CN113733523A

CN113733523A - Health care medicine bottle blowing side cut equipment based on solar energy is supplementary energy-conserving

Info

Publication number: CN113733523A
Application number: CN202111064422.1A
Authority: CN
Inventors: 唐林; 罗红兵; 邱龙江
Original assignee: Guangzhou Liqi Technology Co ltd
Current assignee: Guangzhou Liqi Technology Co ltd
Priority date: 2021-09-10
Filing date: 2021-09-10
Publication date: 2021-12-03
Anticipated expiration: 2041-09-10
Also published as: CN113733523B

Abstract

The invention relates to the technical field of new energy, in particular to solar-assisted energy-saving health-care medicine bottle blow-molding trimming equipment, which comprises an operation cabin, a blow-molding trimming mechanism arranged inside the operation cabin and a solar-assisted mechanism arranged at the top of the operation cabin, wherein the blow-molding trimming mechanism consists of a control table, two groups of blow-molding components, a mold-pressing trimming component and a mechanical arm polishing component.

Description

Health care medicine bottle blowing side cut equipment based on solar energy is supplementary energy-conserving

Technical Field

The invention relates to the technical field of new energy, in particular to solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment.

Background

Health care medicine bottle need use blow molding equipment in actual production process, utilizes the blow molding principle to process production, and general blow molding equipment only possesses the blow molding processing effect, then can't handle the unnecessary rim charge in health care medicine bottle surface after the shaping, and general blow molding equipment is direct with the help of the electric energy operation, and because blow molding equipment power is great, the electric energy waste is obvious. In view of the above, we propose a solar-assisted energy-saving blow-molding edge-cutting device for health-care medicine bottles.

Disclosure of Invention

In order to make up for the defects, the invention provides the solar-assisted energy-saving health-care medicine bottle blow-molding trimming equipment.

The technical scheme of the invention is as follows:

the utility model provides a health care medicine bottle blowing side cut equipment based on energy-conserving is assisted to solar energy, includes the operation storehouse, installs in the inside blowing side cut mechanism of operation storehouse and installs in the solar energy complementary unit at operation storehouse top, blowing side cut mechanism is controlled platform, two sets of blow molding subassembly, mould pressing side cut subassembly and arm and is polished the subassembly and constitute by controlling.

As a preferred technical scheme of the invention, the operation cabin is formed by welding and fixing cabin plates positioned in the front, back, left and right directions and in the bottom surface, a cabin door is installed on the cabin plate positioned in the front side, four rollers which are uniformly distributed are fixedly installed on the cabin plate positioned in the bottom surface through screws, and the control platform, the blow molding assembly, the die pressing edge cutting assembly and the mechanical arm polishing assembly are all fixedly installed on the cabin plate positioned in the bottom surface.

As a preferred technical scheme, the blow molding assembly comprises a base, wherein a front fixing plate is fixedly mounted on the base, a containing cavity is fixedly mounted on the front fixing plate, an injection molding pump is fixedly mounted at the front end of the containing cavity, a transition cavity is mounted on the front side of the injection molding pump, the transition cavity is connected with the injection molding pump through a pipeline, and an injection molding pipe is mounted on the transition cavity.

As a preferred technical scheme, the blow molding assembly further comprises a rear fixing plate fixedly mounted on the base, a molding cavity is mounted on the rear fixing plate, a blow molding air pump is mounted on the rear fixing plate, a pump port of the blow molding air pump is communicated into the molding cavity through a pipeline, and the tail end of the injection molding pipe extends into the molding cavity.

As a preferred technical scheme, the die pressing trimming component comprises a bottom plate, a die pressing platform is fixedly mounted on the bottom plate, four guide columns which are uniformly distributed are also fixedly mounted on the bottom plate, a hydraulic cylinder is fixedly mounted at the top ends of the guide columns, a die pressing block is fixedly mounted at the end part of a piston rod on the hydraulic cylinder, the four guide columns simultaneously penetrate through the die pressing block, the die pressing block can move up and down along the four guide columns, two conveyor belt supporting plates which are parallel to each other are fixedly mounted on one side of the bottom plate, and a conveyor belt for conveying health-care medicine bottles is mounted between the two conveyor belt supporting plates.

As a preferred technical scheme of the invention, the surfaces of the mould pressing platform and the mould pressing block are respectively provided with a plurality of mould grooves, the shapes of the mould pressing blocks are respectively matched with the shapes of the medicine bottles in different placing states, and a circle of mould cutting tools are fixedly arranged on the mould pressing blocks around the notch of each mould groove.

As a preferred technical solution of the present invention, the mechanical arm polishing assembly includes a mounting base, a first driving motor is fixedly mounted on the mounting base, an output shaft of the first driving motor is fixedly connected to a first rotating platform, two first support arms symmetrical to each other are fixedly mounted on the first rotating platform, a second driving motor is fixedly mounted on one of the first support arms, a linking support arm is movably mounted between the two first support arms, an output shaft of the second driving motor is fixedly connected to the linking support arm, two second support arms symmetrical to each other are fixedly mounted at a distal end of the linking support arm, a telescopic hydraulic cylinder is mounted between the second support arm and the first support arm, two ends of the telescopic hydraulic cylinder are respectively movably connected to the second support arm and the first support arm, a driving linking rod is disposed above the linking support arm, the both ends of drive joint pole swing joint have convex arm and back shaft respectively, convex arm fixed mounting is on linking up the support arm, back shaft fixed mounting is between two second support arms, and it has second rotary platform to go back fixed mounting between two second support arms, fixed mounting has third driving motor on the second rotary platform, fixed mounting has the third support arm on third driving motor's the output shaft, fixed mounting has the fourth driving motor on the third support arm, and is equipped with fifth driving motor between the third support arm, the output shaft fixed connection of fifth driving motor and fourth driving motor, just fixed mounting has the head of polishing on fourth driving motor's the output shaft.

As a preferred technical scheme of the invention, the solar auxiliary mechanism is composed of two groups of solar panel components and a solar driving adjusting component which are mutually symmetrical, and the two groups of solar panel components are arranged at the top bin opening of the operation bin.

As a preferred technical scheme of the invention, the solar panel assembly comprises an upper solar panel and a lower solar panel, the lower solar panel is fixedly provided with a bearing block, both sides of the upper solar panel are fixedly provided with side plates, the two sides of the lower solar panel are fixedly provided with slide bars, the bottom surface of the upper solar panel and the front end surface of the lower solar panel are fixedly provided with two mutually symmetrical spring hooks, a spring is connected between the two spring hooks positioned at the same side, each side plate is integrally provided with an arc guide rail bar protruding outwards, the slider is slidably embedded in the arc guide rail bar, the arc guide rail bar is provided with a limiting strip hole penetrating through the arc guide rail bar, each limiting lug is fixedly mounted at a position close to the end part of the slider, and the limiting lug can be slidably arranged in the limiting strip hole.

As a preferable technical scheme of the invention, the solar driving and adjusting component comprises two top supporting bars which are positioned on the same straight line and are both fixed on one of the upper solar panels, the two ends of the top supporting bar are both fixedly provided with hinge shafts, the solar driving adjusting component comprises two hinge bases which are positioned on the same straight line and are both fixed on the other upper solar panel, the hinge shaft is rotatably connected with the hinge seat, a rotating shaft is fixed between the two top supporting bars, a rotating ring is rotatably arranged on the rotating shaft, a top rod is fixedly arranged on the rotating ring, the bottom end of the top rod is fixedly connected with a screw rod, the screw is provided with a rotating wheel supporting plate which is fixed on one of the bin plates, the screw rod passes through the rotating wheel supporting plate, a rotating wheel is further installed on the rotating wheel supporting plate, and the rotating wheel is in threaded connection with the screw rod.

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

1. according to the invention, the blow molding assembly is arranged in the operation bin, so that the injection molding and blow molding operation of the health-care medicine bottle can be realized;

2. according to the invention, the die pressing trimming component is arranged in the operation bin, so that redundant rim charge of the formed health-care medicine bottle can be cut off;

3. according to the invention, the mechanical arm polishing assembly is arranged in the operation bin, so that the surface of the health-care medicine bottle can be finely polished;

4. according to the solar energy power generation system, the solar panel component is arranged on the operation cabin, so that solar energy can be converted into electric energy by virtue of the solar panel, continuous electric energy can be provided for internal electric equipment, energy can be effectively saved, and the effects of energy conservation and environmental protection are achieved;

5. according to the solar energy conversion device, the solar energy driving and adjusting assembly is arranged, so that the solar panel assembly can be unfolded, the sunlight area of the solar panel can be effectively enlarged, the utilization rate of solar energy is improved, and a better electric energy conversion effect is achieved.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic overall exploded view of the present invention;

FIG. 3 is a schematic structural view of an operation cabin of the present invention;

FIG. 4 is a schematic structural view of a blow trimming mechanism according to the present invention;

FIG. 5 is a schematic view of a blow-molded assembly according to the present invention;

FIG. 6 is a schematic view of the die cutting edge assembly of the present invention;

FIG. 7 is a schematic diagram of a robot arm grinding assembly of the present invention;

FIG. 8 is a schematic structural view of a solar assist mechanism according to the present invention;

FIG. 9 is a schematic exploded view of a solar panel assembly according to the present invention;

figure 10 is a bottom view of a solar panel assembly of the present invention;

FIG. 11 is a schematic structural view of a side panel according to the present invention;

FIG. 12 is a schematic view of the structure of the slider of the present invention;

FIG. 13 is a schematic view of a solar driven adjustment assembly according to the present invention;

FIG. 14 is a cross-sectional view of the sanding head of the present invention;

fig. 15 is an exploded view of the sanding head and tubing of the present invention.

In the figure:

the device comprises an operation cabin 1, a cabin plate 11, a cabin door 12 and rollers 13;

a blow molding trimming mechanism 2;

a console 21;

blow-molding assembly 22, base 221, front retaining plate 222, receiving cavity 223, injection pump 224, transition cavity 225, injection tube 226, rear retaining plate 227, blow air pump 229;

the die cutting edge assembly 23, the bottom plate 231, the die pressing platform 232, the guide column 233, the hydraulic cylinder 234, the die pressing block 235, the conveyor belt supporting plate 236 and the conveyor belt 237;

the mechanical arm grinding assembly 24, the mounting base 241, the first driving motor 242, the first rotating platform 243, the first supporting arm 244, the second driving motor 245, the engaging supporting arm 246, the second supporting arm 247, the telescopic hydraulic cylinder 248, the driving engaging rod 249, the convex arm 2410, the supporting shaft 2411, the second rotating platform 2412, the third driving motor 2413, the third supporting arm 2414, the fourth driving motor 2415, the fifth driving motor 2416, the grinding head 2417, the annular groove 24171, the water-cooling channel 24172, the first pipeline 24173, the second pipeline 24174, the convex ring 24175, the annular pipeline 24176, the concave annular groove 24177, the water-cooling liquid tank 2418 and the water pump 2419;

a solar assist mechanism 3;

the solar panel assembly 31, the upper solar panel 311, the lower solar panel 312, the bearing block 313, the side plate 314, the slide bar 315, the spring hook 316, the spring 317, the arc-shaped guide rail bar 318, the limit strip-shaped hole 319 and the limit bump 3110;

the solar energy drives adjusting component 32, the top support bar 321, the hinge 322, the hinge 323, the rotating shaft 324, the swivel 325, the top rod 326, the screw 327, the wheel support plate 328, the wheel 329.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Referring to fig. 1-15, the present invention provides a technical solution:

the utility model provides a health care medicine bottle blowing side cut equipment based on energy-conserving supplementary of solar energy, includes operation storehouse 1, installs in the inside blowing side cut mechanism 2 of operation storehouse 1 and installs in the solar energy complementary unit 3 at operation storehouse 1 top, and blowing side cut mechanism 2 comprises platform 21, two sets of blow molding subassembly 22, mould pressing side cut subassembly 23 and the arm subassembly 24 of polishing.

The solar energy auxiliary mechanism 3 generates electricity and stores the electricity in the storage battery pack, the electricity is converted into alternating current through the inverter and used for supplying power to all electrical appliances of the blow molding edge cutting equipment, meanwhile, a plug used for being connected with a common alternating current socket is arranged on the control table 21, the electricity can be switched into common electricity and storage battery electricity through the power supply change-over switch, and when the electricity in the storage battery pack is insufficient in rainy days for a long time, the electricity is switched into common electricity and is used indoors.

As a preferred technical solution of this embodiment, the operation cabin 1 is formed by welding and fixing cabin plates 11 located in the front, back, left, right, and bottom directions, a cabin door 12 is installed on the cabin plate 11 located in the front side, four rollers 13 evenly distributed are fixedly installed on the cabin plate 11 located in the bottom through screws, and the console 21, the blow molding assembly 22, the die pressing trimming assembly 23, and the mechanical arm polishing assembly 24 are all fixedly installed on the cabin plate 11 located in the bottom.

As a preferred technical solution of this embodiment, the blow molding assembly 22 includes a base 221, a front fixing plate 222 is fixedly mounted on the base 221, a receiving cavity 223 is fixedly mounted on the front fixing plate 222, an injection pump 224 is fixedly mounted at the front end of the receiving cavity 223, a transition cavity 225 is mounted at the front side of the injection pump 224, the transition cavity 225 and the injection pump 224 are connected by a pipeline, and an injection pipe 226 is mounted on the transition cavity 225; the accommodating cavity 223 is used for accommodating and storing molten plastic, the injection pump 224 is used for pumping out the molten plastic in the accommodating cavity 223, during use, the molten plastic is injected into the accommodating cavity 223, and the injection pump 224 is started to pump out the molten plastic and inject the molten plastic into the transition cavity 225 through a pipeline.

As a preferred technical solution of this embodiment, the blow molding assembly 22 further includes a rear fixing plate 227 fixedly installed on the base 221, the rear fixing plate 227 is installed with a molding cavity 228, the rear fixing plate 227 is installed with a blow molding air pump 229, a pump port of the blow molding air pump 229 is communicated to the molding cavity 228 through a pipeline, and a terminal end of the injection molding pipe 226 extends into the molding cavity 228, in a using process, the blow molding air pump 229 is turned on, and compressed air generated by the blow molding air pump 229 is blown into the molding cavity 228 through a pipeline, so that the molten plastic is blown to cling to an inner wall of the molding cavity 228, thereby completing the blow molding.

As a preferred technical solution of this embodiment, the die stamping edge cutting assembly 23 includes a bottom plate 231, a die stamping platform 232 is fixedly installed on the bottom plate 231, four guide posts 233 which are uniformly distributed are also fixedly installed on the bottom plate 231, a hydraulic cylinder 234 is fixedly installed at the top ends of the guide posts 233, a die stamping block 235 is fixedly installed at the end portion of a piston rod on the hydraulic cylinder 234, the four guide posts 233 simultaneously pass through the die stamping block 235, the die stamping block 235 can move up and down along the four guide posts 233, two conveyor belt supporting plates 236 which are parallel to each other are fixedly installed at one side of the bottom plate 231, a conveyor belt 237 for conveying bottles of health care medicines is installed between the two conveyor belt supporting plates 236, in use, the bottles of health care medicines are placed on the conveyor belt 237 and conveyed to the die stamping platform 232 through the conveyor belt 237, the bottles of health care medicines are manually placed in different die slots, the hydraulic cylinder 234 is started to push the die stamping block 235 to move down, the vial is held in place between the molded block 235 and the molded platform 232.

As an optimal technical scheme of this embodiment, the surface of mould pressing platform 232 and mould pressing piece 235 all is equipped with a plurality of die-cut grooves, each mould pressing piece 235 respectively with the medicine bottle shape under the different state of placing coincide each other, and all fixed mounting has a round die-cutting tool around the notch that lies in every die-cut groove on the mould pressing piece 235, the peripheral die-cutting tool in die-cut groove can be amputated the unnecessary rim charge in surface of health care medicine bottle, and through the setting in multiple die-cut groove, can carry out the placing of different angles with health care medicine bottle to can excise the unnecessary rim charge on each position of health care medicine bottle.

As a preferred technical solution of this embodiment, the mechanical arm grinding assembly 24 includes a mounting base 241, a first driving motor 242 is fixedly mounted on the mounting base 241, an output shaft of the first driving motor 242 is fixedly connected with a first rotating platform 243, two first supporting arms 244 which are symmetrical to each other are fixedly mounted on the first rotating platform 243, a second driving motor 245 is fixedly mounted on one of the first supporting arms 244, a linking supporting arm 246 is movably mounted between the two first supporting arms 244, an output shaft of the second driving motor 245 is fixedly connected with the linking supporting arm 246, two second supporting arms 247 which are symmetrical to each other are fixedly mounted at a distal end of the linking supporting arm 246, a telescopic hydraulic cylinder 248 is mounted between the second supporting arm 247 and the first supporting arm 244, two ends of the telescopic hydraulic cylinder 248 are respectively movably connected with the second supporting arm 247 and the first supporting arm 244, a driving connecting rod 249 is arranged above the connecting supporting arms 246, two ends of the driving connecting rod 249 are respectively movably connected with a convex arm 2410 and a supporting shaft 2411, the convex arm 2410 is fixedly arranged on the connecting supporting arms 246, the supporting shaft 2411 is fixedly arranged between the two second supporting arms 247, a second rotating platform 2412 is also fixedly arranged between the two second supporting arms 247, a third driving motor 2413 is fixedly arranged on the second rotating platform 2412, a third supporting arm 2414 is fixedly arranged on an output shaft of the third driving motor 2413, a fourth driving motor 2415 is fixedly arranged on the third supporting arm 2414, a fifth driving motor 2416 is arranged between the third supporting arms 2414, the fifth driving motor 2416 is fixedly connected with an output shaft of the fourth driving motor 2415, a polishing head 2417 is fixedly arranged on an output shaft of the fourth driving motor 2416, the first driving motor 242 can drive the first rotating platform 243 to rotate, the second driving motor 245 can drive the connecting supporting arms 246 to rotate, the telescopic hydraulic cylinder 248 can drive the second support arm 247 to swing, thereby driving the third support arm 2414 to swing, the third driving motor 2413 can drive the third support arm 2414 to rotate, the fourth driving motor 2415 can drive the fourth driving motor 2416 to rotate and the polishing head 2417 to swing longitudinally, the fourth driving motor 2416 can drive the polishing head 2417 to rotate, the whole mechanical arm polishing assembly 24 can swing freely in a plurality of different planes by the driving mode, thereby facilitating the polishing head 2417 on the mechanical arm polishing assembly 24 to polish the health-care medicine bottles in an all-round manner.

In the improvement of other embodiments, the polishing head 2417 polishes the bottle body through the outer edge thereof, when the top edge of the bottle mouth needs to be polished and trimmed due to the special shape of the bottle mouth, the embodiment is further improved, the bottom of the polishing head 2417 is provided with an annular groove 24171 which is consistent with the shape of the bottle mouth, wherein the bottle is easy to deform due to overhigh temperature caused by friction during polishing and trimming, on the basis, the embodiment is provided with a spiral water cooling channel 24172 between the annular groove 24171 and the outer edge of the polishing head 2417, two sides of the upper part of the water cooling channel 24172 are respectively provided with a water hole, a water cooling liquid tank 2418 is arranged inside the third supporting arm 2414, a water pump 2419 is arranged on the bottom surface inside the water cooling liquid tank 2418, the water outlet of the water pump 2419 is communicated with one of the water holes through a first pipeline 73, the water cooling liquid tank 2418 is communicated with the other water hole through a second pipeline 24174, water in the water cooling liquid tank 2418 is circulated through the spiral water cooling channel 24172 through the water pump 2419, so that the temperature of the polishing head 2417 during polishing is not too high. However, considering that the polishing head 2417 rotates rapidly during polishing, and the first and second pipes 24173 and 24174 cannot be twisted together with the first and second pipes, the inventor has made a design in which the outer circumferential wall of the polishing head 2417 is provided with a convex ring 24175, and outlets of the two water holes extend out of the convex ring 24175, as shown in fig. 15. Meanwhile, the end parts of the first pipeline 24173 and the second pipeline 24174 are connected with and communicated with the annular pipeline 24176, the inner wall of the annular pipeline 24176 is provided with a concave ring groove 24177, the outlets of the first pipeline 24173 and the second pipeline 24174 are both arranged on the concave ring groove 24177, the convex ring 24175 is embedded in the concave ring groove 24177, the upper surface and the lower surface of the convex ring 24175 are tightly attached to each other and can rotate, a gap is reserved between the outer wall of the convex ring 24175 and the inner wall of the concave ring groove 24177 for the circulation of the cooling liquid, so that the concave ring groove 24177 and the convex ring 24175 are polished smooth and then used by adding lubricating oil, and under the centrifugal force when the polishing head 2417 rotates at a high speed, the cooling liquid in the spiral water cooling channel 24172 is continuously exchanged with the cooling liquid in the gap, and the conduction of the cooling liquid can be realized while the relative rotation is realized. It should be noted that the first and second conduits 24173 and 24174 are flexible conduits, and can be driven by the fourth driving motor 2415 to swing in the longitudinal direction.

As a preferred technical solution of this embodiment, the solar auxiliary mechanism 3 is composed of two sets of solar panel elements 31 and solar driving adjustment elements 32 which are symmetrical to each other, and the two sets of solar panel elements 31 are put on the top hatch of the operation hatch 1.

As a preferred technical solution of this embodiment, the solar panel assembly 31 includes an upper solar panel 311 and a lower solar panel 312, a bearing block 313 is fixedly installed on the lower solar panel 312, side plates 314 are fixedly installed on both sides of the upper solar panel 311, slide bars 315 are fixedly installed on both sides of the lower solar panel 312, two symmetrical spring hooks 316 are fixedly installed on the bottom surface of the upper solar panel 311 and the front end surface of the lower solar panel 312, a spring 317 is connected between the two spring hooks 316 located on the same side, an outwardly protruding arc-shaped guide rail bar 318 is integrally formed on each side plate 314, the slide bars 315 are slidably embedded in the arc-shaped guide rail bar 318, a limiting strip hole 319 penetrating through the arc-shaped guide rail bar 318 is arranged on the arc-shaped guide rail bar 318, a limiting bump 3110 is fixedly installed on a position on each slide bar 315 near an end portion, the limiting bump 3110 is slidably arranged in the limiting strip hole 319, bearing block 313's setting, can realize when last solar panel 311 slopes, solar panel 312 removes to expand under the pulling, spring 317's setting, can realize being in under the horizontality at last solar panel 311, can pull back solar panel 312 down and reset, setting of draw bar 315 cooperation arc guide rail strip 318, can guarantee down solar panel 312 along rectilinear movement all the time, cooperation through spacing lug 3110 and spacing bar hole 319 is used, can produce spacing effect to solar panel 312 down, avoid it to break away from with last solar panel 311 completely.

It should be noted that, the two side edges of the upper solar panel 311 are hinged to the bin plate 11 near the peripheral edge, so as to ensure that the upper solar panel 311 can be pushed to swing and tilt during the jacking process of the jacking rod 326.

As a preferable technical solution of this embodiment, the solar driving adjustment assembly 32 includes two top supporting bars 321 located on the same straight line and fixed on one of the upper solar panels 311, two ends of the top supporting bars 321 are both fixedly installed with hinge shafts 322, the solar driving adjustment assembly 32 includes two hinge seats 323 located on the same straight line and fixed on the other upper solar panel 311, the hinge shafts 322 and the hinge seats 323 are rotatably connected, a rotating shaft 324 is fixed between the two top supporting bars 321, a rotating ring 325 is rotatably installed on the rotating shaft 324, a top rod 326 is fixedly installed on the rotating ring 325, a screw 327 is fixedly connected to a bottom end of the top rod 326, a rotating wheel supporting plate 328 is installed on the screw 327, the rotating wheel supporting plate 328 is fixed on one of the bin plates 11, the screw 327 passes through the rotating wheel supporting plate 328, a rotating wheel 329 is also installed on the rotating wheel supporting plate 328, and the rotating wheel 329 and the screw 327 are connected with each other by a thread, the hinge shaft 322 is matched with the hinge seat 323, so that the two upper solar panels 311 can be movably hinged, in the using process, the rotating wheel 329 is rotated, the rotating wheel 329 is in threaded connection with the screw 327, and the screw 327 is fixedly connected with the top rod 326, so that the screw 327 is pushed to move upwards while the rotating wheel 329 rotates, the top rod 326 can be pushed to move upwards, the top rod 326 moves upwards to push the rotating ring 325 to synchronously move upwards, the rotating shaft 324 and the top supporting strip 321 are pushed to move upwards, the upper solar panels 311 on two sides can be pushed to incline, the lower solar panel 312 can be driven to incline, and the lower solar panel 312 is pulled to move and expand under the action of the gravity of the bearing block 313.

In the specific using process, injecting the molten plastic into the accommodating cavity 223, starting the injection pump 224 to pump out the molten plastic, injecting the molten plastic into the transition cavity 225 through a pipeline, injecting the molten plastic into the molding cavity 228 through the injection pipe 226, then opening the blow molding air pump 229, blowing compressed air generated by the blow molding air pump 229 into the molding cavity 228 through a pipeline, so that the molten plastic is blown to cling to the inner wall of the molding cavity 228 to complete blow molding, after the blow molding is completed, closing the injection pump 224 and the blow molding air pump 229, opening the accommodating cavity 223 after the molten plastic is completely cooled, taking out a primarily molded health-care medicine bottle, then placing the health-care medicine bottle on a conveyor belt 237, conveying the health-care medicine bottle to a mold pressing platform 232 through the conveyor belt 237, manually placing the health-care medicine bottle in different mold grooves, starting the hydraulic cylinder 234 to push the mold pressing block 235 to move downwards, clamping and fixing the health-care medicine bottle between the mold pressing block 235 and the mold pressing platform 232, in the process, the die cutting tool at the periphery of the model groove can cut off redundant rim charge on the surface of the health care medicine bottle, then the mechanical arm polishing component 24 is started, the mechanical arm polishing component 24 can rotate in different directions through the first driving motor 242, the second driving motor 245, the telescopic hydraulic cylinder 248, the third driving motor 2413, the fourth driving motor 2415 and the fifth driving motor 2416 on the mechanical arm polishing component 24, so that the polishing head 2417 on the mechanical arm polishing component can rotate in different directions, through the arrangement, the fine polishing treatment on the surface of the health care medicine bottle can be realized, the electric energy required by the blow molding component 22 and the mould pressing edge cutting component 23 can be provided by the solar auxiliary mechanism 3, in the actual operation process, the solar panel arranged on the operation bin 1 can continuously generate electric energy only by pushing the operation bin 1 out of the room to receive sunlight irradiation, moreover, can also expand solar energy complementary unit 3 to increase its sunny area, improve the utilization ratio of solar energy, concrete operation is: the rotating wheel 329 is rotated, because the rotating wheel 329 is in threaded connection with the screw 327, and because the screw 327 is fixedly connected with the top rod 326, the rotating wheel 329 is rotated, the screw 327 is pushed to move upwards, so that the top rod 326 can be pushed to move upwards, the rotating ring 325 is pushed to move upwards synchronously by the upward movement of the top rod 326, so that the rotating shaft 324 and the top supporting bars 321 are pushed to move upwards, so that the upper solar panels 311 on two sides can be pushed to incline, because the sliding strips 315 on the lower solar panels 312 can move in the arc-shaped guide track strips 318 on the upper solar panels 311, in the process of inclining the upper solar panels 311, the lower solar panels 312 can be pulled to move downwards and expand under the action of the gravity of the bearing blocks 313, and because of the arrangement of the limiting convex blocks 3110 and the limiting strip-shaped holes 319, the limiting effect can be generated on the lower solar panels 312, so as to avoid the complete separation of the upper solar panels 311, and through the complete expansion of the lower solar panels 312, the area of the solar panels can be effectively increased, when the solar panel is not needed to be used, the rotating wheel 329 is rotated reversely to drive the upper solar panel 311 to rotate to a horizontal state, and after the horizontal state is reached, the lower solar panel 312 is pulled to automatically reset under the action of the elastic force of the spring 317 due to the loss of the gravity action of the bearing block 313 and is overlapped with the upper solar panel 311 again.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the preferred embodiments of the present invention are described in the above embodiments and the description, and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a health care medicine bottle blowing side cut equipment based on solar energy is supplementary energy-conserving, includes operation storehouse (1), installs in inside blowing side cut mechanism (2) of operation storehouse (1) and installs in solar energy complementary unit (3) at operation storehouse (1) top, its characterized in that: the blow molding trimming mechanism (2) is composed of a control platform (21), two groups of blow molding forming assemblies (22), a die pressing trimming assembly (23) and a mechanical arm polishing assembly (24).

2. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 1, wherein: operation storehouse (1) is by being located all around and five ascending storehouse boards (11) welded fastening in bottom surface constitute, is located the front side install door (12) on storehouse board (11), be located storehouse board (11) of bottom surface and go up through screw fixed mounting have four evenly distributed's gyro wheel (13), control platform (21), blow molding subassembly (22), mould pressing side cut subassembly (23) and arm and polish equal fixed mounting of subassembly (24) on storehouse board (11) that are located the bottom surface.

3. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 1, wherein: blow molding subassembly (22) includes base (221), fixed mounting has preceding fixed plate (222) on base (221), fixed mounting has on preceding fixed plate (222) and holds chamber (223), the front end fixed mounting who holds chamber (223) has injection pump (224), excessive chamber (225) are installed to the front side of injection pump (224), pass through pipe connection between excessive chamber (225) and injection pump (224), and install on excessive chamber (225) and mould plastics pipe (226).

4. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 1, wherein: the blow molding assembly (22) further comprises a rear fixing plate (227) fixedly mounted on the base (221), a molding cavity (228) is mounted on the rear fixing plate (227), a blow molding air pump (229) is mounted on the rear fixing plate (227), a pump port of the blow molding air pump (229) is communicated into the molding cavity (228) through a pipeline, and the tail end of the injection molding pipe (226) extends into the molding cavity (228).

5. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 1, wherein: mould pressing side cut subassembly (23) includes bottom plate (231), fixed mounting has mould pressing platform (232) on bottom plate (231), still fixed mounting has four evenly distributed guide post (233) on bottom plate (231), the top fixed mounting of guide post (233) has pneumatic cylinder (234), piston rod end fixed mounting on pneumatic cylinder (234) has moulded piece (235), four guide post (233) pass moulded piece (235) simultaneously, and moulded piece (235) can reciprocate along four guide post (233), one side fixed mounting of bottom plate (231) has two conveyer belt backup pad (236) that are parallel to each other, two install conveyer belt (237) that are used for transporting health care medicine bottle between conveyer belt backup pad (236).

6. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 5, wherein: the surface of mould pressing platform (232) and mould pressing piece (235) all is equipped with a plurality of die-cut grooves, and each mould pressing piece (235) is identical to each other with the shape of medicine bottle under the different states of placing respectively, and all fixed mounting has a round of cross cutting cutter around the notch that lies in every die-cut groove on mould pressing piece (235).

7. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 1, wherein: the mechanical arm polishing assembly (24) comprises an installation base (241), a first driving motor (242) is fixedly installed on the installation base (241), an output shaft of the first driving motor (242) is fixedly connected with a first rotating platform (243), two first supporting arms (244) which are symmetrical to each other are fixedly installed on the first rotating platform (243), a second driving motor (245) is fixedly installed on one of the first supporting arms (244), a linking supporting arm (246) is movably installed between the two first supporting arms (244), an output shaft of the second driving motor (245) is fixedly connected with the linking supporting arm (246), two second supporting arms (247) which are symmetrical to each other are fixedly installed at the tail end of the linking supporting arm (246), and a telescopic hydraulic cylinder (248) is installed between the second supporting arm (247) and the first supporting arm (244), two ends of the telescopic hydraulic cylinder (248) are respectively movably connected with the second supporting arm (247) and the first supporting arm (244), a driving connecting rod (249) is arranged above the connecting supporting arm (246), two ends of the driving connecting rod (249) are respectively movably connected with a convex arm (2410) and a supporting shaft (2411), the convex arm (2410) is fixedly installed on the connecting supporting arm (246), the supporting shaft (2411) is fixedly installed between the two second supporting arms (247), a second rotating platform (2412) is further fixedly installed between the two second supporting arms (247), a third driving motor (2413) is fixedly installed on the second rotating platform (2412), a third supporting arm (2414) is fixedly installed on an output shaft of the third driving motor (2413), and a fourth driving motor (2415) is fixedly installed on the third supporting arm (2414), and a fifth driving motor (2416) is arranged between the third supporting arms (2414), the output shafts of the fifth driving motor (2416) and the fourth driving motor (2415) are fixedly connected, and a polishing head (2417) is fixedly installed on the output shaft of the fourth driving motor (2416).

8. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 1, wherein: the solar auxiliary mechanism (3) is composed of two groups of mutually symmetrical solar panel components (31) and a solar driving adjusting component (32), and the two groups of solar panel components (31) are arranged at the top bin opening of the operation bin (1).

9. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 8, wherein: the solar panel component (31) comprises an upper solar panel (311) and a lower solar panel (312), a bearing block (313) is fixedly mounted on the lower solar panel (312), side plates (314) are fixedly mounted on both sides of the upper solar panel (311), sliders (315) are fixedly mounted on both sides of the lower solar panel (312), two mutually symmetrical spring hooks (316) are fixedly mounted on the bottom surface of the upper solar panel (311) and the front end surface of the lower solar panel (312), springs (317) are connected between the two spring hooks (316) positioned on the same side, an outwards convex arc guide rail bar (318) is integrally formed on each side plate (314), the sliders (315) are embedded in the arc guide rail bar (318) in a sliding manner, and a limit bar-shaped hole (319) penetrating through the arc guide rail bar (318) is formed in the arc guide rail bar (318), every the equal fixed mounting in position that is close to the tip on draw runner (315) has spacing lug (3110), spacing lug (3110) slidable locates in spacing shape hole (319).

10. The solar-assisted energy-saving health-care medicine bottle blow-molding edge-cutting equipment as claimed in claim 8, wherein: solar drive adjusting part (32) include that two are located same straight line and all are fixed in top support strip (321) on one of them last solar panel (311), the equal fixed mounting in both ends of top support strip (321) has hinge (322), solar drive adjusting part (32) include that two are located same straight line and all are fixed in hinge (323) on another last solar panel (311), rotate between hinge (322) and hinge (323) and connect, two be fixed with pivot (324) between top support strip (321), rotatable change (325) of installing in pivot (324), fixed mounting has ejector pin (326) on change (325), the bottom fixedly connected with screw rod (327) of ejector pin (326), be equipped with backup pad (328) on screw rod (327), change wheel backup pad (328) are fixed on one of them barn door (11), the screw rod (327) penetrates through the rotating wheel supporting plate (328), the rotating wheel (329) is further installed on the rotating wheel supporting plate (328), and the rotating wheel (329) is in threaded connection with the screw rod (327).