阅读说明：本技术 一种高精度vr头盔制造用组装装配线 (High accuracy VR helmet is made with equipment assembly line ) 是由 龚翱 成运 王洁 于 2020-12-08 设计创作，主要内容包括：本发明公开了一种高精度VR头盔制造用组装装配线,涉及VR头盔生产技术技术领域。本发明包括旋转装置、支架、升降装置、支撑装置、传送装置以及限位装置,承载板下表面与上底板上表面焊接,两滑杆一端均与承载板下表面焊接,主动齿轮与旋转轴旋转配合,转动座上表面与承载板下表面连接,螺纹杆与转动座旋转配合,插销与圆孔连接。本发明通过设置升降柱以及减震弹簧,以及第一固定板以及第二固定板之间的旋转配合,使得可以提供一种可以调节角度的传送设备,通过设置旋转装置,使竖向传送线可以周期性转变方向,通过设置支架以及升降装置,通过螺纹杆的转动使承载器能带着工件进行竖向传送,并且设有滑杆限制承载器水平方向的转动。(The invention discloses an assembly line for manufacturing a high-precision VR helmet, and relates to the technical field of VR helmet production. The invention comprises a rotating device, a bracket, a lifting device, a supporting device, a conveying device and a limiting device, wherein the lower surface of a bearing plate is welded with the upper surface of an upper bottom plate, one ends of two sliding rods are welded with the lower surface of the bearing plate, a driving gear is rotationally matched with a rotating shaft, the upper surface of a rotating seat is connected with the lower surface of the bearing plate, a threaded rod is rotationally matched with the rotating seat, and a bolt is connected with a circular hole. The invention can provide the conveying equipment with the adjustable angle by arranging the lifting column and the damping spring and the rotary matching between the first fixing plate and the second fixing plate, the direction of a vertical conveying line can be periodically changed by arranging the rotating device, the carrier can carry a workpiece to carry out vertical conveying by rotating the threaded rod by arranging the bracket and the lifting device, and the sliding rod is arranged to limit the horizontal rotation of the carrier.)

1. The utility model provides a high accuracy VR helmet is made with equipment assembly line, includes rotary device (100), support (200), elevating gear (300), strutting arrangement (400), conveyer (500) and stop device (600), its characterized in that: the rotating device (100) comprises a lower bottom plate (110), a rotating seat (120), a circular shaft (130) and an upper bottom plate (140), the lower surface of the rotating seat (120) is connected with the upper surface of the lower bottom plate (110), the circular shaft (130) is in rotating fit with the rotating seat (120), one end of the circular shaft (130) is welded with the lower surface of the upper bottom plate (140), the bracket (200) comprises a bearing plate (210), sliding rods (220) and a lifting motor (240), the lower surface of the bearing plate (210) is welded with the upper surface of the upper bottom plate (140), one ends of the two sliding rods (220) are welded with the lower surface of the bearing plate (210), the other ends of the two sliding rods (220) are welded with the upper surface of the upper bottom plate (140), the lifting motor (240) is provided with a rotating shaft, the lifting device (300) comprises a driving gear (310), a rotating seat (330) and, driving gear (310) and the rotatory cooperation of rotation axis, it is connected with loading board (210) lower surface to rotate seat (330), threaded rod (340) with rotate seat (330) rotatory cooperation, strutting arrangement (400) include first fixed plate (430), second fixed plate (440) and bolt (450), first fixed plate (430) and second fixed plate (440) side surface all are equipped with the round hole, bolt (450) are connected with the round hole, conveyer (500) include backup pad (560), and are a plurality of second fixed plate (440) upper surface all with backup pad (560) lower surface welding, stop device (600) include connecting rod (620), two connecting rod (620) one end all with backup pad (560) upper surface connection.

2. The assembly line for manufacturing high-precision VR helmets according to claim 1, wherein: the rotating device (100) further comprises a positive and negative motor (150), a rotating plate (160), a guide rod (170), a guide column (180) and a rotating plate (190), wherein the lower surface of the positive and negative motor (150) is welded with the upper surface of the lower base plate (110), the positive and negative motor (150) is provided with a rotating shaft, the rotating plate (160) is in rotating fit with the rotating shaft, one end of the guide rod (170) is connected with the outer surface of the rotating plate (160), the lower surface of the guide column (180) is welded with the upper surface of the guide rod (170), the rotating plate (190) is in rotating fit with the circular shaft (130), the upper surface of the rotating plate (190) is provided with a plurality of grooves, and the guide column (180) is in sliding fit with.

3. The assembly line for manufacturing high-precision VR helmets according to claim 1, wherein: the support (200) further comprises a loader (230), a threaded hole is formed in the upper surface of the loader (230), the threaded hole is in rotating fit with the threaded rod (340), two sliding holes are formed in the upper surface of the loader (230), and the two sliding holes are in sliding fit with the two sliding rods (220) respectively.

4. The assembly line for manufacturing high-precision VR helmets according to claim 1, wherein: the lifting device (300) further comprises a driven gear (320), the driven gear (320) is meshed with the driving gear (310), and the driven gear (320) is in rotating fit with the threaded rod (340).

5. The assembly line for manufacturing high-precision VR helmets according to claim 1, wherein: the supporting device (400) further comprises a lifting column (410) and a plurality of damping springs (420), the lower surfaces of the damping springs (420) are respectively connected with the upper surfaces of the lifting column (410), and the lower surfaces of the first fixing plates (430) are respectively connected with the upper surfaces of the damping springs (420).

6. The assembly line for manufacturing high-precision VR helmets according to claim 1, wherein: the conveying device (500) further comprises a first conveying roller (510), a second conveying roller (520), a conveying belt (530), a wheel shaft (540) and fixing rods (550), wherein the inner surface of the wheel shaft (540) is respectively connected with the outer surface of the first conveying roller (510) and the outer surface of the second conveying roller (520), one end of each fixing rod (550) is respectively welded with the outer surfaces of the wheel shafts (540), the other end of each fixing rod (550) is welded with the upper surface of the supporting plate (560), the conveying belt (530) is in rotating fit with the first conveying roller (510), and the second conveying roller (520) is in rotating fit with the conveying belt (530).

7. The assembly line for manufacturing high-precision VR helmets according to claim 1, wherein: stop device (600) still include limiting plate (610) and fixing bolt (630), two the connecting rod (620) other end respectively with two limiting plate (610) side surface connections, two connecting rod (620) upper surface all is equipped with a plurality of mounting holes, and is a plurality of fixing bolt (630) are connected with a plurality of mounting holes respectively.

Technical Field

The invention belongs to the technical field of VR helmet production, and particularly relates to an assembly line for manufacturing a high-precision VR helmet.

Background

The VR technology is a virtual reality technology, also called smart technology, which is a brand-new practical technology developed in the 20 th century, the virtual reality technology includes a computer, electronic information and a simulation technology, and the basic implementation mode is that the computer simulates a virtual environment so as to bring people with environmental immersion.

The assembly line for manufacturing the VR helmet in the prior art has the defects of no automatic steering device, no vertical lifting means, no position adjustment during transverse conveying and the like, and therefore the assembly line for manufacturing the high-precision VR helmet is provided.

Disclosure of Invention

The invention aims to provide an assembly line for manufacturing a high-precision VR helmet, which solves the problems that an existing assembly line is not provided with an automatic steering device, a vertical lifting means and a position adjusting device during transverse conveying.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to an assembly line for manufacturing a high-precision VR helmet, which comprises a rotating device, a support, a lifting device, a supporting device, a conveying device and a limiting device, wherein the rotating device comprises a lower bottom plate, a rotating seat, a round shaft and an upper bottom plate, the lower surface of the rotating seat is connected with the upper surface of the lower bottom plate, the round shaft is in rotating fit with the rotating seat, one end of the round shaft is welded with the lower surface of the upper bottom plate, the support comprises a bearing plate, sliding rods and a lifting motor, the lower surface of the bearing plate is welded with the upper surface of the upper bottom plate, one ends of the two sliding rods are both welded with the lower surface of the bearing plate, the other ends of the two sliding rods are both welded with the upper surface of the upper bottom plate, the lifting motor is provided with a rotating shaft, the lifting device comprises a driving gear, a, the threaded rod and the rotating seat are in rotating fit, the supporting device comprises a first fixing plate, a second fixing plate and a bolt, a round hole is formed in one side surface of the first fixing plate and one side surface of the second fixing plate, the bolt is connected with the round hole, the conveying device comprises a supporting plate and a plurality of supporting plates, the upper surface of the second fixing plate is welded to the lower surface of the supporting plate, the limiting device comprises a connecting rod, and one end of each of the two connecting rods is connected with the upper surface of the supporting plate.

Preferably, rotary device still includes positive and negative motor, rotor plate, guide bar, guide post and rotor plate, positive and negative motor lower surface and lower plate upper surface welding, positive and negative motor is equipped with the axis of rotation, rotor plate and axis of rotation normal running fit, guide bar one end and rotor plate surface connection, guide post lower surface and guide bar upper surface welding, rotor plate and round axle normal running fit, the rotor plate upper surface is equipped with a plurality of recesses, guide post and recess sliding fit, rotary device's effect is the reciprocal rotation that provides the horizontal direction, slides in the recess through the guide post, makes the rotor plate rotate.

Preferably, the support further comprises a loader, a threaded hole is formed in the upper surface of the loader, the threaded hole is in rotating fit with the threaded rod, two sliding holes are formed in the upper surface of the loader, the two sliding holes are in sliding fit with the two sliding rods respectively, the loader is in rotating fit with the threaded rod, and the sliding rods are used for limiting the position of the loader and are not allowed to rotate together with the threaded rod.

Preferably, elevating gear still includes driven gear, driven gear and driving gear meshing, driven gear and threaded rod normal running are provided power for vertical transmission to elevating gear's effect.

Preferably, strutting arrangement still includes lift post and damping spring, and is a plurality of the damping spring lower surface respectively with a plurality of lift post upper surface connections, a plurality of first fixed plate lower surface respectively with a plurality of damping spring upper surface connections, wherein, strutting arrangement has four, and the lift post can height-adjusting to the angle of regulation horizontal direction conveying can adapt to the not conveying of co-altitude.

Preferably, conveyer still includes first transfer roller, second transfer roller, conveyer belt, shaft and dead lever, and is a plurality of shaft internal surface respectively with first transfer roller surface and second transfer roller surface connection, a plurality of dead lever one end respectively with a plurality of shaft surface welding, a plurality of the dead lever other end all with backup pad upper surface welding, conveyer belt and first transfer roller normal running fit, second transfer roller and conveyer belt normal running fit, wherein, shaft and dead lever all have four, and shaft and dead lever cooperate for fixed first transfer roller and second transfer roller.

Preferably, the limiting device further comprises a limiting plate and a fixing bolt, the other end of the connecting rod is connected with one side surface of the two limiting plates respectively, the upper surface of the connecting rod is provided with a plurality of mounting holes, the fixing bolt is connected with the mounting holes respectively, and the limiting device is used for limiting the position of a conveyed workpiece, so that the workpiece is neat and convenient to subsequently process.

The invention has the following beneficial effects:

1. according to the invention, the lifting column and the damping spring are arranged, and the first fixing plate and the second fixing plate are in rotating fit with each other, so that the conveying equipment with the adjustable angle can be provided, and the conveyed workpieces are tidy and ordered through the limiting device.

2. The vertical conveying line can periodically change the direction by arranging the rotating device, and is more convenient to carry without manpower, wherein four wheel shafts and four fixing rods are arranged, and the wheel shafts are matched with the fixing rods and are used for fixing the first conveying roller and the second conveying roller.

3. According to the invention, through the arrangement of the bracket and the lifting device, the workpiece can be driven by the carrier to be vertically conveyed through the rotation of the threaded rod, the sliding rod is arranged to limit the rotation of the carrier in the horizontal direction, and the limiting device is used for limiting the position of the conveyed workpiece to enable the conveyed workpiece to be tidy and convenient for subsequent processing.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic overall structure diagram of an assembly line for manufacturing a high-precision VR helmet according to the present invention;

FIG. 2 is an isometric view of an assembly line for manufacturing a high precision VR helmet in accordance with the present invention;

FIG. 3 is a schematic structural diagram of a rotating device of an assembly line for manufacturing a high-precision VR helmet according to the present invention;

FIG. 4 is a schematic structural diagram of a support and a lifting device of an assembly line for manufacturing a high-precision VR helmet according to the present invention;

FIG. 5 is a schematic structural diagram of a lifting device of an assembly line for manufacturing high-precision VR helmets according to the present invention;

fig. 6 is a schematic structural diagram of a conveying device and a limiting device of an assembly line for manufacturing a high-precision VR helmet according to the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

100. a rotating device; 110. a lower base plate; 120. a rotating base; 130. a circular shaft; 140. an upper base plate; 150. a positive and negative motor; 160. a rotating plate; 170. a guide rod; 180. a guide post; 190. a rotating plate; 200. a support; 210. a carrier plate; 220. a slide bar; 230. a carrier; 240. a lifting motor; 300. a lifting device; 310. a driving gear; 320. a driven gear; 330. a rotating seat; 340. a threaded rod; 400. a support device; 410. a lifting column; 420. a damping spring; 430. a first fixing plate; 440. a second fixing plate; 450. a bolt; 500. a conveying device; 510. a first transfer roller; 520. a second transfer roller; 530. a conveyor belt; 540. a wheel axle; 550. fixing the rod; 560. a support plate; 600. a limiting device; 610. a limiting plate; 620. a connecting rod; 630. and (5) fixing the bolt.

Detailed Description

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

In the description of the present invention, it is to be understood that the terms "upper", "middle", "outer", "inner", "lower", "around", and the like, indicate orientations or positional relationships, are used merely to facilitate the description of the present invention and to simplify the description, and do not indicate or imply that the referenced components or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be taken as limiting the present invention.

Example one

Referring to fig. 1-6, the present invention is an assembly line for manufacturing a high precision VR helmet, including a rotation device 100, a support 200, a lifting device 300, a supporting device 400, a transmitting device 500, and a limiting device 600, wherein the rotation device 100 includes a lower plate 110, a rotation base 120, a circular shaft 130, and an upper plate 140, a lower surface of the rotation base 120 is connected to an upper surface of the lower plate 110, the circular shaft 130 is rotatably engaged with the rotation base 120, one end of the circular shaft 130 is welded to a lower surface of the upper plate 140, the support 200 includes a bearing plate 210, a sliding rod 220, and a lifting motor 240, a lower surface of the bearing plate 210 is welded to an upper surface of the upper plate 140, one end of each of the two sliding rods 220 is welded to a lower surface of the bearing plate 210, the other end of each of the two sliding rods 220 is welded to an upper surface of the upper plate 140, the lifting motor 240 has a rotation, rotate seat 330 upper surface and bearing board 210 lower surface and be connected, threaded rod 340 and the rotatory cooperation of rotating seat 330, strutting arrangement 400 includes first fixed plate 430, second fixed plate 440 and bolt 450, first fixed plate 430 and second fixed plate 440 side surface all are equipped with the round hole, bolt 450 is connected with the round hole, conveyer 500 includes backup pad 560, a plurality of second fixed plate 440 upper surfaces all with backup pad 560 lower surface welding, stop device 600 includes connecting rod 620, two connecting rod 620 one end all with backup pad 560 upper surface connection.

Further, the rotating device 100 further comprises a positive and negative motor 150, a rotating plate 160, a guide rod 170, a guide post 180 and a rotating plate 190, the lower surface of the positive and negative motor 150 is welded with the upper surface of the lower base plate 110, the positive and negative motor 150 is provided with a rotating shaft, the rotating plate 160 is in rotating fit with the rotating shaft, one end of the guide rod 170 is connected with the outer surface of the rotating plate 160, the lower surface of the guide post 180 is welded with the upper surface of the guide rod 170, the rotating plate 190 is in rotating fit with the circular shaft 130, the upper surface of the rotating plate 190 is provided with a plurality of grooves, the guide post 180 is in sliding fit with the grooves, the rotating device 100 is used for providing reciprocating rotation in the horizontal direction.

Further, the bracket 200 further includes a carrier 230, the upper surface of the carrier 230 is provided with a threaded hole, the threaded hole is rotatably engaged with the threaded rod 340, the upper surface of the carrier 230 is provided with two sliding holes, the two sliding holes are respectively slidably engaged with the two sliding rods 220, the carrier 230 is rotatably engaged with the threaded rod 340, and the sliding rods 220 are used for limiting the position of the carrier 230 and preventing the carrier 230 from rotating together with the threaded rod 340.

Further, the lifting device 300 further comprises a driven gear 320, the driven gear 320 is meshed with the driving gear 310, the driven gear 320 is in rotating fit with the threaded rod 340, and the lifting device 300 is used for providing power for vertical transmission to enable the lifting device to normally operate.

Further, strutting arrangement 400 still includes lift post 410 and damping spring 420, a plurality of damping spring 420 lower surfaces respectively with a plurality of lift post 410 surface connection, a plurality of first fixed plate 430 lower surfaces respectively with a plurality of damping spring 420 surface connection, wherein, strutting arrangement 400 has four, lift post 410 can height-adjusting to adjust the angle of horizontal direction conveying, can adapt to the not conveying of co-altitude.

Further, the conveying device 500 further includes a first conveying roller 510, a second conveying roller 520, a conveying belt 530, a plurality of wheel shafts 540 and fixing rods 550, the inner surfaces of the plurality of wheel shafts 540 are respectively connected with the outer surface of the first conveying roller 510 and the outer surface of the second conveying roller 520, one ends of the plurality of fixing rods 550 are respectively welded with the outer surfaces of the plurality of wheel shafts 540, the other ends of the plurality of fixing rods 550 are respectively welded with the upper surface of the supporting plate 560, the conveying belt 530 is rotatably matched with the first conveying roller 510, the second conveying roller 520 is rotatably matched with the conveying belt 530, wherein four of the wheel shafts 540 and the four fixing rods 550 are provided, and the wheel shafts 540 are matched with the fixing rods 550 to fix the.

Further, stop device 600 still includes limiting plate 610 and fixing bolt 630, and two connecting rod 620 other ends are connected with two limiting plate 610 side surface respectively, and two connecting rod 620 upper surfaces all are equipped with a plurality of mounting holes, and a plurality of fixing bolt 630 are connected with a plurality of mounting holes respectively, and stop device 600's effect is the position of the work piece of restriction conveying, makes it neat, is convenient for follow-up processing.

Example two

Referring to fig. 1 to 6, the present invention provides a conveying apparatus capable of adjusting an angle by providing the lifting column 410 and the damping spring 420, and the rotation cooperation between the first fixing plate 430 and the second fixing plate 440, and the conveyed workpieces are ordered by the limiting device 600, and the direction of the vertical conveying line can be periodically changed by providing the rotating device 100, so that the conveying is not required to be carried by manpower, which is more convenient, by providing the support 200 and the lifting device 300, the carrier 230 can carry the workpieces to be conveyed vertically by the rotation of the threaded rod 340, and the sliding rod 220 is provided to limit the rotation of the carrier 230 in the horizontal direction.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.