CN112061786A - Vertical transportation equipment for hollow glass finished products - Google Patents

Abstract

The invention discloses vertical transportation equipment for a hollow glass finished product, which comprises a rack, a moving frame, a transportation mechanism, an adjusting assembly and a wheel leaning mechanism, wherein the moving frame is arranged on the rack; first belt conveyor and second belt conveyor carry out synchronous operation through drive assembly, stability when guaranteeing cavity glass transportation, and first belt conveyor and second belt conveyor accept the long limit in bottom both sides after glass is put immediately, and intermediate layer position is unsettled, effectively avoids intermediate layer's binder and equipment to take place the contact, guarantees product quality. Meanwhile, the position of the conveying mechanism is regulated and controlled by the adjusting component, so that the hollow glass with different thicknesses and sizes can be conveyed at the same height, and the subsequent stations can process the hollow glass conveniently.

Description

Vertical transportation equipment for hollow glass finished products

Technical Field

The invention relates to glass transportation equipment, in particular to vertical transportation equipment for hollow glass finished products.

Background

The general hollow glass is made by bonding two or three sheets of glass by an adhesive. In order to match station operation on a production line in the production process, the hollow glass needs to be vertically and obliquely placed and transported, and the adhesive on the edge of the interlayer of the hollow glass is easy to adhere to a transportation belt in the transportation process. Therefore, a device which can facilitate the vertical conveying of the hollow glass needs to be designed.

Disclosure of Invention

The present invention is directed to solving, at least to some extent, one of the above-mentioned problems in the related art. Therefore, the invention provides vertical type transportation equipment for hollow glass finished products.

In order to achieve the purpose, the technical scheme of the invention is as follows:

according to the first aspect of the invention, the vertical transportation equipment for the finished hollow glass product comprises:

the rack is provided with a movable rack in a sliding way;

the conveying mechanism is arranged on the moving frame and comprises a first belt conveying device, a second belt conveying device and a driving assembly, the first belt conveying device and the second belt conveying device are obliquely arranged mutually, the conveying directions are in the same direction, a V shape with a large opening end facing upwards is formed between the conveying surfaces of the first belt conveying device and the second belt conveying device, and the driving assembly drives the first belt conveying device and the second belt conveying device to synchronously convey in the same direction; the adjusting assembly is arranged between the rack and the moving frame and drives the moving frame to perform inclined lifting movement on the rack;

the idler wheel mechanism is obliquely arranged above the conveying mechanism and comprises a support and a plurality of pulleys arranged on the support.

According to the embodiment of the invention, the vertical type transportation equipment for the finished hollow glass products at least has the following beneficial effects: first belt conveyor and second belt conveyor carry out synchronous operation through drive assembly, stability when guaranteeing cavity glass transportation, and first belt conveyor and second belt conveyor accept the long limit in bottom both sides after glass is put immediately, and intermediate layer position is unsettled, effectively avoids intermediate layer's binder and equipment to take place the contact, guarantees product quality. Meanwhile, the position of the conveying mechanism is regulated and controlled by the adjusting component, so that the hollow glass with different thicknesses and sizes can be conveyed at the same height, and the subsequent stations can process the hollow glass conveniently.

According to some embodiments of the invention, the driving assembly comprises a bevel gear transmission set and a first motor, the bevel gear transmission set is installed on the same rotating shaft of the first belt conveyor and the second belt conveyor, and the first motor drives the bevel gear transmission set to rotate so that the first belt conveyor and the second belt conveyor run synchronously.

According to some embodiments of the present invention, each of the first belt conveyor and the second belt conveyor includes a driving rotating shaft and a driven rotating shaft, the driving assembly is connected to the driving rotating shaft, the driven rotating shaft is rotatably connected to a movable frame through a tensioning assembly, the tensioning assembly includes a connecting shaft, a mounting seat, a first adjusting screw and a locking screw, the mounting seat is fixed on the movable frame, the mounting seat is provided with a sliding groove, the connecting shaft is coaxially connected to the driven rotating shaft, the connecting shaft is inserted into the sliding groove, the first adjusting screw passes through the mounting seat and is radially and threadedly connected to the connecting shaft, and the locking screw is threadedly connected to the mounting seat, and one end of the locking screw extends into the sliding groove and abuts against a side wall of the first adjusting screw.

According to some embodiments of the invention, the first belt conveyor and the second belt conveyor are connected with the moving frame through a connecting plate, the connecting plate is provided with an elliptical hole, and a second adjusting screw is arranged between the bottom of the connecting plate and the moving frame.

According to some embodiments of the invention, the adjusting assembly comprises an adjusting screw rod and a second motor, the adjusting screw rod is connected between the moving frame and the machine frame, and the second motor drives the adjusting screw rod to rotate so as to drive the moving frame to perform inclined lifting movement along the guide rail on the machine frame.

According to some embodiments of the invention, the adjusting screw rod is sleeved with a first hinge frame and a second hinge frame, the first hinge frame is hinged on the frame, and the second hinge frame is hinged on the movable frame.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

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

FIG. 2 is a left side view of a portion of the structure of the present invention;

FIG. 3 is a perspective view of a portion of the present invention;

FIG. 4 is an enlarged partial schematic view of FIG. 3;

FIG. 5 is a schematic view of the present invention showing a comparison of the transport heights of hollow glass sheets of different thicknesses;

FIG. 6 is a schematic view of the construction of the driven shaft side of the present invention;

fig. 7 is a partially enlarged schematic view of fig. 3.

Reference numerals: a frame 110; a guide rail 111; a moving frame 120; a transport mechanism 200; a first belt conveyor 210; a second belt conveyor 220; a drive assembly 300; an adjustment assembly 400; a wheel leaning mechanism 500; a holder 510; a pulley 520; a bevel gear drive set 310; a first motor 320; a driving shaft 201; a driven rotation shaft 202; a tension assembly 600; a connecting shaft 610; a mounting seat 620; a first adjusting screw 630; a locking screw 640; a chute 621; a connection plate 710; an elliptical hole 720; a second adjusting screw 730; an adjusting screw 410; a second motor 420; a first hinge frame 430; a second hinge frame 440; hollow glass 800.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

As shown in fig. 1, the vertical transportation device for the hollow glass product comprises a frame 110, a moving frame 120, a transportation mechanism 200, an adjusting assembly 400 and a wheel leaning mechanism 500.

As shown in fig. 2, the frame 110 has a guide rail 111 provided obliquely, and the moving frame 120 is slidably attached to the frame 110 via the guide rail 111 and moves up and down in an oblique direction along the guide rail 111. The adjusting assembly 400 is installed between the frame 110 and the moving frame 120, and the position of the moving frame 120 moving on the frame 110 is adjusted and controlled by the adjusting assembly 400. The transport mechanism 200 is mounted on the moving frame 120, and includes a first belt conveyor 210, a second belt conveyor 220, and a driving assembly 300. The long edge directions of the first belt conveyor 210 and the second belt conveyor 220 are parallel to each other, the conveying surfaces of the first belt conveyor 210 and the second belt conveyor 220 are inclined to form a V-shape with a large opening end facing upwards, and the long edges of the first belt conveyor 210 and the second belt conveyor 220 which are located at the bottom of the V-shape and correspond to each other are close to each other. The driving assembly 300 drives the first belt conveyor 210 and the second belt conveyor 220 to run synchronously at the same direction and speed. The wheel-riding mechanism 500 is obliquely installed on the frame 110 and located above the transportation mechanism 200, and the wheel-riding mechanism 500 comprises a bracket 510 and a plurality of riding wheels installed on the bracket 510.

The following description will take an example of a hollow glass 800 formed by molding two pieces of glass. In operation, as shown in fig. 5, the hollow glass 800 is vertically placed on the transportation mechanism 200, the left edge of the bottom of the vertically placed hollow glass 800 abuts against the transportation surface of the first belt transportation device 210, the right edge of the bottom of the vertically placed hollow glass 800 abuts against the transportation surface of the second belt transportation device 220, and the middle interlayer of the hollow glass 800 is suspended between the first belt transportation device 210 and the second belt transportation device 220. The upper part of the insulating glass 800 is leaned against the idler of the idler mechanism 500. The driving assembly 300 is started, the first belt conveyor 210 and the second belt conveyor 220 run synchronously, and the hollow glass 800 is transported along with the first belt conveyor. The middle interlayer of the hollow glass 800 is not contacted with the conveying surface in the transportation process, so that the phenomenon that the adhesive at the middle interlayer is adhered to the conveying surface to influence the product forming quality is avoided. When the hollow glass 800 with different thicknesses is vertically placed on the transportation mechanism 200, under the condition that the positions of the first belt conveyor 210 and the second belt conveyor 220 are not changed, as shown in fig. 5, the height of the hollow glass 800 with the larger thickness is higher than the height of the bottom edge of the hollow glass 800 with the smaller thickness, and according to the specific thickness of the transported hollow glass 800, the adjusting assembly 400 is utilized to drive the moving frame 120 to move in the inclined direction on the frame 110, so that the spatial height positions of the first belt conveyor 210 and the second belt conveyor 220 relative to the frame 110 are changed, the vertical placed bottom edges of the hollow glass 800 with different thicknesses are ensured to be kept at the same spatial height position, and the hollow glass 800 is convenient to be processed after being transported to a subsequent station. And since the thickness variation range of the hollow glass 800 is generally within 10mm, the movable frame 120 moves up and down on the frame 110 along the guide rail 111 in an inclined direction, so that the total weight of the movable frame 120 and the components thereon is distributed on the frame 110 in an inclined manner, and the movement adjustment of the movable frame 120 is facilitated.

As shown in fig. 2, in some embodiments of the present invention, the driving assembly 300 includes a bevel gear set 310 and a first motor 320, the bevel gear set 310 is installed on the same rotating shaft of the first belt conveyor 210 and the second belt conveyor 220, and the first motor 320 drives the bevel gear set 310 to rotate so that the first belt conveyor 210 and the second belt conveyor 220 operate synchronously. The bevel gear transmission set 310 comprises two bevel gears, the two bevel gears are respectively installed on the rotating shafts on the same side of the first belt conveyor 210 and the second belt conveyor 220, the bevel gear surfaces of the two bevel gears are meshed with each other, the first motor 320 is connected with one of the bevel gears, and the bevel gear transmission set 310 is driven to rotate so as to drive the first belt conveyor 210 and the second belt conveyor 220 to synchronously run at the same direction and speed.

As shown in fig. 3 and 6, in some embodiments of the present invention, each of the first belt conveyor 210 and the second belt conveyor 220 includes a driving rotating shaft 201 and a driven rotating shaft 202, the driving assembly 300 is connected to the driving rotating shaft 201, the driven rotating shaft 202 is rotatably connected to the moving frame 120 through a tensioning assembly 600, the tensioning assembly 600 includes a connecting shaft 610, a mounting seat 620, a first adjusting screw 630 and a locking screw 640, the mounting seat 620 is fixed to the moving frame 120, a sliding slot 621 is formed in the mounting seat 620, the connecting shaft 610 is coaxially connected to the driven rotating shaft 202, the connecting shaft 610 is inserted into the sliding slot 621, the first adjusting screw 630 is radially threaded through the mounting seat 620 and connected to the connecting shaft 610, the locking screw 640 is threaded on the mounting seat 620, and one end of the locking screw extends into the sliding slot 621 and abuts against a sidewall of the first adjusting screw 630. As shown in fig. 6, the sliding slot 621 is opened along the conveying direction, and by rotating the first adjusting screw 630, the position of the connecting shaft 610 is changed so as to change the distance between the driven rotating shaft 202 and the driving rotating shaft 201 to control the tension of the belt, and after adjustment, the locking screw 640 abuts against the outer wall of the first adjusting screw 630 to position the first adjusting screw 630, so as to ensure that the first adjusting screw 630 is kept at the current position without moving when the driven rotating operation is performed.

As shown in fig. 3 and 7, in some embodiments of the present invention, the first belt conveyor 210 and the second belt conveyor 220 are connected to the movable frame 120 through a connecting plate 710, an elliptical hole 720 is formed in the connecting plate 710, and a second adjusting screw 730 is disposed between the bottom of the connecting plate 710 and the movable frame 120. As shown in fig. 7, the corresponding connecting plates 710 are respectively arranged perpendicular to the conveying surfaces of the first belt conveyor 210 and the second belt conveyor 220, and the upper parts of the connecting plates 710 are fixedly connected with the first belt conveyor 210/the second belt conveyor 220 through bolts; the lower portion of the connection plate 710 is provided with an elliptical hole 720, and is fixed to the movable frame 120 by bolts. The position adjustment of connecting plate 710 is convenient for in the setting of elliptical hole 720, rotates second adjusting screw 730 during the regulation, and the top butt of second adjusting screw 730 is at the bottom of connecting plate 710 to carry on spacingly to the position of connecting plate 710. The relative position between the first belt conveyor 210 and the second belt conveyor 220 is adjusted in turn.

As shown in fig. 2, 3 and 4, in some embodiments of the present invention, the adjusting assembly 400 includes an adjusting screw 410 and a second motor 420, the adjusting screw 410 is connected between the moving frame 120 and the frame 110, and the second motor 420 drives the adjusting screw 410 to rotate to drive the moving frame 120 to perform an inclined lifting movement along the guide rail 111 on the frame 110. Accurate position adjustment control is carried out on the movable frame 120 through the adjusting screw 410, meanwhile, the movable frame 120 can be positioned at the current position, the adjusting precision is high, and the use is convenient.

In some embodiments of the present invention, the adjusting screw 410 is sleeved with a first hinge frame 430 and a second hinge frame 440, the first hinge frame 430 is hinged to the frame 110, and the second hinge frame 440 is hinged to the movable frame 120. As shown in fig. 3 and 4, the adjusting screw 410 can swing on the frame 110 and the moving frame 120 by the first hinge frame 430 and the second hinge frame 440 according to the inclination angle of the guide rail 111 to match the movement of the moving frame 120, i.e. a worker does not need to adjust the parallelism between the adjusting screw and the guide rail 111 intentionally during installation, thereby greatly improving the installation efficiency. Wherein, the included angle between the first belt conveyor 210 and the second belt conveyor 220 is controlled within the range of 85-95 degrees. The long edge of the same side of the hollow glass 800 is generally provided with a 45-degree chamfer with slight deviation, and an included angle between the first belt conveying device 210 and the second belt conveying device 220 is set within the range of 85-95 degrees so as to be matched with the two edges of the same side of the hollow glass 800 to be respectively attached to the conveying surfaces of the first belt conveying device 210 and the second belt conveying device 220, so that the conveying stability is further ensured.

In the description herein, references to the description of "some specific embodiments" 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 are not necessarily intended to 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.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (6)

1. The utility model provides a vertical transportation equipment of cavity glass finished product which characterized in that includes:

a frame (110) on which a movable frame (120) is slidably mounted;

the conveying mechanism (200) is installed on the moving frame (120) and comprises a first belt conveying device (210), a second belt conveying device (220) and a driving assembly (300), the first belt conveying device (210) and the second belt conveying device (220) are installed in an inclined mode, the conveying directions are the same, a V-shape with a large opening end facing upwards is formed between the conveying surfaces of the first belt conveying device (210) and the second belt conveying device (220), and the driving assembly (300) drives the first belt conveying device (210) and the second belt conveying device (220) to carry out synchronous and same-direction conveying;

the adjusting assembly (400) is arranged between the rack (110) and the moving rack (120) and drives the moving rack (120) to perform inclined lifting movement on the rack (110);

the wheel leaning mechanism (500) is obliquely arranged above the conveying mechanism (200) and comprises a support (510) and a plurality of pulleys (520) arranged on the support (510).

2. The insulated glass finishing vertical conveyance apparatus of claim 1, wherein: the driving assembly (300) comprises a bevel gear transmission set (310) and a first motor (320), the bevel gear transmission set (310) is installed on the same-side rotating shaft of the first belt conveyor (210) and the second belt conveyor (220), and the first motor (320) drives the bevel gear transmission set (310) to rotate so that the first belt conveyor (210) and the second belt conveyor (220) run synchronously.

3. The insulated glass finishing vertical transport apparatus of claim 1 or 2, wherein: the first belt conveying device (210) and the second belt conveying device (220) comprise a driving rotating shaft (201) and a driven rotating shaft (202), the driving assembly (300) is connected with the driving rotating shaft (201), the driven rotating shaft (202) is connected to the movable frame (120) through a tensioning assembly (600) in a rotating mode, the tensioning assembly (600) comprises a connecting shaft (610), a mounting seat (620), a first adjusting screw (630) and a locking screw (640), the mounting seat (620) is fixed to the movable frame (120), a sliding groove (621) is formed in the mounting seat (620), the connecting shaft (610) is coaxially connected with the driven rotating shaft (202), the connecting shaft (610) penetrates through the sliding groove (621), the first adjusting screw (630) penetrates through the mounting seat (620) and the radial threaded connection of the mounting seat (610), locking screw (640) threaded connection on mount pad (620) and one end stretch into in spout (621) butt on first adjusting screw (630) lateral wall.

4. The insulated glass finishing vertical conveyance apparatus of claim 1, wherein: first belt conveyors (210), second belt conveyors (220) through connecting plate (710) with remove frame (120) and be connected, be equipped with elliptical hole (720) on connecting plate (710), connecting plate (710) bottom with remove and be equipped with second adjusting screw (730) between frame (120).

5. The insulated glass finishing vertical conveyance apparatus of claim 1, wherein: the adjusting assembly (400) comprises an adjusting screw rod (410) and a second motor (420), the adjusting screw rod (410) is connected between the moving frame (120) and the rack (110), and the second motor (420) drives the adjusting screw rod (410) to rotate so as to drive the moving frame (120) to move along the guide rail (111) on the rack (110) in an inclined lifting manner.

6. The insulated glass finishing vertical conveyance apparatus of claim 5, wherein: a first hinge frame (430) and a second hinge frame (440) are sleeved on the adjusting screw rod (410), the first hinge frame (430) is hinged on the rack (110), and the second hinge frame (440) is hinged on the movable frame (120).

Images