CN214869964U - Convertible positioning mechanism of wind-powered electricity generation blade mould - Google Patents

Abstract

A wind power blade die turnover type positioning mechanism comprises a base, a supporting rod, a clamping mechanism, an upper abutting assembly, a floating adjusting mechanism and a turnover mechanism; the utility model discloses tilting mechanism has been add, tilting mechanism installation transverse connection pole is passed through to the upper end of longitudinal tie pole, install the location axle in the upper end of longitudinal tie pole, install the rotating turret in transverse connection pole's the inner, so the rotating turret rotates through the rotatory hole of grafting of both sides and cup joints on the grafting short column at location axle both ends, so when needs support the upper portion and press the subassembly to remove the upset when coming out from between movable clamp plate and the locating plate, rotatory flexible screw rod on the rotatory locating piece at first, make upper portion support and press the subassembly from removing the clamp plate and go out with the upward movement between the locating plate, then utilize the rotating turret to rotate on the location axle, so realize breaking away from the upset, convenient wind-powered electricity generation blade mould settles.

Description

Convertible positioning mechanism of wind-powered electricity generation blade mould

Technical Field

The utility model relates to a convertible positioning mechanism of wind-powered electricity generation blade mould.

Background

Like aerogenerator blade in aerogenerator's accessory production, it needs to utilize the blade mould to carry out the process flow preparation such as moulding plastics, after the production of blade mould is accomplished, detect the blade mould of preparation like three-dimensional size, surface roughness and inside flaw detection etc. the blade mould of unreasonable preparation of design, the blade that can appear producing appears the gap, the bubble etc. and cause the fan blade to scrap, rework and fan blade poor quality, current structure that is used for the blade mould to detect, can not satisfy the high standard operation requirement of current aerogenerator blade mould, current blade mould supporting mechanism can not adapt different specification and size and adjust, use very flexibility and inflexibility.

Disclosure of Invention

To the weak point of above-mentioned prior art, the utility model provides a problem do: the clamping mechanism is convenient to install and can be adapted to wind power blade moulds of different specifications and sizes.

In order to solve the above problem, the utility model discloses the technical scheme who takes as follows:

a wind power blade die turnover type positioning mechanism comprises a base, a supporting rod, a clamping mechanism, an upper abutting assembly, a floating adjusting mechanism and a turnover mechanism; two supporting rods are respectively arranged on two sides of the upper end of the base; the supporting rods are respectively provided with a clamping mechanism; the clamping mechanism comprises a positioning clamping plate and a movable clamping plate; the positioning clamping plate and the movable clamping plate are arranged in parallel relatively; one side of the bottom of the movable clamping plate is slidably connected with one side of the bottom of the positioning clamping plate; the bottom of one side of the positioning clamping plate is arranged at the upper end of the supporting rod; an upper abutting assembly is arranged between the upper ends of the positioning clamping plate and the movable clamping plate; the upper pressing component comprises a positioning plate, a telescopic plate and a pressing elastic body; the middle of the inner side of the positioning plate is provided with a through connecting groove; the middle of the inner side of the expansion plate is provided with an expansion rod; a pressing elastic body is arranged in the penetration groove; the telescopic plate is inserted in the penetrating groove at the inner side of the positioning plate in a sliding manner through the telescopic rod at the inner side; the end part of the telescopic rod is abutted against the abutting elastic body; the outer sides of the positioning plate and the telescopic plate are respectively abutted against the inner walls of the positioning clamping plate and the movable clamping plate; the floating adjusting mechanism comprises a positioning block, a telescopic screw rod, a floating block, a longitudinal connecting rod and a transverse connecting rod; the positioning block is arranged on the outer side of the positioning clamping plate; a telescopic screw rod is connected to the positioning block in a threaded and rotating manner; the upper end of the telescopic screw rod is rotatably clamped with a floating block; the upper end of the floating block is provided with a longitudinal connecting rod; one side of the longitudinal connecting rod is slidably clamped and mounted on the outer side of the positioning clamp plate; the upper end of the longitudinal connecting rod is provided with a transverse connecting rod through a turnover mechanism; the outer end of the transverse connecting rod is connected to the upper side of the positioning plate; the turnover mechanism comprises a positioning shaft and a rotating frame; the upper end of the longitudinal connecting rod is provided with a positioning shaft; the two ends of the positioning shaft are provided with splicing short columns; the rotating frame is of a U-shaped structure, and two sides of the rotating frame are respectively provided with an inserting rotary hole; the inner end of the transverse connecting rod is provided with a rotating frame; the rotating frame is rotatably sleeved on the inserting short columns at the two ends of the positioning shaft through the inserting rotary holes at the two sides.

Further, the clamping mechanism also comprises a driving screw rod; one side of the bottom of the movable clamping plate is provided with a sliding block; one side of the bottom of the positioning clamping plate is provided with a sleeving block; the movable clamping plate is connected in a sleeving connection block at one side of the bottom of the positioning clamping plate in a sliding mode through a sliding block at one side of the bottom of the positioning clamping plate; a threaded channel is arranged inside the outer end of the sliding block; the drive screw rod is rotationally clamped on the sleeving block, the inner end of the drive screw rod penetrates through the sleeving block and then is in threaded connection with the inside of the threaded channel of the sliding block, and the outer end of the drive screw rod extends to the outside of the sleeving block; the upper end of the supporting rod is respectively connected to the lower side of the sleeve joint block on one side of the bottom of the positioning clamp plate.

Furthermore, the outer sides of the periphery of the driving screw are provided with rotary clamping rings; the sleeve joint block is provided with a rotary clamping ring groove; the driving screw is rotationally clamped on the rotary clamping ring groove on the sleeving block through the rotary clamping rings on the periphery of the driving screw.

Furthermore, a sliding clamping groove is formed in the outer side of the positioning clamping plate; one side of the longitudinal connecting rod is provided with a sliding clamping and connecting rod; the longitudinal connecting rod is connected to the sliding clamping groove on the outer side of the positioning clamping plate in a vertically sliding clamping mode through a sliding clamping rod on one side.

Further, the lower extreme of base evenly is equipped with the removal gyro wheel.

Furthermore, limit latch teeth are respectively arranged at the upper part and the lower part in the penetration groove; the upper part and the lower part of the telescopic rod are respectively provided with a limiting clamping groove; the limiting clamping groove slides on the limiting clamping tooth.

The beneficial effects of the utility model

The utility model discloses tilting mechanism has been add, tilting mechanism installation transverse connection pole is passed through to the upper end of longitudinal tie pole, install the location axle in the upper end of longitudinal tie pole, install the rotating turret in transverse connection pole's the inner, so the rotating turret rotates through the rotatory hole of grafting of both sides and cup joints on the grafting short column at location axle both ends, so when needs support the upper portion and press the subassembly to remove the upset when coming out from between movable clamp plate and the locating plate, rotatory flexible screw rod on the rotatory locating piece at first, make upper portion support and press the subassembly from removing the clamp plate and go out with the upward movement between the locating plate, then utilize the rotating turret to rotate on the location axle, so realize breaking away from the upset, convenient wind-powered electricity generation blade mould settles.

The utility model discloses a rotation driving screw rod for movable clamp plate slides in the piece that cup joints of locating plate bottom one side through the sliding block of bottom one side, so adjustable movable clamp plate and the centre gripping interval between the locating plate, the wind-powered electricity generation blade mould size that the adaptation is different, in addition through rotating flexible screw rod on the locating piece, drive vertical connecting rod and the same fluctuation of transverse connecting rod, thereby it reciprocates to press the subassembly to drive upper portion between movable clamp plate and locating plate, seal wind-powered electricity generation blade mould upper end, structural design is nimble ingenious.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic view of a partially enlarged structure of the side portion of the present invention.

Fig. 3 is a schematic view of the tilting mechanism of the present invention.

Fig. 4 is an enlarged schematic view of the penetration groove and the telescopic rod of the present invention.

Fig. 5 is a schematic structural view of the turnover of the upper pressing component of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 5, a wind power blade mold turnover type positioning mechanism comprises a base 1, a support rod 2, a clamping mechanism 3, an upper part pressing component 4, a floating adjusting mechanism 5 and a turnover mechanism 6; two sides of the upper end of the base 1 are respectively provided with a supporting rod 2; the supporting rods 2 are respectively provided with a clamping mechanism 3; the clamping mechanism 3 comprises a positioning clamping plate 31 and a moving clamping plate 32; the positioning clamping plate 31 and the movable clamping plate 32 are arranged in parallel; one side of the bottom of the movable clamping plate 32 is connected with one side of the bottom of the positioning clamping plate 31 in a sliding way; the bottom of one side of the positioning clamping plate 31 is arranged at the upper end of the support rod 2; an upper pressing component 4 is arranged between the upper ends of the positioning clamping plate 31 and the movable clamping plate 32; the upper pressing component 4 comprises a positioning plate 42, a telescopic plate 41 and a pressing elastic body 43; the middle of the inner side of the positioning plate 42 is provided with a through connecting groove 421; the middle of the inner side of the expansion plate 41 is provided with an expansion rod 411; the penetration groove 421 is internally provided with a pressing elastic body 43; the retractable plate 41 is slidably inserted into the through slot 421 of the inner side of the positioning plate 42 through the retractable rod 411 of the inner side; the end of the telescopic rod 411 abuts against the abutting elastic body 43; the outer sides of the positioning plate 42 and the telescopic plate 41 are respectively abutted against the inner walls of the positioning clamping plate 31 and the movable clamping plate 32; the floating adjusting mechanism 5 comprises a positioning block 51, a telescopic screw rod 52, a floating block 53, a longitudinal connecting rod 54 and a transverse connecting rod 55; the positioning block 51 is arranged on the outer side of the positioning splint 31; a telescopic screw rod 52 is in threaded rotary connection with the positioning block 51; the upper end of the telescopic screw rod 52 is rotatably clamped with a floating block 53; the upper end of the floating block 53 is provided with a longitudinal connecting rod 54; one side of the longitudinal connecting rod 54 is slidably clamped and installed on the outer side of the positioning clamping plate 31; the upper end of the longitudinal connecting rod 54 is provided with a transverse connecting rod 55 through the turnover mechanism 6; the outer end of the transverse connecting rod 55 is connected to the upper side of the positioning plate 42; the turnover mechanism 6 comprises a positioning shaft 62 and a rotating frame 61; the upper end of the longitudinal connecting rod 54 is provided with a positioning shaft 62; the two ends of the positioning shaft 62 are provided with plug-in short columns 621; the rotating frame 61 is of a U-shaped structure, and two sides of the rotating frame 61 are respectively provided with an inserting rotary hole 611; the inner end of the transverse connecting rod 55 is provided with a rotating frame 61; the rotating frame 61 is rotatably sleeved on the plug short columns 621 at the two ends of the positioning shaft 62 through the plug rotating holes 611 at the two sides.

As shown in fig. 1 to 5, further, the clamping mechanism 3 further includes a drive screw 33; a sliding block 321 is arranged at one side of the bottom of the movable clamping plate 32; one side of the bottom of the positioning clamp plate 31 is provided with a sleeving connection block 311; the movable clamping plate 32 is connected in a sliding way in the socket block 311 on one side of the bottom of the positioning clamping plate 31 through a sliding block 321 on one side of the bottom; a thread channel 322 is arranged inside the outer end of the sliding block 321; the driving screw 33 is rotatably clamped on the sleeving block 311, the inner end of the driving screw 33 penetrates through the sleeving block 311 and then is in threaded connection with the threaded channel 322 of the sliding block 321, and the outer end of the driving screw 33 extends to the outside of the sleeving block 311; the upper ends of the support rods 2 are respectively connected to the lower sides of the sleeve-joint blocks 311 on one side of the bottom of the positioning clamp plate 31. Further, the outer sides of the periphery of the driving screw 33 are provided with rotary clamping rings; the sleeve joint block is provided with a rotary clamping ring groove; the driving screw rod 33 is rotationally clamped on the rotary clamping ring groove on the sleeving block through the rotary clamping rings on the periphery and the outer side. Further, a sliding clamping groove 313 is arranged on the outer side of the positioning clamping plate 31; a sliding clamping connection rod 541 is arranged at one side of the longitudinal connection rod 54; the longitudinal connecting rod 54 is vertically slidably engaged with the sliding engaging groove 313 on the outer side of the positioning clamp plate 31 through a sliding engaging rod 541 on one side. Further, the lower end of the base 1 is uniformly provided with a movable roller 11. Furthermore, the upper part and the lower part of the inside of the penetration groove 421 are respectively provided with a limit clip 422 tooth; the upper part and the lower part of the telescopic rod 411 are respectively provided with a limiting clamping groove 412; the limit slots 412 slide on the limit teeth 422.

The utility model discloses tilting mechanism 6 has been add, tilting mechanism 6 installation transverse connection pole 55 is passed through to the upper end of longitudinal tie 54, install location axle 62 in the upper end of longitudinal tie 54, install rotating turret 61 in the inner of transverse connection pole 55, so rotating turret 61 rotates through the rotatory hole 611 of grafting of both sides and cup joints on the grafting short column 621 at location axle 62 both ends, so when needs support upper portion to press subassembly 4 from removing the upset between movable clamp plate 32 and the location splint 31 and come out, at first rotatory telescopic screw 52 on the rotatory locating piece 51, make upper portion support to press subassembly 4 from removing movable clamp plate 32 and location splint 31 between upwards removing, then utilize rotating turret 61 to rotate on location axle 62, so realize breaking away from the upset, facilitate the blade mould to settle.

The utility model discloses a rotation driving screw 33 for sliding block 321 that movable clamp plate 32 passes through bottom one side slides in the piece 311 that cup joints of positioning clamp plate 31 bottom one side, so adjustable movable clamp plate 32 and the centre gripping interval between the positioning clamp plate 31, the wind-powered electricity generation blade mould size that the adaptation is different, in addition through rotating telescopic screw 52 on locating piece 51, drive vertical connecting rod 54 and the same fluctuation of transverse connection pole 55, thereby it reciprocates to drive upper portion to press subassembly 4 between movable clamp plate 32 and positioning clamp plate 31, carry out the closure to wind-powered electricity generation blade mould upper end, structural design is nimble ingenious.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. A wind power blade die turnover type positioning mechanism is characterized by comprising a base, a supporting rod, a clamping mechanism, an upper part abutting assembly, a floating adjusting mechanism and a turnover mechanism; two supporting rods are respectively arranged on two sides of the upper end of the base; the supporting rods are respectively provided with a clamping mechanism; the clamping mechanism comprises a positioning clamping plate and a movable clamping plate; the positioning clamping plate and the movable clamping plate are arranged in parallel relatively; one side of the bottom of the movable clamping plate is slidably connected with one side of the bottom of the positioning clamping plate; the bottom of one side of the positioning clamping plate is arranged at the upper end of the supporting rod; an upper abutting assembly is arranged between the upper ends of the positioning clamping plate and the movable clamping plate; the upper pressing component comprises a positioning plate, a telescopic plate and a pressing elastic body; the middle of the inner side of the positioning plate is provided with a through connecting groove; the middle of the inner side of the expansion plate is provided with an expansion rod; a pressing elastic body is arranged in the penetration groove; the telescopic plate is inserted in the penetrating groove at the inner side of the positioning plate in a sliding manner through the telescopic rod at the inner side; the end part of the telescopic rod is abutted against the abutting elastic body; the outer sides of the positioning plate and the telescopic plate are respectively abutted against the inner walls of the positioning clamping plate and the movable clamping plate; the floating adjusting mechanism comprises a positioning block, a telescopic screw rod, a floating block, a longitudinal connecting rod and a transverse connecting rod; the positioning block is arranged on the outer side of the positioning clamping plate; a telescopic screw rod is connected to the positioning block in a threaded and rotating manner; the upper end of the telescopic screw rod is rotatably clamped with a floating block; the upper end of the floating block is provided with a longitudinal connecting rod; one side of the longitudinal connecting rod is slidably clamped and mounted on the outer side of the positioning clamp plate; the upper end of the longitudinal connecting rod is provided with a transverse connecting rod through a turnover mechanism; the outer end of the transverse connecting rod is connected to the upper side of the positioning plate; the turnover mechanism comprises a positioning shaft and a rotating frame; the upper end of the longitudinal connecting rod is provided with a positioning shaft; the two ends of the positioning shaft are provided with splicing short columns; the rotating frame is of a U-shaped structure, and two sides of the rotating frame are respectively provided with an inserting rotary hole; the inner end of the transverse connecting rod is provided with a rotating frame; the rotating frame is rotatably sleeved on the inserting short columns at the two ends of the positioning shaft through the inserting rotary holes at the two sides.

2. The wind blade mold turnover positioning mechanism according to claim 1, wherein the clamping mechanism further comprises a drive screw; one side of the bottom of the movable clamping plate is provided with a sliding block; one side of the bottom of the positioning clamping plate is provided with a sleeving block; the movable clamping plate is connected in a sleeving connection block at one side of the bottom of the positioning clamping plate in a sliding mode through a sliding block at one side of the bottom of the positioning clamping plate; a threaded channel is arranged inside the outer end of the sliding block; the drive screw rod is rotationally clamped on the sleeving block, the inner end of the drive screw rod penetrates through the sleeving block and then is in threaded connection with the inside of the threaded channel of the sliding block, and the outer end of the drive screw rod extends to the outside of the sleeving block; the upper end of the supporting rod is respectively connected to the lower side of the sleeve joint block on one side of the bottom of the positioning clamp plate.

3. The turnover type positioning mechanism for the wind power blade mold according to claim 2, wherein a rotary clamping ring is arranged on the outer side of the periphery of the driving screw; the sleeve joint block is provided with a rotary clamping ring groove; the driving screw is rotationally clamped on the rotary clamping ring groove on the sleeving block through the rotary clamping rings on the periphery of the driving screw.

4. The turnover type positioning mechanism for the wind power blade mold according to claim 1, wherein a sliding clamping groove is formed in the outer side of the positioning clamping plate; one side of the longitudinal connecting rod is provided with a sliding clamping and connecting rod; the longitudinal connecting rod is connected to the sliding clamping groove on the outer side of the positioning clamping plate in a vertically sliding clamping mode through a sliding clamping rod on one side.

5. The turnover type positioning mechanism for the wind power blade mold according to claim 1, wherein the lower end of the base is uniformly provided with moving rollers.

6. The turnover type positioning mechanism for the wind power blade die as claimed in claim 1, wherein limiting latch teeth are respectively arranged at the upper and lower parts in the penetration groove; the upper part and the lower part of the telescopic rod are respectively provided with a limiting clamping groove; the limiting clamping groove slides on the limiting clamping tooth.

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