CN112140580A - Pre-invasion material winding propeller manufacturing equipment - Google Patents

Pre-invasion material winding propeller manufacturing equipment Download PDF

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Publication number
CN112140580A
CN112140580A CN202011074065.2A CN202011074065A CN112140580A CN 112140580 A CN112140580 A CN 112140580A CN 202011074065 A CN202011074065 A CN 202011074065A CN 112140580 A CN112140580 A CN 112140580A
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shaft
plate
connecting plate
connection
linkage
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CN202011074065.2A
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Chinese (zh)
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韩力
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C70/00Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts
    • B29C70/04Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts comprising reinforcements only, e.g. self-reinforcing plastics
    • B29C70/28Shaping operations therefor
    • B29C70/30Shaping by lay-up, i.e. applying fibres, tape or broadsheet on a mould, former or core; Shaping by spray-up, i.e. spraying of fibres on a mould, former or core
    • B29C70/32Shaping by lay-up, i.e. applying fibres, tape or broadsheet on a mould, former or core; Shaping by spray-up, i.e. spraying of fibres on a mould, former or core on a rotating mould, former or core
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C35/00Heating, cooling or curing, e.g. crosslinking or vulcanising; Apparatus therefor
    • B29C35/02Heating or curing, e.g. crosslinking or vulcanizing during moulding, e.g. in a mould
    • B29C35/04Heating or curing, e.g. crosslinking or vulcanizing during moulding, e.g. in a mould using liquids, gas or steam
    • B29C35/045Heating or curing, e.g. crosslinking or vulcanizing during moulding, e.g. in a mould using liquids, gas or steam using gas or flames
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C70/00Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts
    • B29C70/04Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts comprising reinforcements only, e.g. self-reinforcing plastics
    • B29C70/28Shaping operations therefor
    • B29C70/54Component parts, details or accessories; Auxiliary operations, e.g. feeding or storage of prepregs or SMC after impregnation or during ageing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29LINDEXING SCHEME ASSOCIATED WITH SUBCLASS B29C, RELATING TO PARTICULAR ARTICLES
    • B29L2031/00Other particular articles
    • B29L2031/08Blades for rotors, stators, fans, turbines or the like, e.g. screw propellers
    • B29L2031/087Propellers

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Composite Materials (AREA)
  • Mechanical Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Health & Medical Sciences (AREA)
  • Oral & Maxillofacial Surgery (AREA)
  • Thermal Sciences (AREA)
  • Devices For Conveying Motion By Means Of Endless Flexible Members (AREA)

Abstract

The invention relates to propeller manufacturing equipment, in particular to pre-immersed material wound propeller manufacturing equipment which comprises a winding mechanism, a heating mechanism and an output mechanism, wherein the equipment can clamp a propeller core, pre-immersed material fiber yarns can be wound on the propeller core, the equipment can convey a wound propeller to an electric heater, the equipment can heat the wound propeller to melt and level glue in the pre-immersed material, the equipment can automatically output the propeller to an inclined plate, the winding mechanism is connected with the heating mechanism, the heating mechanism is connected with the output mechanism, and the output mechanism is connected with the winding mechanism.

Description

Pre-invasion material winding propeller manufacturing equipment
Technical Field
The invention relates to propeller manufacturing equipment, in particular to propeller manufacturing equipment for winding a pre-impregnated material.
Background
When the propeller is manufactured, the process is complex, the large-batch production is not facilitated, and no good propeller manufacturing equipment is available in the market, so that the propeller manufacturing equipment for winding the pre-invaded material is designed.
Disclosure of Invention
The invention mainly solves the technical problem of providing equipment for manufacturing a pre-immersed material wound propeller, the equipment can clamp a propeller core, pre-immersed material fiber yarns can be wound on the propeller core, the equipment can convey the wound propeller to an electric heater, the equipment can heat the wound propeller to melt glue in the pre-immersed material and level the glue, and the equipment can automatically output the propeller to an inclined plate.
In order to solve the technical problems, the invention relates to propeller manufacturing equipment, in particular to pre-immersed material winding propeller manufacturing equipment which comprises a winding mechanism, a heating mechanism and an output mechanism, wherein the equipment can clamp a propeller core, pre-immersed material fiber yarns can be wound on the propeller core, the equipment can convey the wound propeller to an electric heater, the equipment can heat the wound propeller to melt and level glue in the pre-immersed material, and the equipment can automatically output the propeller to an inclined plate.
The winding mechanism is connected with the heating mechanism, the heating mechanism is connected with the output mechanism, and the output mechanism is connected with the winding mechanism.
As a further optimization of the technical scheme, the invention relates to equipment for manufacturing a pre-invaded wound propeller, which comprises a connecting plate a, a connecting plate b, a connecting plate c, a connecting plate d, a connecting plate e, a connecting plate f, a motor shaft, a belt, a transmission shaft, a friction wheel, a transmission shaft a, a connecting plate g, a ball shaft a, a rotating plate, a rotating connecting block, a rotating ring, a rotating fluctuation strip, a ball shaft b, a connecting shaft, a ball shaft c, a ball shaft d, a limiting triangle, a limiting plate, a limiting spring, a limiting sliding shaft, a limiting shaft sleeve, a hinge strip, a sliding groove, a connecting plate h, a connecting shaft a, a connecting plate j, a winding shaft, a pre-invaded fiber wire, a connecting plate i, a pre-invaded fiber wire connecting point, a fiber wire groove, a propeller core, a pressing shaft, a pressing pull handle, a pressing spring limiting, the connecting plate a is connected with a connecting plate b, the connecting plate a is connected with a rotating wave sliding strip in a sliding mode, the connecting plate b is connected with a connecting plate c, the connecting plate b is connected with a connecting plate e, the connecting plate b is connected with a connecting plate b, the connecting plate b is connected with a connecting plate k, the connecting plate c is connected with a connecting plate d, the connecting plate d is connected with a connecting plate e, the connecting plate d is connected with a connecting plate f, the connecting plate d is connected with a connecting plate g, the connecting plate d is connected with a connecting plate k, the connecting plate d is connected with a connecting plate l, the connecting plate e is connected with a rotating wave sliding strip in a sliding mode, the connecting plate e is connected with a connecting plate f, the motor is connected with a motor shaft, the motor is connected with the, the transmission shaft a is connected with the connecting plate g in a sliding manner, the transmission shaft a is connected with the ball shaft a in a sliding manner, the transmission shaft a is connected with the ball shaft d, the groove on the transmission shaft a is connected with the limiting shaft sleeve bearing, the ball shaft a is connected with the rotating plate bearing, the rotating plate is connected with the rotating connecting block, the rotating plate is connected with the rotating ring in a sliding manner, the rotating ring is connected with the rotating fluctuation strip, the ball shaft b is connected with the rotating plate bearing, the ball shaft b is connected with the connecting shaft, the connecting shaft is connected with the ball shaft c, the ball shaft c is connected with the connecting plate i bearing, the limiting triangle is connected with the limiting plate, the limiting plate is connected with the limiting sliding shaft, the limiting spring is sleeved on the limiting sliding shaft and limited on the limiting plate and the sliding groove, the limiting sliding shaft is connected with the sliding groove, the limiting shaft, connecting plate h is connected with connecting plate i, connecting axle an is connected with connecting plate j, connecting plate j with invade material cellosilk sliding connection in advance, the winding axle is connected with connecting plate h bearing, invade material cellosilk winding in advance and be connected between two connecting plates j through the hole on connecting plate i and the hole on connecting plate j on the winding axle, the cellosilk groove is opened on external thread post, oppression axle and oppression spring spacing connection, oppression axle and connecting plate k sliding connection, oppression handle and oppression axle are connected, oppression spring housing is epaxial and spacing in oppression spring spacing and connecting plate k, connecting plate k is connected with connecting plate l, external thread post and ball D threaded connection, external thread post and transmission shaft a bearing are connected.
As a further optimization of the technical scheme, the invention relates to a manufacturing device of a pre-invaded material winding propeller, wherein a heating mechanism comprises a heating motor, a heating motor shaft, a mounting plate, a connecting belt a, a linkage shaft a, a connecting belt b, a linkage shaft b, a connecting belt c, a linkage friction wheel, a connecting belt d, a linkage shaft c, a linkage friction wheel a, a linkage shaft d, a thread extension shaft, a tension spring connecting plate, a connecting belt e, a linkage shaft e, a mounting plate b, a linkage friction wheel b, a rotating ring, a fixed ring connecting strip, an electric heating plate, a ring body connecting block, a fixed connecting ring and a fan blade, the heating motor is connected with the heating motor shaft which is connected with a mounting plate bearing, the heating motor shaft is connected with the connecting belt a in a friction manner, the heating motor shaft is connected with the connecting belt d in a friction manner, the mounting plate is connected with, the mounting plate is connected with a linkage shaft c bearing, the mounting plate is connected with a thread extension shaft through a thread, the mounting plate is connected with a linkage shaft e bearing, a connecting belt a is in friction connection with the linkage shaft a, the linkage shaft a is in friction connection with a connecting belt b, the linkage shaft a is in bearing connection with a connecting plate c, the linkage shaft a is in bearing connection with a connecting plate l, the connecting belt b is in friction connection with the linkage shaft b, the linkage shaft b is in friction connection with a connecting belt c, the linkage shaft b is in bearing connection with a connecting plate k, the connecting belt c is in friction connection with a linkage friction wheel, the linkage friction wheel is in friction connection with a pressing shaft, a connecting belt d is in friction connection with the linkage shaft c, the linkage shaft c is connected with the linkage friction wheel a, the linkage friction wheel a is in friction connection with the thread extension shaft, the linkage friction wheel a is in friction connection with the linkage shaft d, the, the tension spring is sleeved on the threaded extension shaft, one end of the tension spring is connected with the tension spring connecting plate, the other end of the tension spring is connected with the connecting plate c, the connecting belt e is in friction connection with the linkage shaft e, the linkage shaft e is in bearing connection with the mounting plate b, the linkage shaft e is connected with the linkage friction wheel b, the mounting plate b is connected with the connecting plate b, the linkage friction wheel b is in friction connection with the rotating ring, the rotating ring is in sliding connection with the electric heating plate, the rotating ring is in sliding connection with the ring body connecting block, the rotating ring is in sliding connection with the fixed connecting ring, the rotating ring is connected with the fan blades, one fixed ring connecting strip is connected with the connecting plate d, the other fixed ring connecting strip is connected with the connecting plate f, the electric heating plate is connected with the ring body connecting block.
As a further optimization of the technical scheme, the invention relates to a manufacturing device of a pre-impregnated winding propeller, wherein an output mechanism comprises an output wheel, an output shaft connecting plate, an output belt, an output shaft a, a torsion spring, an output shaft a bearing plate, an output belt a, an output shaft b bearing plate, a pulling steel wire, a wave plate, an output tension spring, a pulling limiting shaft, an inclined mounting plate a, an inclined mounting plate b and an inclined plate, the output wheel is connected with the output shaft, the output shaft is connected with the output shaft connecting plate through a bearing, the output shaft connecting plate is connected with a connecting plate c, the output belt is in friction connection with the output shaft, the output shaft a is in friction connection with the output belt, the torsion spring is sleeved on the output shaft a, one end of the torsion spring is connected with the output shaft a bearing plate, the output belt a is in friction connection with the output shaft a, the output shaft b is in friction connection with the output belt a, an output shaft b bearing plate is in bearing connection with the output shaft b, a pulling steel wire is wound on the output shaft b, one end of the pulling steel wire is connected with the middle output shaft b bearing plate, the other end of the pulling steel wire is connected with a wave plate, the wave plate is in sliding connection with a pulling limiting shaft, one end of an output tension spring is connected with the wave plate, the other end of the output tension spring is connected with a connecting plate d, the pulling limiting shaft is connected with the connecting plate d, an inclined mounting plate a is connected with an inclined mounting plate b, the inclined mounting plate b is connected with the connecting plate d, an inclined plate is connected with the inclined mounting plate a, the output belt is in sliding connection with a groove in the connecting.
As a further optimization of the technical scheme, the equipment for manufacturing the pre-impregnated winding propeller is characterized in that the electric heating plate heats the metal plate close to one side of the fan blade through the resistance of the electric heating plate after the electric heating plate is powered on.
The manufacturing equipment for the pre-impregnated winding propeller has the beneficial effects that:
according to the manufacturing equipment for the pre-immersed material wound propeller, the equipment can clamp the propeller core, the equipment can wind the pre-immersed material fiber yarns on the propeller core, the equipment can convey the wound propeller to the direction of the electric heater, the equipment can heat the wound propeller to melt and level the glue in the pre-immersed material, and the equipment can automatically output the propeller to the inclined plate.
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 pre-impregnated wound propeller manufacturing apparatus according to the present invention.
Fig. 2 is a schematic structural diagram of a pre-impregnated wound propeller manufacturing apparatus according to the present invention.
Fig. 3 is a schematic structural diagram of a winding mechanism 1 of a pre-impregnated wound propeller manufacturing device.
Fig. 4 is a schematic structural diagram of a winding mechanism 1 of a pre-impregnated wound propeller manufacturing device.
Fig. 5 is a schematic structural diagram of a winding mechanism 1 of a pre-impregnated wound propeller manufacturing device.
Fig. 6 is a schematic structural diagram of a winding mechanism 1 of a pre-impregnated wound propeller manufacturing device.
Fig. 7 is a schematic structural diagram of a winding mechanism 1 of a pre-impregnated wound propeller manufacturing device.
Fig. 8 is a schematic structural diagram of the heating mechanism 2 of the pre-impregnated wound propeller manufacturing apparatus according to the present invention.
Fig. 9 is a schematic structural diagram of a heating mechanism 2 of a pre-impregnated wound propeller manufacturing apparatus according to the present invention.
Fig. 10 is a schematic structural diagram of a heating mechanism 2 of a pre-impregnated wound propeller manufacturing apparatus according to the present invention.
Fig. 11 is a schematic structural diagram of a heating mechanism 2 of a pre-impregnated wound propeller manufacturing apparatus according to the present invention.
Fig. 12 is a schematic structural view of the linkage friction wheels 2-9 of the pre-invader-wound propeller manufacturing equipment.
Fig. 13 is a schematic structural diagram of an output mechanism 3 of a pre-impregnated wound propeller manufacturing apparatus according to the present invention.
Fig. 14 is a schematic structural diagram of an output mechanism 3 of a pre-impregnated wound propeller manufacturing apparatus according to the present invention.
In the figure: a winding mechanism 1; connection board a 1-1; connecting plate b 1-2; connecting plate c 1-3; connecting plate d 1-4; connecting plate e 1-5; connecting plate f 1-6; 1-7 of a motor; 1-8 of a motor shaft; 1-9 parts of a belt; 1-10 parts of a transmission shaft; 1-11 parts of friction wheel; a drive shaft a 1-12; connecting plates g 1-13; ball axis a 1-14; a rotating plate 1-15; 1-16 of a rotary connecting block; 1-17 of a rotating ring; rotating the wave strips 1-18; ball shafts b 1-19; 1-20 of a connecting shaft; ball axis c 1-21; ball shaft d 1-22; 1-23 parts of a limiting triangle; 1-24 parts of limiting plates; 1-25 parts of a limiting spring; limiting sliding shafts 1-26; 1-27 parts of a limiting shaft sleeve; hinge strips 1-28; sliding grooves 1-29; h 1-30; connecting shafts a 1-31; web j 1-32; winding shafts 1 to 33; 1-34 of pre-impregnated fiber filaments; connecting plates i 1-35; connecting points of the pre-impregnated fiber yarns are 1-36; fiber groove 1-37; 1-38 of propeller core; a compression shaft 1-39; 1-40 of a compression handle; pressing the springs 1-41; limiting by 1-42 through a compression spring; connection plates k 1-43; webs l 1-44; 1-45 parts of external threaded column; a heating mechanism 2; heating a motor 2-1; heating a motor shaft 2-2; mounting plates 2-3; a connecting belt a 2-4; linkage shaft a 2-5; a connecting belt b 2-6; linkage shaft b 2-7; connecting belt c 2-8; 2-9 of linkage friction wheels; a connecting belt d 2-10; linkage shaft c 2-11; a linkage friction wheel a 2-12; linkage shaft d 2-13; 2-14 parts of a threaded extension shaft; 2-15 of a tension spring; tension spring connecting plates 2-16; connecting belts e 2-17; linkage shaft e 2-18; mounting plate b 2-19; a linkage friction wheel b 2-20; 2-21 parts of a rotating ring; 2-22 of a fixed ring connecting strip; 2-23 parts of electric heating plates; 2-24 parts of ring body connecting blocks; 2-25 of fixed connection ring; fan blades 2-26; an output mechanism 3; an output wheel 3-1; an output shaft 3-2; an output shaft connecting plate 3-3; 3-4 parts of an output belt; output shaft a 3-5; 3-6 parts of a torsion spring; output shaft a bearing plates 3-7; output belt a 3-8; output shaft b 3-9; bearing plates 3-10 of the output shaft b; pulling 3-11 parts of steel wires; 3-12 of a heave plate; 3-13 parts of an output tension spring; pulling the limiting shaft 3-14; the inclined mounting plate a 3-15; inclined mounting plates b 3-16; the inclined plates 3-17.
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, and fig. 14, the present invention relates to a propeller manufacturing apparatus, and more specifically, to a pre-invaded material-wound propeller manufacturing apparatus, which includes a winding mechanism 1, a heating mechanism 2, and an output mechanism 3, and is capable of clamping a propeller core, winding a pre-invaded material fiber wire on the propeller core, conveying the wound propeller toward an electric heater, heating the wound propeller to melt and level the glue in the pre-invaded material, and automatically outputting the propeller to an inclined plate.
The winding mechanism 1 is connected with the heating mechanism 2, the heating mechanism 2 is connected with the output mechanism 3, and the output mechanism 3 is connected with the winding 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, and the embodiment further describes the embodiment, where the winding mechanism 1 includes a connection plate a1-1, a connection plate b1-2, a connection plate c1-3, a connection plate d1-4, a connection plate e1-5, a connection plate f1-6, a motor 1-7, a motor shaft 1-8, a belt 1-9, a transmission shaft 1-10, a friction wheel 1-11, a transmission shaft a1-12, a connection plate g1-13, a ball shaft a1-14, a rotation plate 1-15, a rotation connection block 1-16, a rotation ring 1-17, a rotation fluctuation strip 1-18, a ball shaft b1-19, a connection shaft 1-20, a connection shaft b and, Ball shaft c1-21, ball shaft d1-22, limit triangle 1-23, limit plate 1-24, limit spring 1-25, limit sliding shaft 1-26, limit shaft sleeve 1-27, hinge strip 1-28, sliding groove 1-29, connecting plate h1-30, connecting shaft a1-31, connecting plate j1-32, winding shaft 1-33, pre-invaded fiber 1-34, connecting plate i1-35, pre-invaded fiber connection point 1-36, fiber groove 1-37, propeller core 1-38, pressing shaft 1-39, pressing handle 1-40, pressing spring 1-41, pressing spring limit 1-42, connecting plate k1-43, connecting plate l1-44, external thread column 1-45, connecting plate a1-1 is connected with connecting plate b1-2, connecting plate a1-1 is connected with rotating wave sliding strips 1-18 in a sliding mode, connecting plate b1-2 is connected with connecting plate c1-3, connecting plate b1-2 is connected with connecting plate e1-5, connecting plate b1-2 is connected with connecting plate e1-5, connecting plate b1-2 is connected with connecting plate f1-6, connecting plate b1-2 is connected with connecting plate k1-43, connecting plate c1-3 is connected with connecting plate d1-4, connecting plate d1-4 is connected with connecting plate e1-5, connecting plate d1-4 is connected with connecting plate f1-6, connecting plate d1-4 is connected with connecting plate g1-13, connecting plate d1-4 is connected with connecting plate k1-43, connecting plate d1-4 is connected with connecting plate l1-44, connecting plate e1-5 is connected with rotating wave sliding strips 1-18, a connecting plate e1-5 is connected with a connecting plate f1-6, motors 1-7 are connected with motor shafts 1-8, motors 1-7 are connected with connecting plates g1-13, motor shafts 1-8 are in friction connection with belts 1-9, belts 1-9 are in friction connection with transmission shafts 1-10, transmission shafts 1-10 are connected with friction wheels 1-11, transmission shafts 1-10 are in bearing connection with connecting plates g1-13, friction wheels 1-11 are in friction connection with transmission shafts a1-12, transmission shafts a1-12 are in sliding connection with connecting plates g1-13, transmission shafts a1-12 are in sliding connection with ball shafts a1-14, transmission shafts a1-12 are connected with ball shafts d1-22, grooves on the transmission shafts a1-12 are in bearing connection with limiting shaft sleeves 1-27, ball shafts a1-14 are in bearing connection with rotating plates 1-15, the rotating plate 1-15 is connected with the rotating connecting block 1-16, the rotating plate 1-15 is connected with the rotating ring 1-17 in a sliding manner, the rotating ring 1-17 is connected with the rotating wave strip 1-18, the ball shaft b1-19 is connected with the rotating plate 1-15 in a bearing manner, the ball shaft b1-19 is connected with the connecting shaft 1-20, the connecting shaft 1-20 is connected with the ball shaft c1-21, the ball shaft c1-21 is connected with the connecting plate i1-35 in a bearing manner, the limiting triangle 1-23 is connected with the limiting plate 1-24, the limiting plate 1-24 is connected with the limiting sliding shaft 1-26, the limiting spring 1-25 is sleeved on the limiting sliding shaft 1-26 and limited on the limiting plate 1-24 and the sliding groove 1-29, the limiting sliding shaft 1-26 is connected with the sliding groove 1-29 in a sliding, limiting shaft sleeves 1-27 are hinged with hinge strips 1-28, the hinge strips 1-28 are hinged with limiting plates 1-24, sliding grooves 1-29 are connected with a connecting plate e1-5, a connecting plate h1-30 is connected with a connecting shaft a1-31, a connecting plate h1-30 is connected with a connecting plate i1-35, a connecting shaft a1-31 is connected with a connecting plate j1-32, a connecting plate j1-32 is connected with pre-impregnated fiber wires 1-34 in a sliding mode, winding shafts 1-33 are connected with connecting plates h1-30 through bearings, the pre-impregnated fiber wires 1-34 are wound on the winding shafts 1-33 and are connected between the two connecting plates j1-32 through holes in the connecting plates i1-35 and holes in the connecting plates j1-32, fiber grooves 1-37 are opened in external threaded columns 1-45, the pressing shafts 1-39 are connected with pressing spring limits 1-42, the pressing shafts 1-39 are connected with connecting plates k1-43 in a sliding mode, the pressing handles 1-40 are connected with the pressing shafts 1-39, the pressing springs 1-41 are sleeved on the pressing shafts 1-39 and limited at the pressing spring limits 1-42 and connected with the connecting plates k1-43, the connecting plates k1-43 are connected with the connecting plates l1-44, the external threaded columns 1-45 are in threaded connection with the ball shafts d1-22, the external threaded columns 1-45 are connected with the transmission shafts a1-12 through bearings, equipment can clamp propeller cores, can wind pre-invaded fiber wires on the propeller cores, pull the pressing handles 1-40, drive the pressing shafts 1-39 and the pressing spring limits 1-42, the pressing springs limit 1-42 press the springs 1-41, when the pressing shaft 1-39 is pulled to generate a gap with the external thread column 1-45, the propeller core is placed between the pressing shaft 1-39 and the external thread column 1-45, under the action of the pressing spring 1-41, the propeller core is clamped, the rotating fluctuation strip 1-18 is rotated, the rotating fluctuation strip 1-18 rotates by taking the ball shaft a1-14 as the center, the rotating fluctuation strip 1-18 rotates to drive the rotating plate 1-15 to rotate, the rotating plate 1-15 rotates and drives the rotating ring 1-17 to rotate through the rotating connecting block 1-16, the rotating fluctuation strip 1-18 is limited by the limiting triangle 1-23 under the action of the limiting spring 1-25 when rotating, the connecting plate i1-35 is driven to rotate under the action of the ball shaft b1-19, the connecting shaft 1-20 and the ball shaft c1-21 when the rotating plate 1-15 rotates, the connecting plates i1-35 rotate to drive the connecting plates h1-30 to rotate, the connecting plates i1-35 rotate to drive the connecting plates j1-32 to rotate through the connecting shafts a1-31, namely the winding angle can be controlled when the rotating fluctuation strips 1-18 rotate, the motors 1-7 work to drive the motor shafts 1-8 to rotate, the motor shafts 1-8 rotate to drive the transmission shafts 1-10 to rotate through the belts 1-9, the transmission shafts 1-10 rotate to drive the friction wheels 1-11 to rotate, the friction wheels 1-11 rotate to drive the transmission shafts a1-12 to rotate, the transmission shafts a1-12 rotate to slide on the external threaded columns 1-45, when the transmission shafts a1-12 move towards the connecting plates k1-43, the equipment starts to wind on the propeller core, pre-cutting fiber filaments are wound on the two winding shafts 1-33, one end of each pre-cut fiber enters between two connecting plates j1-32 through holes in the connecting plates i1-35 and the connecting plates j1-32, one of the two pre-cut fibers passes through fiber grooves 1-37 and is tied with the other one, when the transmission shaft a1-12 slides on the external threaded column 1-45, the pre-cut fibers are wound on the propeller core 1-38 according to a certain inclination, and when the transmission shaft a1-12 moves, the limiting plates 1-24 are driven to move by the limiting shaft sleeves 1-27 and the hinge strips 1-28, so that the stability of the inclination when the pre-cut fibers are wound is further facilitated.
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, and fig. 14, and the embodiment further describes the embodiment, where the heating mechanism 2 includes a heating motor 2-1, a heating motor shaft 2-2, a mounting plate 2-3, a connecting belt a2-4, a linkage shaft a2-5, a connecting belt b2-6, a linkage shaft b2-7, a connecting belt c2-8, a linkage friction wheel 2-9, a connecting belt d2-10, a linkage shaft c2-11, a linkage friction wheel a2-12, a linkage shaft d2-13, a threaded extension shaft 2-14, a tension spring 2-15, a tension spring connecting plate 2-16, a connecting belt e2-17, a linkage shaft e2-18, a tension spring connecting plate b 2-12, a linkage shaft, Mounting plate b2-19, linkage friction wheel b2-20, rotating ring 2-21, fixing ring connecting strip 2-22, electric heating plate 2-23, ring body connecting block 2-24, fixed connecting ring 2-25, fan blade 2-26, heating motor 2-1 is connected with heating motor shaft 2-2, heating motor shaft 2-2 is connected with mounting plate 2-3 bearing, heating motor shaft 2-2 is connected with connecting belt a2-4 friction, heating motor shaft 2-2 is connected with connecting belt d2-10 friction, mounting plate 2-3 is connected with connecting plate b1-2, mounting plate 2-3 is connected with connecting plate d1-4, mounting plate 2-3 is connected with linkage shaft c2-11 bearing, mounting plate 2-3 is connected with screw thread extension shaft 2-14 thread, the mounting plate 2-3 is in bearing connection with a linkage shaft e2-18, a connecting belt a2-4 is in friction connection with a linkage shaft a2-5, the linkage shaft a2-5 is in friction connection with a connecting belt b2-6, the linkage shaft a2-5 is in bearing connection with a connecting plate c1-3, the linkage shaft a2-5 is in bearing connection with a connecting plate l1-44, the connecting belt b2-6 is in friction connection with a linkage shaft b2-7, the linkage shaft b2-7 is in friction connection with a connecting belt c2-8, the linkage shaft b2-7 is in bearing connection with a connecting plate k1-43, the connecting belt c2-8 is in friction connection with linkage friction wheels 2-9, the linkage friction wheels 2-9 are in friction connection with compression shafts 1-39, the connecting belt d2-10 is in friction connection with a linkage shaft c2-11, and the linkage shaft c2-11 is in connection with a linkage friction wheel a2-12, the linkage friction wheel a2-12 is in friction connection with the thread extension shaft 2-14, the linkage friction wheel a2-12 is in friction connection with the linkage shaft d2-13, the linkage shaft d2-13 is in friction connection with the connecting belt e2-17, the thread extension shaft 2-14 is connected with the tension spring connecting plate 2-16, the tension spring 2-15 is sleeved on the thread extension shaft 2-14, one end of the tension spring is connected with the tension spring connecting plate 2-16, the other end of the tension spring is connected with the connecting plate c1-3, the connecting belt e2-17 is in friction connection with the linkage shaft e2-18, the linkage shaft e2-18 is in bearing connection with the mounting plate b2-19, the linkage shaft e2-18 is connected with the linkage friction wheel b2-20, the mounting plate b2-19 is connected with the connecting plate b1-2, the linkage friction wheel b2-20 is in friction connection with, the rotating ring 2-21 is connected with the electric heating plate 2-23 in a sliding manner, the rotating ring 2-21 is connected with the ring body connecting block 2-24 in a sliding manner, the rotating ring 2-21 is connected with the fixed connecting ring 2-25 in a sliding manner, the rotating ring 2-21 is connected with the fan blade 2-26, one fixed ring connecting strip 2-22 is connected with the connecting plate d1-4, the other fixed ring connecting strip 2-22 is connected with the connecting plate f1-6, the electric heating plate 2-23 is connected with the ring body connecting block 2-24, the ring body connecting block 2-24 is connected with the fixed connecting ring 2-25, the fixed connecting ring 2-25 is connected with the two fixed ring connecting strips 2-22, the equipment can transmit the wound propeller to the direction of the electric heating device, the equipment can heat the wound propeller to melt and level the glue in the pre-impregnated material, after the pre-impregnated fiber yarns are wound on the propeller core, the pre-impregnated fiber yarns wound on the propeller core are cut off, the heating motor 2-1 works to drive the heating motor shaft 2-2 to rotate, the heating motor shaft 2-2 rotates to drive the linkage shaft c2-11 to rotate through the connecting belt d2-10, the linkage shaft c2-11 rotates to drive the linkage shaft d2-13 to move, the linkage shaft d2-13 transversely moves when rotating, when moving towards the external threaded column 1-45, the wound propeller transmits towards the direction of an electric heater, in order to avoid obstacle, the transmission shaft a1-12 reversely rotates, the connecting plate j1-32 moves towards the direction of the connecting plate c1-3, the linkage friction wheel a2-12 rotates and simultaneously drives the linkage shaft d2-13 to rotate, the linkage shaft d2-13 rotates to drive the linkage shaft e2-18 to rotate through the connecting belt 2-17, the linkage shaft e2-18 rotates to drive the linkage friction wheel b2-20 to rotate, the linkage friction wheel b2-20 rotates to drive the rotating ring 2-21 to rotate, the rotating ring 2-21 rotates to drive the fan blades 2-26 to rotate, after the electric heating plates 2-23 are powered on, the electric heating plates 2-23 close to the fan blades 2-26 start to generate heat, the heat is blown to the outer direction through the fan blades 2-26, the wound propeller is heated when moving on the outer threaded columns 1-45, and the glue in the pre-soaked materials is melted and leveled.
The fourth concrete implementation mode:
referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, the present embodiment will be further described, wherein the output mechanism 3 includes an output wheel 3-1, an output shaft 3-2, an output shaft connecting plate 3-3, an output belt 3-4, an output shaft a3-5, a torsion spring 3-6, an output shaft a bearing plate 3-7, an output belt a3-8, an output shaft b3-9, an output shaft b bearing plate 3-10, a pulling steel wire 3-11, a fluctuating plate 3-12, an output tension spring 3-13, a pulling limiting shaft 3-14, an inclined mounting plate a3-15, an inclined mounting plate b3-16, an inclined plate 3-17, an output wheel 3-1 is connected with an output shaft 3-2, an output shaft 3-2 is in bearing connection with an output shaft connecting plate 3-3, the output shaft connecting plate 3-3 is connected with a connecting plate c1-3, an output belt 3-4 is in friction connection with the output shaft 3-2, an output shaft a3-5 is in friction connection with the output belt 3-4, a torsion spring 3-6 is sleeved on the output shaft a3-5, one end of the torsion spring is connected with an output shaft a bearing plate 3-7, the other end of the torsion spring is connected with another output shaft a bearing plate 3-7, the output shaft a bearing plate 3-7 is in bearing connection with an output shaft a3-5, the output belt a3-8 is in friction connection with an output shaft a3-5, the output shaft b 7-9 is in friction connection with an output belt a 355639-8, the output shaft b bearing plate 3-10 is in bearing connection with an output shaft b3-9, a steel wire 3-11 is pulled to -10, the other end of the pulling wire 3-11 is connected with the heave plate 3-12, the heave plate 3-12 is connected with the pulling limit shaft 3-14 in a sliding way, one end of the output tension spring 3-13 is connected with the heave plate 3-12, the other end is connected with the connecting plate d1-4, the pulling limit shaft 3-14 is connected with the connecting plate d1-4, the inclined mounting plate a3-15 is connected with the inclined mounting plate b3-16, the inclined mounting plate b3-16 is connected with the connecting plate d1-4, the inclined plate 3-17 is connected with the inclined mounting plate a3-15, the output belt 3-4 is connected with the groove on the connecting plate b1-2 in a sliding way, the output shaft a bearing plate 3-7 is connected with the connecting plate b1-2, the output shaft b bearing plate 3-10 is connected with the connecting plate, the inclined plates 3-17 are connected with the connecting plate d1-4, the equipment can automatically output the propeller onto the inclined plates, when the heated propeller is conveyed above the undulation plates 3-12, the motors 1-7 work to drive the motor shafts 1-8 to rotate, the motor shafts 1-8 rotate to drive the transmission shafts 1-10 to rotate through the belts 1-9, the transmission shafts 1-10 rotate to drive the friction wheels 1-11 to rotate, the friction wheels 1-11 rotate to drive the transmission shafts a1-12 to rotate, the transmission shafts a1-12 rotate and move towards the external threaded columns 1-45, the transmission shafts a1-12 rotate to drive the output wheels 3-1 to rotate, the output wheels 3-1 rotate to drive the output shafts 3-2 to rotate, the output shafts 3-2 rotate to drive the output shafts a3-5 to rotate through the output belts 3-4, when the output shaft a3-5 rotates, the torsion spring 3-6 continuously accumulates torsion, when the output shaft a3-5 rotates, the output belt a3-8 drives the output shaft b3-9 to rotate, the output shaft b3-9 rotates to drive the pulling steel wire 3-11 to wind on the output shaft b3-9, the output shaft b3-9 pulls the wave plate 3-12 to move upwards under the limitation of the pulling limit shaft 3-14, when the transmission shaft a1-12 moves to be out of contact with the output wheel 3-1, the torsion of the torsion spring 3-6 is released instantly, the output shaft a3-5 starts to rotate reversely, the output shaft b3-9 rotates reversely synchronously, when the output shaft b3-9 rotates, the pulling steel wire 3-11 is unwound, the wave plate 3-12 is pulled downwards instantly under the action of the output tension spring 3-13, the heave plate 3-12 in the downward movement brings the propeller down onto the inclined plate 3-17, under the effect of the inclined plate 3-17 the propeller is tilted out.
The fifth concrete implementation mode:
the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, and 14, and the present embodiment further describes that the electric heating plates 2 to 23 generate heat at the metal plates on the sides close to the fan blades 2 to 26 by their own electric resistance after the power is turned on.
The working principle of the device is as follows: the equipment can clamp a propeller core, the equipment can wind pre-impregnated fiber filaments on the propeller core, pull a pressing handle 1-40, the pressing handle 1-40 drives a pressing shaft 1-39 and a pressing spring limit 1-42, the pressing spring limit 1-42 presses a pressing spring 1-41, when the pressing shaft 1-39 is pulled to form a gap with an external thread column 1-45, the propeller core is placed between the pressing shaft 1-39 and the external thread column 1-45, the propeller core is clamped under the action of the pressing spring 1-41, the propeller core rotates and rotates a fluctuation strip 1-18, the rotation fluctuation strip 1-18 rotates by taking a spherical shaft a1-14 as a center when rotating, the rotation fluctuation strip 1-18 rotates to drive a rotation plate 1-15 to rotate, the rotation plate 1-15 rotates and drives a rotation ring 1-17 to rotate through a rotation connecting block 1-16, the rotary fluctuation strips 1-18 are limited by the limiting triangles 1-23 under the action of the limiting springs 1-25 when rotating, the connecting plates i1-35 are driven to rotate under the action of the ball shafts b1-19, the connecting shafts 1-20 and the ball shafts c1-21 when the rotating plates 1-15 rotate, the connecting plates i1-35 rotate to drive the connecting plates h1-30 to rotate, the connecting plates i1-35 rotate and drive the connecting plates j1-32 to rotate through the connecting shafts a1-31, namely, the winding angle can be controlled when the rotary fluctuation strips 1-18 rotate, the motors 1-7 work to drive the motor shafts 1-8 to rotate, the motor shafts 1-8 rotate to drive the transmission shafts 1-10 to rotate through the belts 1-9, the transmission shafts 1-10 rotate to drive the friction wheels 1-11 to rotate, the friction wheels 1-11 rotate to drive the transmission shafts a1-12 to rotate, the transmission shafts a1-12 rotate to slide on the external threaded columns 1-45, when the transmission shafts a1-12 move towards the connecting plates k1-43, the equipment starts to wind on the propeller core, pre-invaded fiber filaments are wound on the two winding shafts 1-33, one ends of the pre-invaded fiber filaments enter between the two connecting plates j1-32 through holes on the connecting plates i1-35 and the connecting plates j1-32, one of the two pre-invaded fiber filaments passes through the fiber filament slots 1-37 and is tied with the other, when the transmission shafts a1-12 slide on the external threaded columns 1-45, the pre-invaded fiber filaments are wound on the propeller core 1-38 according to a certain inclination, when the transmission shafts a1-12 move, the limiting plates 1-24 are driven by the limiting shaft sleeves 1-27 and the hinge strips 1-28, the device can convey the wound propeller towards the direction of an electric heater, the device can heat the wound propeller to melt and level glue in the pre-immersed material, the pre-immersed material fiber wound on a propeller core is cut off after the pre-immersed material fiber is wound on the propeller core, a heating motor 2-1 works, the heating motor 2-1 works to drive a heating motor shaft 2-2 to rotate, the heating motor shaft 2-2 rotates to drive a linkage shaft c2-11 to rotate through a connecting belt d2-10, the linkage shaft c2-11 rotates to drive a linkage shaft d2-13 to move, the linkage shaft d2-13 rotates transversely, the wound propeller is conveyed towards the direction of the electric heater when moving towards an outer threaded column 1-45, and in order to avoid the reverse rotation of a transmission shaft a1-12 when an obstacle exists, the connecting plate j1-32 is enabled to move towards the connecting plate c1-3, the linkage friction wheel a2-12 rotates and simultaneously drives the linkage shaft d2-13 to rotate, the linkage shaft d2-13 rotates and drives the linkage shaft e2-18 to rotate through the connecting belt e2-17, the linkage shaft e2-18 rotates and drives the linkage friction wheel b2-20 to rotate, the linkage friction wheel b2-20 rotates and drives the rotating ring 2-21 to rotate, the rotating ring 2-21 rotates and drives the fan blades 2-26 to rotate, after the electric heating plates 2-23 are powered on, the electric heating plates 2-23 close to the fan blades 2-26 start to generate heat, the heat is blown towards the fan blades 2-26, the wound propeller is heated when moving towards the external threaded column 1-45 until the glue in the pre-soaked material is melted and leveled, the equipment can automatically output the propeller onto the inclined plate, when the heated propeller is conveyed to the upper part of the fluctuating plate 3-12, the motor 1-7 works to drive the motor shaft 1-8 to rotate, the motor shaft 1-8 rotates to drive the transmission shaft 1-10 to rotate through the belt 1-9, the transmission shaft 1-10 rotates to drive the friction wheel 1-11 to rotate, the friction wheel 1-11 rotates to drive the transmission shaft a1-12 to rotate, the transmission shaft a1-12 rotates and moves towards the external threaded column 1-45, the transmission shaft a1-12 rotates to drive the output wheel 3-1 to rotate, the output wheel 3-1 rotates to drive the output shaft 3-2 to rotate, the output shaft 3-2 rotates to drive the output shaft a3-5 to rotate through the output belt 3-4, when the output shaft a3-5 rotates, the torsion spring 3-6 continuously accumulates torsion, when the output shaft a3-5 rotates, the output belt a3-8 drives the output shaft b3-9 to rotate, the output shaft b3-9 rotates to drive the pulling steel wire 3-11 to wind on the output shaft b3-9, the output shaft b3-9 pulls the wave plate 3-12 to move upwards under the limitation of the pulling limit shaft 3-14, when the transmission shaft a1-12 moves to be out of contact with the output wheel 3-1, the torsion of the torsion spring 3-6 is released instantly, the output shaft a3-5 starts to rotate reversely, the output shaft b3-9 rotates reversely synchronously, when the output shaft b3-9 rotates, the pulling steel wire 3-11 is unwound, the wave plate 3-12 is pulled downwards instantly under the action of the output tension spring 3-13, the heave plate 3-12 in the downward movement brings the propeller down onto the inclined plate 3-17, under the effect of the inclined plate 3-17 the propeller is tilted out.
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.

Claims (5)

1. The utility model provides a precut material winding screw preparation equipment, includes winding mechanism (1), heating mechanism (2), output mechanism (3), its characterized in that: the winding mechanism (1) is connected with the heating mechanism (2), the heating mechanism (2) is connected with the output mechanism (3), and the output mechanism (3) is connected with the winding mechanism (1).
2. A pre-encroaching material-wound propeller manufacturing apparatus as recited in claim 1, wherein: the winding mechanism (1) comprises a connecting plate a (1-1), a connecting plate b (1-2), a connecting plate c (1-3), a connecting plate d (1-4), a connecting plate e (1-5), a connecting plate f (1-6), a motor (1-7), a motor shaft (1-8), a belt (1-9), a transmission shaft (1-10), a friction wheel (1-11), a transmission shaft a (1-12), a connecting plate g (1-13), a ball shaft a (1-14), a rotating plate (1-15), a rotating connecting block (1-16), a rotating ring (1-17), a rotating fluctuation strip (1-18), a ball shaft b (1-19), a connecting shaft (1-20), a ball shaft c (1-21), a ball shaft d (1-22), The device comprises limiting triangles (1-23), limiting plates (1-24), limiting springs (1-25), limiting sliding shafts (1-26), limiting shaft sleeves (1-27), hinge strips (1-28), sliding grooves (1-29), connecting plates h (1-30), connecting shafts a (1-31), connecting plates j (1-32), winding shafts (1-33), pre-impregnated fiber filaments (1-34), connecting plates i (1-35), pre-impregnated fiber filament connecting points (1-36), fiber filament grooves (1-37), propeller cores (1-38), pressing shafts (1-39), pressing handles (1-40), pressing springs (1-41), pressing spring limiting blocks (1-42), connecting plates k (1-43), A connecting plate l (1-44) and an external threaded column (1-45), wherein the connecting plate a (1-1) is connected with the connecting plate b (1-2), the connecting plate a (1-1) is connected with a rotating wave sliding strip (1-18) in a sliding manner, the connecting plate b (1-2) is connected with the connecting plate c (1-3), the connecting plate b (1-2) is connected with the connecting plate e (1-5), the connecting plate b (1-2) is connected with the connecting plate f (1-6), the connecting plate b (1-2) is connected with the connecting plate k (1-43), the connecting plate c (1-3) is connected with the connecting plate d (1-4), and the connecting plate d (1-4) is connected with the connecting plate e (1-5), a connecting plate d (1-4) is connected with a connecting plate f (1-6), the connecting plate d (1-4) is connected with a connecting plate g (1-13), the connecting plate d (1-4) is connected with a connecting plate k (1-43), the connecting plate d (1-4) is connected with a connecting plate l (1-44), a connecting plate e (1-5) is connected with a rotating fluctuation strip (1-18) in a sliding manner, the connecting plate e (1-5) is connected with a connecting plate f (1-6), a motor (1-7) is connected with a motor shaft (1-8), a motor (1-7) is connected with a connecting plate g (1-13), a motor shaft (1-8) is connected with a belt (1-9) in a friction manner, a belt (1-9) is connected with a transmission shaft (1-10) in a friction manner, and a transmission shaft (1-10) is connected with a friction wheel (1-11), the transmission shaft (1-10) is in bearing connection with the connecting plate g (1-13), the friction wheel (1-11) is in friction connection with the transmission shaft a (1-12), the transmission shaft a (1-12) is in sliding connection with the connecting plate g (1-13), the transmission shaft a (1-12) is in sliding connection with the ball shaft a (1-14), the transmission shaft a (1-12) is connected with the ball shaft d (1-22), the groove on the transmission shaft a (1-12) is in bearing connection with the limiting shaft sleeve (1-27), the ball shaft a (1-14) is in bearing connection with the rotating plate (1-15), the rotating plate (1-15) is connected with the rotating connecting block (1-16), the rotating plate (1-15) is in sliding connection with the rotating ring (1-17), the rotating ring (1-17) is connected with the rotating fluctuation strip (1-18), the ball shaft b (1-19) is in bearing connection with the rotating plate (1-15), the ball shaft b (1-19) is in bearing connection with the connecting shaft (1-20), the connecting shaft (1-20) is in connection with the ball shaft c (1-21), the ball shaft c (1-21) is in bearing connection with the connecting plate i (1-35), the limiting triangle (1-23) is in connection with the limiting plate (1-24), the limiting plate (1-24) of the limiting plate (1-24) is in connection with the limiting sliding shaft (1-26), the limiting spring (1-25) is sleeved on the limiting sliding shaft (1-26) and limited on the limiting plate (1-24) and the sliding groove (1-29), the limiting sliding shaft (1-26) is in sliding connection with the sliding groove (1-29), the limiting shaft sleeve (1-27) is hinged with the hinge strip (1-28), the hinge strips (1-28) are hinged with the limit plates (1-24), the sliding grooves (1-29) are connected with the connecting plates e (1-5), the connecting plates h (1-30) are connected with connecting shafts a (1-31), the connecting plates h (1-30) are connected with the connecting plates i (1-35), the connecting shafts a (1-31) are connected with the connecting plates j (1-32), the connecting plates j (1-32) are connected with pre-impregnated fiber yarns (1-34) in a sliding mode, the winding shafts (1-33) are connected with the connecting plates h (1-30) through bearings, the pre-impregnated fiber yarns (1-34) are wound on the winding shafts (1-33) and are connected between the two connecting plates j (1-32) through holes in the connecting plates i (1-35) and holes in the connecting plates j (1-32), the fiber groove (1-37) is arranged on the external thread column (1-45), the pressing shaft (1-39) is connected with a pressing spring limit (1-42), the pressing shaft (1-39) is connected with a connecting plate k (1-43) in a sliding mode, the pressing handle (1-40) is connected with the pressing shaft (1-39), the pressing spring (1-41) is sleeved on the pressing shaft (1-39) and limited on the pressing spring limit (1-42) and the connecting plate k (1-43), the connecting plate k (1-43) is connected with a connecting plate l (1-44), the external thread column (1-45) is in threaded connection with the ball shaft d (1-22), and the external thread column (1-45) is in bearing connection with the transmission shaft a (1-12).
3. A pre-encroaching material-wound propeller manufacturing apparatus as recited in claim 1, wherein: the heating mechanism (2) comprises a heating motor (2-1), a heating motor shaft (2-2), a mounting plate (2-3), a connecting belt a (2-4), a linkage shaft a (2-5), a connecting belt b (2-6), a linkage shaft b (2-7), a connecting belt c (2-8), a linkage friction wheel (2-9), a connecting belt d (2-10), a linkage shaft c (2-11), a linkage friction wheel a (2-12), a linkage shaft d (2-13), a thread extension shaft (2-14), a tension spring (2-15), a tension spring connecting plate (2-16), a connecting belt e (2-17), a linkage shaft e (2-18), a mounting plate b (2-19), a linkage friction wheel b (2-20), The device comprises a rotating ring (2-21), a fixed ring connecting strip (2-22), an electric heating plate (2-23), a ring body connecting block (2-24), a fixed connecting ring (2-25) and fan blades (2-26), a heating motor (2-1) is connected with a heating motor shaft (2-2), the heating motor shaft (2-2) is in bearing connection with a mounting plate (2-3), the heating motor shaft (2-2) is in friction connection with a connecting belt a (2-4), the heating motor shaft (2-2) is in friction connection with a connecting belt d (2-10), the mounting plate (2-3) is connected with a connecting plate b (1-2), the mounting plate (2-3) is connected with a connecting plate d (1-4), the mounting plate (2-3) is in bearing connection with a linkage shaft c (2-11), the mounting plate (2-3) is in threaded connection with the threaded extension shaft (2-14), the mounting plate (2-3) is in bearing connection with a linkage shaft e (2-18), a connecting belt a (2-4) is in frictional connection with a linkage shaft a (2-5), the linkage shaft a (2-5) is in frictional connection with a connecting belt b (2-6), the linkage shaft a (2-5) is in bearing connection with a connecting plate c (1-3), the linkage shaft a (2-5) is in bearing connection with a connecting plate l (1-44), the connecting belt b (2-6) is in frictional connection with a linkage shaft b (2-7), the linkage shaft b (2-7) is in frictional connection with a connecting belt c (2-8), the linkage shaft b (2-7) is in bearing connection with a connecting plate k (1-43), the connecting belt c (2-8) is in frictional connection with a linkage friction wheel (2-9), the linkage friction wheels (2-9) are in friction connection with the compression shafts (1-39), the connecting belts d (2-10) are in friction connection with the linkage shafts c (2-11), the linkage shafts c (2-11) are connected with the linkage friction wheels a (2-12), the linkage friction wheels a (2-12) are in friction connection with the thread extension shafts (2-14), the linkage friction wheels a (2-12) are in friction connection with the linkage shafts d (2-13), the linkage shafts d (2-13) are in friction connection with the connecting belts e (2-17), the thread extension shafts (2-14) are connected with the tension spring connecting plates (2-16), the tension springs (2-15) are sleeved on the thread extension shafts (2-14), one ends of the tension springs are connected with the tension springs (2-16), the other ends of the tension springs are connected with the connecting plates c (1-3), a connecting belt e (2-17) is in friction connection with a linkage shaft e (2-18), the linkage shaft e (2-18) is in bearing connection with a mounting plate b (2-19), the linkage shaft e (2-18) is in connection with a linkage friction wheel b (2-20), the mounting plate b (2-19) is in connection with a connecting plate b (1-2), the linkage friction wheel b (2-20) is in friction connection with a rotating ring (2-21), the rotating ring (2-21) is in sliding connection with an electric heating plate (2-23), the rotating ring (2-21) is in sliding connection with a ring body connecting block (2-24), the rotating ring (2-21) is in sliding connection with a fixed connecting ring (2-25), the rotating ring (2-21) is in connection with a fan blade (2-26), a fixed ring connecting strip (2-22) is connected with a connecting plate d (1-4), the other fixing ring connecting strip (2-22) is connected with the connecting plate f (1-6), the electric heating plates (2-23) are connected with the ring body connecting blocks (2-24), the ring body connecting blocks (2-24) are connected with the fixing connecting rings (2-25), and the fixing connecting rings (2-25) are connected with the two fixing ring connecting strips (2-22).
4. A pre-encroaching material-wound propeller manufacturing apparatus as recited in claim 1, wherein: the output mechanism (3) comprises an output wheel (3-1), an output shaft (3-2), an output shaft connecting plate (3-3), an output belt (3-4), an output shaft a (3-5), a torsion spring (3-6), an output shaft a bearing plate (3-7), an output belt a (3-8), an output shaft b (3-9), an output shaft b bearing plate (3-10), a pulling steel wire (3-11), a wave plate (3-12), an output tension spring (3-13), a pulling limiting shaft (3-14), an inclined mounting plate a (3-15), an inclined mounting plate b (3-16) and an inclined plate (3-17), wherein the output wheel (3-1) is connected with the output shaft (3-2), and the output shaft (3-2) is in bearing connection with the output shaft connecting plate (3-3), an output shaft connecting plate (3-3) is connected with a connecting plate c (1-3), an output belt (3-4) is in friction connection with an output shaft (3-2), an output shaft a (3-5) is in friction connection with the output belt (3-4), a torsion spring (3-6) is sleeved on the output shaft a (3-5), one end of the torsion spring is connected with an output shaft a bearing plate (3-7), the other end of the torsion spring is connected with another output shaft a bearing plate (3-7), the output shaft a bearing plate (3-7) is in bearing connection with the output shaft a (3-5), the output belt a (3-8) is in friction connection with the output shaft a (3-5), the output shaft b (3-9) is in friction connection with the output belt a (3-8), and the output shaft b bearing plate (3-10) is in bearing connection with the output shaft b (3-9), a pulling steel wire (3-11) is wound on an output shaft b (3-9), one end of the pulling steel wire (3-11) is connected with a middle output shaft b bearing plate (3-10), the other end of the pulling steel wire (3-11) is connected with a heave plate (3-12), the heave plate (3-12) is connected with a pulling limit shaft (3-14) in a sliding way, one end of an output tension spring (3-13) is connected with the heave plate (3-12), the other end of the output tension spring is connected with a connecting plate d (1-4), the pulling limit shaft (3-14) is connected with a connecting plate d (1-4), an inclined mounting plate a (3-15) is connected with an inclined mounting plate b (3-16), the inclined mounting plate b (3-16) is connected with the connecting plate d (1-4), and an inclined plate (3-17) is connected with the inclined mounting plate a, an output belt (3-4) is in sliding connection with a groove on a connecting plate b (1-2), an output shaft a bearing plate (3-7) is connected with the connecting plate b (1-2), an output shaft b bearing plate (3-10) is connected with the connecting plate b (1-2), and an inclined plate (3-17) is connected with a connecting plate d (1-4).
5. A pre-encroaching material-wound propeller manufacturing apparatus as recited in claim 1, wherein: the electric heating plates (2-23) generate heat on the metal plates close to the fan blades (2-26) through self resistance after being powered on.
CN202011074065.2A 2020-10-09 2020-10-09 Pre-invasion material winding propeller manufacturing equipment Withdrawn CN112140580A (en)

Priority Applications (1)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113510949A (en) * 2021-07-23 2021-10-19 董清方 Prepreg winding and propeller manufacturing equipment

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113510949A (en) * 2021-07-23 2021-10-19 董清方 Prepreg winding and propeller manufacturing equipment

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Application publication date: 20201229