CN110281551B - Production facility suitable for wind-powered electricity generation is carbon fiber pultrusion panel for blade girder - Google Patents

Abstract

The invention discloses a production device of a carbon fiber pultrusion plate for a wind power blade main beam, which comprises a machine body, a rotating cavity is arranged at the upper part in the machine body, the right upper wall of the rotating cavity is fixedly connected with a motor, the left upper wall of the rotating cavity is fixedly connected with a hydraulic device, a raw material cavity is arranged at the lower right part of the rotating cavity, a pressurizing plate is connected in the raw material cavity in a sliding way, a primary impregnation tank is arranged below the raw material cavity, the invention increases pressure to change carbon fiber raw materials into fiber bundles, and the fiber bundles are wrapped by core layer raw materials and impregnated by outer layer materials, thereby effectively improving the strength of the materials, the invention screws the carbon fibers vertically by mechanical transmission, and the whole process is continuously carried out after the conveying and the stretching and the forming die are repeated, so that the production efficiency is improved.

Description

Production facility suitable for wind-powered electricity generation is carbon fiber pultrusion panel for blade girder

Technical Field

The invention relates to the field of wind power equipment, in particular to production equipment suitable for a carbon fiber pultrusion plate for a wind power blade main beam.

Background

With the continuous upgrading of technologies of wind power related industries, the length of a wind power blade is longer and longer at present, the weight reduction requirement of the blade is urgent, a carbon fiber pultrusion plate is high in strength and light in weight and becomes the best material for the wind power blade, pultrusion is a process for continuously producing fibers impregnated with resin after being formed through the extrusion action of a die, but no complete mechanical equipment capable of automatically producing exists in the current production equipment, so that the production equipment suitable for the carbon fiber pultrusion plate for the main beam of the wind power blade is designed intentionally.

Disclosure of Invention

The technical problem is as follows:

the existing pultrusion equipment is not perfect enough and has low automation degree.

In order to solve the problems, the embodiment designs a production device suitable for carbon fiber pultrusion plates for wind power blade girders, which comprises a machine body, wherein a rotating cavity is arranged at the upper part in the machine body, a motor is fixedly connected with the upper right wall of the rotating cavity, a hydraulic device is fixedly connected with the upper left wall of the rotating cavity, a raw material cavity is arranged at the lower right part of the rotating cavity, a pressurizing plate is slidably connected in the raw material cavity, a primary impregnation tank is arranged below the raw material cavity, an outer layer material cavity is arranged at the right side of the raw material cavity, a primary tightening device is arranged below the rotating cavity, a secondary impregnation tank is arranged at the right side of the primary tightening device, a secondary tightening device is arranged at the right side of the secondary impregnation tank, a forming die is arranged at the right side of the secondary tightening device, and during operation, raw materials are changed into a plurality of fiber bundles to flow out under the action of the pressurizing plate in the raw material, outer layer material chamber provides the tow of outer parcel, process the second grade impregnation groove, through behind the second grade tightening means fibre stick and outer parcel are screwed up together, at last the effect down the shaping, obtain complete carbon fiber pultrusion board material after the cooling, through the tensile of motor control tow and the shaping of carbon fiber board, whole process links together, has improved production efficiency.

Further, hydraulic means power is connected with the hydraulic stem, the hydraulic stem with pressure boost board fixed connection, raw materials cavity below is equipped with the hole sieve, the one-level flooding inslot internal rotation is connected with first cross axle, the first flooding wheel of first cross axle fixedly connected with, the right-hand one-level mouth that is equipped with of one-level flooding groove, the rotation is connected with the second cross axle in the one-level mouth, the first guide pulley of second cross axle fixedly connected with.

Further, outer material chamber right side below is equipped with the aperture, it is equipped with the lumen to rotate the chamber in the below, the left wall of lumen rotates and is connected with the third cross axle, the first gear of third cross axle fixedly connected with, first gear meshing have with the left gear axle sleeve that the left wall of lumen rotates and is connected, left gear axle sleeve internal rotation is connected with first minor axis and second minor axis, the first pinch roller of first minor axis fixedly connected with, second minor axis fixedly connected with second pinch roller, the lumen internal rotation is connected with the fourth cross axle, fourth cross axle fixedly connected with second guide pulley, third cross axle right-hand member fixedly connected with second gear.

Furthermore, the second gear is meshed with a third gear, the third gear is fixedly connected with a fifth cross shaft, the fifth cross shaft is fixedly connected with a fourth gear, the fourth gear is meshed with a fifth gear, the fifth gear is fixedly connected with a sixth cross shaft which is rotatably connected with the right wall of the middle cavity, and the sixth cross shaft is fixedly connected with a sixth gear.

Furthermore, a seventh cross shaft is rotatably connected in the secondary impregnation tank, the seventh cross shaft is fixedly connected with a second impregnation wheel, an eighth cross shaft is rotatably connected in the secondary impregnation tank, the eighth cross shaft is fixedly connected with a third guide wheel, a ninth cross shaft is rotatably connected to the right of the secondary impregnation tank, and the ninth cross shaft is fixedly connected with a third guide wheel.

Further, a right gear shaft sleeve is meshed with the sixth gear, a third short shaft and a fourth short shaft are rotationally connected in the right gear shaft sleeve, a third pinch roller and a fourth pinch roller are fixedly connected to the third short shaft and the fourth short shaft in a subsection manner, a first helical gear is fixedly connected to a sixth cross shaft, a second helical gear is meshed with the first helical gear, a right cross shaft is fixedly connected to the second helical gear, the right cross shaft is rotatably connected to the inner wall of a discharging cavity arranged at the lower right side of the rotating cavity, a third helical gear is fixedly connected to the right cross shaft, an upper chain wheel is fixedly connected to the right cross shaft, a chain is in transmission connection with the upper chain wheel, a lower chain wheel is fixedly connected to the lower chain wheel, the upper chain wheel is rotatably connected to the discharging cavity, an upper gear is fixedly connected to the upper cross shaft, a lower gear is meshed with the upper cross shaft, and the lower gear is fixedly connected to the lower cross shaft rotatably connected to, the upper transverse shaft and the lower transverse shaft are fixedly connected with an upper conveying wheel and a lower conveying wheel respectively.

Further, motor power is connected with the output shaft, output shaft fixedly connected with fan-shaped helical gear, fan-shaped helical gear intermittent type meshing has the fourth helical gear, fourth helical gear fixedly connected with rotate the right upper shaft that the chamber right wall rotated the connection, right upper shaft fixedly connected with cam, output shaft fixedly connected with front sprocket, the front sprocket transmission is connected with the chain, it is connected with the rear sprocket to go up the chain transmission, rear sprocket fixedly connected with rotate the chamber lower wall and rotate the vertical axis of connection, vertical axis fixedly connected with fan-shaped gear.

Furthermore, the upper wall of the discharging cavity is fixedly connected with a connecting rod, the connecting rod is fixedly connected with a feeler lever, the upper wall of the discharging cavity is slidably connected with a telescopic rod, the telescopic rod is fixedly connected with the forming die, a conveying belt is arranged below the forming die, the conveying belt is in transmission connection with a left belt pulley and a right belt pulley, the left belt pulley is fixedly connected with a left small shaft which is rotatably connected with the inner wall of the discharging cavity, the right belt pulley is fixedly connected with a right small shaft which is rotatably connected with the inner wall of the discharging cavity, a spring is fixedly connected below the feeler lever, and the spring is fixedly connected with the forming die.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic overall structure diagram of a production facility suitable for carbon fiber pultrusion plates for main beams of wind power blades, which is disclosed by the invention;

FIG. 2 is an enlarged schematic view of A in FIG. 1;

FIG. 3 is an enlarged view of B in FIG. 1;

FIG. 4 is an enlarged view of C in FIG. 1;

FIG. 5 is a schematic cross-sectional view D-D of FIG. 1;

fig. 6 is a schematic cross-sectional view of E-E in fig. 3.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to production equipment suitable for a carbon fiber pultrusion plate for a wind power blade main beam, which is mainly applied to production of the wind power blade main beam.

The invention relates to a production device of carbon fiber pultrusion plates suitable for wind power blade main beams, which comprises a machine body 10, wherein a rotating cavity 11 is arranged at the upper part in the machine body 10, a motor 27 is fixedly connected with the right upper wall of the rotating cavity 11, a hydraulic device 12 is fixedly connected with the left upper wall of the rotating cavity 11, a raw material cavity 15 is arranged at the lower right part of the rotating cavity 11, a pressurizing plate 14 is connected in the raw material cavity 15 in a sliding manner, a primary impregnation tank 44 is arranged below the raw material cavity 15, an outer layer material cavity 16 is arranged at the right side of the raw material cavity 15, a primary tightening device 39 is arranged at the middle lower part of the rotating cavity 11, a secondary impregnation tank 36 is arranged at the right side of the primary tightening device 39, a secondary tightening device 24 is arranged at the right side of the secondary impregnation tank 36, a forming die 79 is arranged at the right side of the secondary tightening device 24, and during working, raw materials are changed, the fiber bundle is soaked in the primary soaking tank 44 and then reaches the primary tightening device 39 to become a fiber rod, the outer layer material cavity 16 provides an outer layer wrapped fiber bundle, the fiber rod and the outer layer are tightly wrapped and tightened together through the secondary tightening device 24 after passing through the secondary soaking tank 36, finally, the fiber bundle is formed under the action of the 79, a complete carbon fiber pultrusion plate material is obtained after cooling, the stretching of the fiber bundle and the forming of the carbon fiber plate are controlled through the motor 27, the whole process is linked together, and the production efficiency is improved.

Preferably, the hydraulic device 12 is power-connected with a hydraulic rod 13, the hydraulic rod 13 is fixedly connected with the pressurizing plate 14, a perforated screen 46 is arranged below the raw material chamber, a first cross shaft 43 is rotatably connected to the first-stage dipping tank 44, the first cross shaft 43 is fixedly connected with a first dipping wheel 42, a first-stage port 45 is arranged on the right side of the first-stage dipping tank 44, a second cross shaft 40 is rotatably connected to the first-stage port 45, and the second cross shaft 40 is fixedly connected with a first guide wheel 41.

Preferably, a small hole 17 is formed in the lower right of the outer layer cavity 16, a middle cavity 54 is formed in the lower middle of the rotating cavity 11, a third transverse shaft 47 is rotatably connected to the left wall of the middle cavity 54, a first gear 48 is fixedly connected to the third transverse shaft 47, a left gear shaft sleeve 49 rotatably connected to the left wall of the middle cavity 54 is meshed with the first gear 48, a first short shaft 50 and a second short shaft 52 are rotatably connected to the left gear shaft sleeve 49, the first short shaft 50 is fixedly connected to a first pressure roller 51, the second short shaft 52 is fixedly connected to a second pressure roller 53, a fourth transverse shaft 19 is rotatably connected to the middle cavity 54, a second guide roller 18 is fixedly connected to the fourth transverse shaft 19, and a second gear 55 is fixedly connected to the right end of the third transverse shaft 47.

Preferably, the second gear 55 is engaged with a third gear 56, the third gear 56 is fixedly connected with a fifth horizontal shaft 21, the fifth horizontal shaft 21 is fixedly connected with a fourth gear 92, the fourth gear 92 is engaged with a fifth gear 58, the fifth gear 58 is fixedly connected with a sixth horizontal shaft 90 rotatably connected with the right wall of the middle cavity 54, and the sixth horizontal shaft 90 is fixedly connected with a sixth gear 59.

Preferably, a seventh transverse shaft 23 is rotatably connected to the secondary impregnation tank 36, the seventh transverse shaft 23 is fixedly connected to the second impregnation wheel 22, an eighth transverse shaft 37 is rotatably connected to the secondary impregnation tank 36, the eighth transverse shaft 37 is fixedly connected to the third guide wheel 38, a ninth transverse shaft 61 is rotatably connected to the right side of the secondary impregnation tank 36, and the ninth transverse shaft 61 is fixedly connected to the third guide wheel 62.

Preferably, the sixth gear 59 is engaged with a right gear shaft sleeve 63, the right gear shaft sleeve 63 is rotatably connected with a third short shaft 65 and a fourth short shaft 66, the third short shaft 65 and the fourth short shaft 66 are fixedly connected with a third pressing wheel 64 and a fourth pressing wheel 67, the sixth cross shaft 90 is fixedly connected with a first helical gear 60, the first helical gear 60 is engaged with a second helical gear 68, the second helical gear 68 is fixedly connected with a right cross shaft 93, the right cross shaft 93 is rotatably connected with the inner wall of a discharging cavity 94 arranged at the lower right of the rotating cavity 11, the right cross shaft 93 is fixedly connected with a third helical gear 84, the right cross shaft 93 is fixedly connected with an upper sprocket 85, the upper sprocket 85 is in transmission connection with a chain 86, the chain 86 is in transmission connection with a lower sprocket 87, the lower sprocket 87 is fixedly connected with an upper cross shaft 70 rotatably connected with the discharging cavity 94, the upper cross shaft 70 is fixedly connected with an upper gear 88, the upper gear 88 is engaged with a lower gear 89, the lower gear 89 is fixedly connected with a lower transverse shaft 71 which is rotatably connected with the discharging cavity, and the upper transverse shaft 70 and the lower transverse shaft 71 are respectively and fixedly connected with an upper conveying wheel 69 and a lower conveying wheel 72.

Preferably, the motor 27 is power connected with an output shaft 30, the output shaft 30 is fixedly connected with a sector bevel gear 26, the sector bevel gear 26 is intermittently meshed with a fourth bevel gear 28, the fourth bevel gear 28 is fixedly connected with a right upper shaft 29 rotatably connected with the right wall of the rotating cavity 11, the right upper shaft 29 is fixedly connected with a cam 31, the output shaft 30 is fixedly connected with a front chain wheel 25, the front chain wheel 25 is in transmission connection with an upper chain 81, the upper chain 81 is in transmission connection with a rear chain wheel 82, the rear chain wheel 82 is fixedly connected with a vertical shaft 33 rotatably connected with the lower wall of the rotating cavity 11, and the vertical shaft 33 is fixedly connected with a sector gear 83.

Preferably, the upper wall of the discharging cavity 94 is fixedly connected with a connecting rod 34, the connecting rod 34 is fixedly connected with a feeler lever 80, the upper wall of the discharging cavity 94 is slidably connected with an expansion link 32, the expansion link 32 is fixedly connected with the forming die 79, a conveyor belt 75 is arranged below the forming die, the conveyor belt 75 is in transmission connection with a left belt pulley 74 and a right belt pulley 77, the left belt pulley 74 is fixedly connected with a left small shaft 73 rotatably connected with the inner wall of the discharging cavity 94, the right belt pulley 77 is fixedly connected with a right small shaft 76 rotatably connected with the inner wall of the discharging cavity 94, a spring 78 is fixedly connected below the feeler lever 80, and the spring 78 is fixedly connected with the forming die 79.

The use steps of the production equipment suitable for the carbon fiber pultrusion plate for the wind power blade main beam are described in detail in the following with reference to fig. 1 to 6:

1. after the carbon fiber raw material is heated in the raw material cavity 15, the hydraulic device 12 is started, the hydraulic rod 13 pushes the pressurizing plate 14 downwards, the carbon fiber is changed into a plurality of fiber bundles through the hole screen 46, and the fiber bundles are soaked in the primary soaking groove 44, then the fiber bundles bypass the first soaking wheel 42, bypass the first guide wheel 41, are screwed into fiber rods under the action of the primary screwing device 39, are contacted with the outer layer material at the third guide wheel 38, are soaked together in the secondary soaking groove 36, then bypass the second soaking wheel 22, are screwed through the secondary screwing device 24, and finally are molded through the molding die 79.

2. The motor 27 is started to drive the output shaft 30 to rotate, and simultaneously drive the fan-shaped helical gear 26 to rotate, and drive the fan-shaped gear 83 to rotate through intermediate transmission, when the fan-shaped gear 83 is meshed with the third helical gear 84, the right cross shaft 93 is driven to rotate, the left gear shaft sleeve 49 is driven to rotate through intermediate transmission, and simultaneously the right gear shaft sleeve 63 is driven to rotate, and simultaneously the upper conveying wheel 69 and the lower conveying wheel 72 are driven to rotate, so that the fiber rod is driven to move forward.

3. When the fiber rod reaches the lower part of the forming die 79, the fan-shaped bevel gear 26 is meshed with the fourth bevel gear 28, the cam 31 is driven to rotate to be in contact with the telescopic rod 32, the telescopic rod 32 moves downwards to drive the forming die 79 to move downwards, the forming die 79 extrudes the fiber rod and cuts off the fiber rod to obtain the complete carbon fiber pultruded plate material, then the cam 31 is not in contact with the telescopic rod 32 any more, the forming die 79 moves upwards under the action of spring force, and the contact rod 80 moves downwards relative to the forming die 79 to push the material in the forming die 79 to move downwards to fall on the conveyor belt 75.

The invention has the beneficial effects that: according to the invention, the carbon fiber raw material is changed into the fiber bundle by increasing the pressure, the core layer raw material is impregnated and then the outer layer material is wrapped for impregnation, so that the strength of the material is effectively improved.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims (1)

1. The utility model provides a production facility suitable for wind-powered electricity generation is carbon fiber pultrusion panel for blade girder, includes the fuselage, its characterized in that:

a rotating cavity is arranged above the machine body, a motor is fixedly connected to the right upper wall of the rotating cavity, a hydraulic device is fixedly connected to the left upper wall of the rotating cavity, a raw material cavity is arranged below the right side of the rotating cavity, a pressurizing plate is slidably connected to the raw material cavity, a primary impregnation tank is arranged below the raw material cavity, an outer layer material cavity is arranged on the right side of the raw material cavity, a primary tightening device is arranged below the rotating cavity, a secondary impregnation tank is arranged on the right side of the primary tightening device, a secondary tightening device is arranged on the right side of the secondary impregnation tank, and a forming die is arranged on the right side of the secondary tightening device;

during working, raw materials are changed into a plurality of fiber bundles to flow out under the action of the pressurizing plate from the raw material cavity, the fiber bundles are soaked in the primary soaking tank and then reach the primary tightening device to form a fiber rod, the outer layer material cavity provides fiber bundles wrapped by the outer layer, the fiber rod and the outer layer are wrapped and tightened together through the secondary soaking tank and the secondary tightening device, and finally, the material is molded under the action and cooled to obtain a complete carbon fiber pultrusion plate material;

the stretching of the fiber bundles and the forming of the carbon fiber plate are controlled by the motor, and the whole process is linked together, so that the production efficiency is improved;

the hydraulic device is in power connection with a hydraulic rod, the hydraulic rod is fixedly connected with the pressurizing plate, a hole sieve is arranged below the raw material cavity, a first cross shaft is connected in the primary impregnation tank in a rotating mode, the first cross shaft is fixedly connected with a first impregnation wheel, a primary port is formed in the right side of the primary impregnation tank, a second cross shaft is connected in the primary port in a rotating mode, and the second cross shaft is fixedly connected with a first guide wheel;

a small hole is formed in the right lower portion of the outer layer cavity, a middle cavity is formed in the middle lower portion of the rotating cavity, a third transverse shaft is rotatably connected to the left wall of the middle cavity, a first gear is fixedly connected to the third transverse shaft, a left gear shaft sleeve rotatably connected to the left wall of the middle cavity is meshed with the first gear, a first short shaft and a second short shaft are rotatably connected to the left gear shaft sleeve, a first pressing wheel is fixedly connected to the first short shaft, a second pressing wheel is fixedly connected to the second short shaft, a fourth transverse shaft is rotatably connected to the middle cavity, a second guide wheel is fixedly connected to the fourth transverse shaft, and a second gear is fixedly connected to the right end of the third transverse shaft;

the second gear is meshed with a third gear, the third gear is fixedly connected with a fifth transverse shaft, the fifth transverse shaft is fixedly connected with a fourth gear, the fourth gear is meshed with a fifth gear, the fifth gear is fixedly connected with a sixth transverse shaft which is rotatably connected with the right wall of the middle cavity, and the sixth transverse shaft is fixedly connected with a sixth gear;

a seventh cross shaft is rotatably connected in the secondary impregnation tank, the seventh cross shaft is fixedly connected with a second impregnation wheel, an eighth cross shaft is rotatably connected in the secondary impregnation tank, the eighth cross shaft is fixedly connected with a third guide wheel, a ninth cross shaft is rotatably connected to the right of the secondary impregnation tank, and the ninth cross shaft is fixedly connected with a third guide wheel;

the sixth gear is meshed with a right gear shaft sleeve, a third short shaft and a fourth short shaft are rotationally connected in the right gear shaft sleeve, a third pinch roller and a fourth pinch roller are fixedly connected to the third short shaft and the fourth short shaft in a subsection manner, a first helical gear is fixedly connected to a sixth transverse shaft, a second helical gear is meshed with the first helical gear, a right transverse shaft is fixedly connected to the second helical gear, the right transverse shaft is rotatably connected with the inner wall of a discharging cavity arranged at the right lower side of the rotating cavity, a third helical gear is fixedly connected to the right transverse shaft, an upper chain wheel is fixedly connected to the right transverse shaft, a chain is connected to the right transverse shaft in a transmission manner, a lower chain wheel is fixedly connected to the chain in a transmission manner, an upper transverse shaft is fixedly connected to the discharging cavity in a rotating manner, an upper gear is fixedly connected to the upper transverse shaft, a lower gear is meshed with a lower transverse shaft rotatably connected to the discharging cavity, the upper transverse shaft and the lower transverse shaft are respectively and fixedly connected with an upper conveying wheel and a lower conveying wheel;

the motor is in power connection with an output shaft, the output shaft is fixedly connected with a sector bevel gear, the sector bevel gear is intermittently meshed with a fourth bevel gear, the fourth bevel gear is fixedly connected with a right upper shaft which is rotatably connected with the right wall of the rotating cavity, the right upper shaft is fixedly connected with a cam, the output shaft is fixedly connected with a front chain wheel, the front chain wheel is in transmission connection with an upper chain, the upper chain is in transmission connection with a rear chain wheel, the rear chain wheel is fixedly connected with a vertical shaft which is rotatably connected with the lower wall of the rotating cavity, and the vertical shaft is fixedly connected with the sector gear;

the feeding device comprises a feeding cavity, a forming die, a feeding cavity, a discharging cavity, a connecting rod, a contact rod, a telescopic rod, a conveying belt, a left belt wheel, a right belt wheel, a left small shaft, a right small shaft, a spring and a forming die, wherein the connecting rod is fixedly connected to the upper wall of the feeding cavity, the contact rod is fixedly connected to the upper wall of the feeding cavity, the telescopic rod is slidably connected to the upper wall of the feeding cavity, the forming die is fixedly connected to the telescopic rod, the conveying belt is arranged below the forming die, the conveying belt is in transmission connection with the left belt wheel and the right belt.

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