlapping blades 162 while moving, enabling the eight overlapping blades 162 to be overlapped together at the same time, enabling the eight overlapping blades 162 to be fixedly connected on the deformation through hole 166, enabling the caliber of the deformation through hole 166 to be enlarged along with the time when the eight overlapping blades 162 are overlapped together at the same time, enabling the worker to vertically penetrate through the deformation through hole 166, enabling the worker to open the tray body 167, enabling the abutting elastic member 164 to have a rebound effect of a spring, enabling the abutting elastic member 164 to generate a certain degree of rebound force under the condition that the abutting elastic member 164 does not rotate along with the tray body 167, enabling the abutting elastic member 164 to be contracted into the medicine bottle to be stably connected with the medicine bottle by the aid of rolling force, enabling the eight overlapping blades 162 to be contracted into the bottle to be stably deformed by the deformation through hole 166 when the medicine bottle is not required to be compressed by the rotating in the rolling direction;

opening the switch of organism 4, the staff will need the medicine of partial shipment to lead into inside organism 4 through hopper 2, control the adjustment through the output of operation panel 1 to the medicine, it carries first connect the silo 64 to carry medicine ration through organism 4, it is inside to carry material chamber 65 with the stable conduction of medicine through first connect the silo 64, restrict medicine in carrying material chamber 65 inside through flexible hose 63, prevent the medicine card in the department of buckling of flexible bellows 67 in the transportation flow process, make flexible hose 63 can be stable with the medicine lead into second connect the silo 614 inside with medicine in carrying material chamber 65 through connecting piece 62, can collide on the non-sticky piece 152 when the medicine falls in second connect the silo 614 inside, non-sticky piece 152 has the non-sticky effect of lotus, make medicine whereabouts carried powder be difficult for adhering on non-sticky piece 152, the collision force guide that produces medicine whereabouts carries cushion 151 through non-sticky piece 152, energy-absorbing cushion 151 has certain energy-absorbing effect, can cooperate each other with rubber spacer 153 and carry out the absorption force that produces medicine whereabouts to medicine, can make the medicine can be carried out the impact force that makes the medicine and drop down in the shape and make the medicine take shape and make the medicine drop down in the mouth that can be difficult to make the medicine drop down in the hole through the flexible spacer 153, the hole that makes the medicine is difficult to be broken down in the hole 166 is made to the hole in the shape is made to the hole is made to the medicine to be more difficult to the medicine because of the expansion piece 153 is made to be expanded to the air bag is made.

In summary, the novel biological macromolecule medicine split charging system is formed by combining the operation panel, the hopper, the movable handle, the machine body, the power interface and the material guiding device, when the medicines are split charged, the material receiving groove is fixedly connected to the machine body, a worker holds the material discharging assembly to pull the material discharging assembly, the telescopic bellows can be outwards prolonged due to the pulling force, the telescopic hose can be outwards extended along with the extension of the telescopic bellows, the material discharging assembly can be used for adjusting the angle position under the cooperation of the telescopic bellows and the telescopic hose, the material discharging assembly and the medicine bottle can be vertically sleeved together, the medicines can be effectively and stably guided into the medicine bottle, and the working strength of the worker is further reduced.

While the fundamental and principal features of the invention and advantages of the invention have been shown and described, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims

1. The utility model provides a biological macromolecule class medicine partial shipment system, its structure includes operating panel (1), hopper (2), removes handle (3), organism (4), power source (5), guider (6), its characterized in that:

the operation panel (1) is electrified with the machine body (4), the hopper (2) is communicated with the material guiding device (6) through the machine body (4), and a movable grip (3) and a power interface (5) are arranged on one side of the machine body (4);

the material guiding device (6) comprises a material discharging component (61), a connecting piece (62), a telescopic hose (63), a first material receiving groove (64), a material conveying cavity (65), an auxiliary traction piece (66) and a telescopic corrugated pipe (67), wherein the material discharging component (61) is matched with the connecting piece (62), the connecting piece (62) is connected with the telescopic corrugated pipe (67), the telescopic corrugated pipe (67) is connected with the auxiliary traction piece (66), the telescopic hose (63) and the material conveying cavity (65) are arranged on the telescopic corrugated pipe (67), and the telescopic corrugated pipe (67) is communicated with the first material receiving groove (64);

the auxiliary traction piece (66) comprises a fixed block (661), a joint (662), a screw brace (663), a positioning seat (664) and an elastic steel plate (665), wherein the fixed block (661) is fixedly connected to the telescopic corrugated pipe (67), the screw brace (663) is connected to the fixed block (661), the screw brace (663) is inserted into the joint (662), the joint (662) is fixedly connected with the positioning seat (664), the positioning seat (664) is connected to the elastic steel plate (665), and the elastic steel plate (665) is connected to the telescopic corrugated pipe (67);

the telescopic corrugated pipe (67) comprises a pipe body (671), a fiber reinforced layer (672) and a spring (673), wherein the spring (673) is arranged between the fiber reinforced layer (672) and the pipe body (671), the pipe body (671) is connected between a first material receiving groove (64) and a connecting piece (62), the pipe body (671) is provided with a telescopic hose (63) and a material conveying cavity (65), and the pipe body (671) is connected with a fixed block (661) and an elastic steel plate (665);

the discharging assembly (61) comprises an air bag (611), a main body (612), a connecting port (613), a second receiving groove (614), a protection element (615) and a rotary guide piece (616), wherein the air bag (611) is connected to the second receiving groove (614), the air bag (611) is in contact with the protection element (615), the second receiving groove (614) is arranged on the main body (612), the second receiving groove (614) is communicated with the connecting port (613) and the rotary guide piece (616), and the connecting port (613) is matched with the connecting piece (62);

the protective element (615) comprises an energy-absorbing cushion (151), a non-stick sheet (152) and a rubber spacer (153), wherein the non-stick sheet (152) is attached to the energy-absorbing cushion (151), the energy-absorbing cushion (151) is connected to the rubber spacer (153), the rubber spacer (153) is connected to the second receiving groove (614), and the rubber spacer (153) is in contact with the air bag (611);

the rotary guide piece (616) comprises a supporting block (161), a superposition blade (162), an anti-slip piece (163), a butt joint elastic piece (164), a buckling joint (165), a deformation through hole (166) and a disc body (167), wherein the supporting block (161) is connected with the anti-slip piece (163) on the disc body (167), the disc body (167) is fixedly connected with the buckling joint (165), the buckling joint (165) is connected with the butt joint elastic piece (164), the butt joint elastic piece (164) is connected onto the superposition blade (162) in a penetrating manner, the superposition blade (162) is connected onto the deformation through hole (166), and the disc body (167) is connected with a second receiving groove (614);

the rubber spacers (153) are arranged in two, and the two rubber spacers (153) are tightly attached to two sides of the abutting elastic piece (164) in a curved structure.

2. The biomacromolecule drug dispensing system of claim 1, wherein: the supporting block (161) is provided with a plurality of supporting blocks, two ends of the plurality of supporting blocks (161) are connected with anti-slip sheets (163), and the anti-slip sheets are connected to form an annular structure.