阅读说明：本技术 一种轻量化玻璃容器快速成型设备及其使用方法 (Lightweight glass container rapid forming equipment and use method thereof ) 是由 唐永 于 2021-08-25 设计创作，主要内容包括：本发明公开了一种轻量化玻璃容器快速成型设备及其使用方法,属于玻璃容器成型技术领域,一种轻量化玻璃容器快速成型设备,包括成型框架、伸缩连板、转动弯板、滑动孔板、模具推杆、旋转连板、支撑连杆、限位滑轨和成型架,所述成型框架的顶端固定连接有成型电机,所述成型电机的输出端安装有用于带动所述伸缩连板水平滑动的螺纹杆,所述伸缩连板的两端均活动连接有用于带动所述转动弯板水平旋转的旋转孔槽,该轻量化玻璃容器快速成型设备及其使用方法,通过设置转动弯板,伸缩连板运动通过两组旋转孔槽带动两组转动弯板相对转动,以使得转动弯板转动通过滑动孔板带动与模具推杆相连接的两组成型模具相对运动,实现成型模具的合模操作。(The invention discloses a light-weight glass container rapid forming device and a using method thereof, belonging to the technical field of glass container forming, the light-weight glass container rapid forming device comprises a forming frame, a telescopic connecting plate, a rotating bent plate, a sliding orifice plate, a mold push rod, a rotating connecting plate, a supporting connecting rod, a limiting slide rail and a forming frame, wherein the top end of the forming frame is fixedly connected with a forming motor, the output end of the forming motor is provided with a threaded rod for driving the telescopic connecting plate to horizontally slide, two ends of the telescopic connecting plate are respectively and movably connected with a rotating orifice groove for driving the rotating bent plate to horizontally rotate, the light-weight glass container rapid forming device and the using method thereof are characterized in that the rotating bent plate is arranged, the telescopic connecting plate moves to drive two groups of rotating bent plates to relatively rotate through the two groups of rotating orifice grooves, so that the rotating bent plate rotates to drive two groups of forming molds connected with the mold push rod to relatively move through the sliding orifice plate, and realizing the mold closing operation of the forming mold.)

1. The utility model provides a light-weighted glass container rapid prototyping equipment, includes shaping frame (1), flexible even board (4), rotates bent plate (6), slip orifice plate (7), mould push rod (8), rotatory even board (11), support link (13), spacing slide rail (15) and shaping frame (16), its characterized in that: shaping frame's (1) top fixedly connected with forming motor (2), the output of forming motor (2) is installed and is used for driving flexible even board (4) horizontal slip threaded rod (3), flexible even the equal swing joint in both ends of board (4) is used for driving rotate rotatory hole groove (5) of bent plate (6) horizontal rotation, so that rotate bent plate (6) and rotate and pass through slip orifice plate (7) drive with mould push rod (8) fixed connection's forming die (9) horizontal slip, flexible even the top fixedly connected with of board (4) is used for driving rotatory even board (11) vertical wobbling motion orifice plate (10), rotatory even the top swing joint of board (1) is used for driving support orifice plate (12) of support connecting rod (13) motion, the one end that support connecting rod (13) was kept away from support orifice plate (12) has soon to connect and is used for driving shaping frame (16) are followed spacing slide rail (15) A sliding movement slider (14).

2. The apparatus of claim 1, wherein the apparatus comprises: the lateral wall fixedly connected with rotating base (17) of forming frame (1), and rotating base (17) keep away from lateral wall fixedly connected with conveyer belt (18) of forming frame (1), one side fixedly connected with transport mechanism (19) of conveyer belt (18).

3. The apparatus of claim 1, wherein the apparatus comprises: the rotary bending plate (6) is provided with two sets, the position relation of the two sets of rotary bending plates (6) is symmetrical about the telescopic connecting plate (4), the moving sliding block (14) forms a sliding structure through the supporting hole plate (12), the supporting connecting rod (13) and the limiting sliding rail (15), and the bottom end of the limiting sliding rail (15) is overlapped with the vertical central axis of the forming die (9).

4. The apparatus of claim 2, wherein: the rotary base (17) comprises a rotary motor (1701), a rotary guide disc (1702), a guide post (1703), an intermittent rotary disc (1704), a guide sliding groove (1705), a limiting post (1706), a limiting guide rail (1707), a rotary disc (1708), a rotary orifice plate (1709), a clamping frame (1710) and a guide rail (1711), wherein the rotary motor (1701) is fixedly connected to the top end of the rotary base (17), the rotary guide disc (1702) is installed at the output end of the rotary motor (1701), the guide post (1703) is fixedly connected to the edge of the top end of the rotary guide disc (1702), the intermittent rotary disc (1704) is arranged on the side wall of the guide post (1703), the guide sliding groove (1705) is arranged at the connecting part of the guide post (1703) and the intermittent rotary disc (1704), the limiting post (1706) is fixedly connected to the bottom end of the intermittent rotary disc (1704), and the limiting guide rail (1707) is arranged at the connecting part of the limiting post (1706) and the rotary guide disc (1702), the top fixedly connected with rolling disc (1708) of intermittent type carousel (1704), and the rotatory orifice plate of lateral wall fixedly connected with (1709) of rolling disc (1708), the inner wall swing joint of rotatory orifice plate (1709) has holding frame (1710), and holding frame (1710) keep away from the one end sliding connection of rotatory orifice plate (1709) have with swivel base (17) lateral wall fixedly connected with guide rail (1711).

5. The apparatus of claim 4, wherein: intermittent type carousel (1704) pass through and constitute intermittent type revolution mechanic between guide post (1703) and direction spout (1705) and rotating base (17), and intermittent type rotation angle of intermittent type carousel (1704) is 90, spacing guide rail (1707) are through rotating and constitute sliding construction between guide dish (1702) and spacing post (1706), spacing post (1706) are provided with four groups, and the centre of four groups of spacing post (1706) coincides mutually with the centre of a circle of intermittent type carousel (1704).

6. The apparatus of claim 4, wherein: rotatory orifice plate (1709) are provided with four groups, and the position distribution of four groups of rotatory orifice plate (1709) is the circumference distribution of equal angle about the centre of a circle of rolling disc (1708), holding frame (1710) constitute sliding construction through rotating between orifice plate (1709) and guide rail (1711), and the center of holding frame (1710) coincides mutually with the center of forming die (9), guide rail (1711) are provided with four groups of concave positions.

7. The apparatus of claim 2, wherein: the transfer mechanism (19) comprises a transfer motor (1901), a rotating guide plate (1902), a connecting sleeve (1903), a track sliding block (1904), a track sliding rail (1905), an abutting block (1906) and a moving block (1907), a transfer motor (1901) is fixedly connected with the side wall of the transfer mechanism (19), and the output end of the transfer motor (1901) is provided with a rotary guide plate (1902), the outer wall of the rotary guide plate (1902) is sleeved with a connecting sleeve (1903), and the side wall of the connecting sleeve (1903) is screwed with a track sliding block (1904), the connecting part of the track sliding block (1904) and the transfer mechanism (19) is provided with a track sliding rail (1905), one end of the track sliding block (1904) far away from the connecting sleeve (1903) is screwed with a butting block (1906), and the side wall of the abutting block (1906) abuts against a moving block (1907) fixedly connected with the side wall of the conveyor belt (18).

8. The apparatus of claim 7, wherein: the rotary guide plates (1902) are provided with two groups, the position distribution of the two groups of rotary guide plates (1902) is symmetrical about the conveyor belt (18), the track sliding block (1904) forms a sliding structure through the rotary guide plates (1902), the connecting sleeve (1903) and the track sliding rail (1905), and the track sliding rail (1904) is rectangular in appearance.

9. The apparatus of claim 7, wherein: the forming frames (1) are provided with two groups, the two groups of forming frames (1) are symmetrical about the transfer mechanism (19), the conveyor belt (18) forms an intermittent sliding structure through the abutting blocks (1906), the moving blocks (1907) and the rotating base (17), and the intermittent sliding length of the conveyor belt (18) is equal to the horizontal length of the track slide rail (1905).

10. The use method of the light-weight glass container rapid forming equipment is characterized by comprising the following steps of:

s1, when the device is used, firstly, intermittent feeding operation is carried out on glass blanks, the glass blanks are placed on a conveyor belt (18), in a transfer mechanism (19), a transfer motor (1901) works to drive a rotary guide plate (1902) to rotate, so that the rotary guide plate (1902) rotates to drive a track slide block (1904) to slide along a track slide rail (1905) through a connecting sleeve (1903), the track slide block (1904) drives an abutting block (1906) to abut against a moving block (1907) on the side wall of the conveyor belt (18), and the abutting block (1906) moves to drive the conveyor belt (18) to intermittently slide, so that the intermittent feeding operation of the glass blanks is realized;

s2, then, transferring the glass blank, in the rotating base (17), the rotating motor (1701) works to drive the rotating guide disc (1702) to rotate, the rotating guide disc (1702) rotates to drive the intermittent turntable (1704) to rotate intermittently through the guide post (1703) and the guide chute (1705), so that the rotating guide disc (1702) rotates to drive the limiting guide rail (1707) to slide along the limiting post (1706), and the transferring operation of the glass blank is realized;

s3, then, the glass blank is clamped, in the rotating base (17), the rotating disc (1708) intermittently rotates to drive the rotating orifice plate (1709) to intermittently rotate, the rotating orifice plate (1709) rotates to drive the clamping frame (1710) to slide along the guide rail (1711), and the clamping operation of the clamping frame (1710) is realized through the concave part of the guide rail (1711);

s4, then, the rotating motor (1701) continues to work, the glass blank is transferred to the forming frame (1), then the glass blank is preformed, in the forming frame (1), the forming motor (2) works to drive the telescopic connecting plate (4) to move through the threaded rod (3), the telescopic connecting plate (4) moves to drive the two groups of rotating bent plates (6) to rotate relatively through the two groups of rotating hole grooves (5), so that the rotating bent plates (6) rotate to drive the two group forming molds (9) connected with the mold push rods (8) to move relatively through the sliding hole plates (7), the mold closing operation of the forming molds (9) is realized, meanwhile, the telescopic connecting plate (4) moves to drive the rotating connecting plate (11) to rotate through the moving hole plates (10), the rotating connecting plate (11) rotates to drive the supporting connecting rods (13) to move through the supporting hole plates (12), and the supporting connecting rods (13) move to drive the forming frame (16) connected with the moving slide blocks (14) to move along the limiting slide rails (15) ) Sliding to realize the pre-forming operation of the glass blank;

and S5, finally, the rotating motor (1701) continues to work to sequentially transfer the glass blank to a forming station and a blanking station, and then the formed glass is placed on the conveyor belt (18) to realize the forming operation of the glass blank.

Technical Field

The invention relates to the technical field of glass container forming, in particular to light-weight glass container rapid forming equipment and a using method thereof.

Background

The glass container is made of more than ten raw materials such as cullet, soda ash, sodium nitrate, shellfish carbonate, quartz sand and the like, is manufactured by processes such as 1600-DEG C high-temperature melting and molding, can be used for producing glass bottles with different shapes according to different molds, and mainly comprises various special-shaped glass bottles such as various wine bottles, beverage bottles, pickles bottles, honey bottles, can bottles, soda bottles, carbonated beverage bottles, coffee bottles, tea cups and the like, wherein the glass bottles have sealed light transmission and can store products highly sensitive to humidity for a long time, and the glass bottle container is a transparent container made of molten glass materials through blowing and mold molding.

However, the problem that the existing glass container rapid forming equipment cannot intermittently feed materials when in use results in the problem that glass blanks are bonded and cannot automatically switch manufacturing stations of glass containers when glass is produced, the temperature of the glass blanks is reduced, and the surface quality of the glass containers is low due to inaccurate mold closing of glass molds, so that the requirements of people cannot be met.

Disclosure of Invention

The invention aims to solve the problems that intermittent feeding cannot be carried out, stations cannot be automatically switched and die assembly is inaccurate in the prior art, and provides light glass container rapid forming equipment and a using method thereof.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a lightweight glass container rapid prototyping equipment, is including shaping frame, flexible even board, rotation bent plate, slip orifice plate, mould push rod, rotatory even board, supporting link, spacing slide rail and shaping frame, shaping frame's top fixedly connected with forming motor, the output of forming motor is installed and is used for driving flexible even board horizontal slip's threaded rod, the equal swing joint in both ends of flexible even board is used for driving rotate the rotatory hole groove of bent plate horizontal rotation, so that rotate the bent plate and rotate and pass through the slip orifice plate drive with mould push rod fixed connection's forming die horizontal slip, flexible even board's top fixedly connected with is used for driving rotatory even vertical wobbling motion orifice plate of board, rotatory even board's top swing joint is used for driving the supporting link motion orifice plate, the one end that the supporting link kept away from the supporting orifice plate has soon been connect and is used for driving the shaping frame is followed spacing slide rail is smooth A movable moving slide block.

Preferably, the lateral wall fixedly connected with rotating base of shaping frame, and rotating base keeps away from shaping frame's lateral wall fixedly connected with conveyer belt, one side fixedly connected with transport mechanism of conveyer belt.

Preferably, the rotating bending plates are provided with two groups, the position relations of the two groups of rotating bending plates are symmetrical about the telescopic connecting plate, the moving sliding block forms a sliding structure through the supporting hole plate, the supporting connecting rod and the limiting sliding rail, and the bottom end of the limiting sliding rail coincides with the vertical central axis of the forming mold.

Preferably, rotating base includes rotating electrical machines, rotates guide disc, guide post, intermittent type carousel, direction spout, spacing post, spacing guide rail, rolling disc, rotatory orifice plate, holding frame and guide rail, rotating base's top fixedly connected with rotating electrical machines, and rotating electrical machines's output installs the rotation guide disc, the top edge fixedly connected with guide post that rotates the guide disc, and the lateral wall of guide post is provided with intermittent type carousel, the direction spout has been seted up with intermittent type carousel's the position of being connected to the guide post, the spacing post of bottom fixedly connected with of intermittent type carousel, and spacing post is provided with spacing guide rail with the position of being connected of rotating the guide disc, the top fixedly connected with rolling disc of intermittent type carousel, and the lateral wall fixedly connected with rotatory orifice plate of rolling disc, the inner wall swing joint of rotatory orifice plate has the holding frame, and the holding frame keep away from the one end sliding connection of rotatory orifice plate have with rotating base lateral wall fixedly connected with guide rail .

Preferably, the intermittent type carousel passes through and constitutes intermittent type revolution mechanic between guide post and the direction spout and the rotating base, and the intermittent type rotation angle of intermittent type carousel is 90, limit guide forms sliding structure through rotating between guide disc and the spacing post, the spacing post is provided with four groups, and the centre of four groups of spacing posts coincides mutually with the centre of a circle of intermittent type carousel.

Preferably, the rotary pore plates are provided with four groups, the position distribution of the four groups of rotary pore plates is equiangular and circumferentially distributed about the circle center of the rotary disc, the clamping frame forms a sliding structure through the rotary pore plates and the guide rails, the center of the clamping frame coincides with the center of the forming die, and the guide rails are provided with four groups of concave parts.

Preferably, transport mechanism is including transporting motor, rotatory baffle, connecting sleeve, track slider, orbit slide rail, butt piece and motion piece, transport mechanism's lateral wall fixedly connected with transports motor, and transports the output of motor and install rotatory baffle, the connecting sleeve has been cup jointed to the outer wall of rotatory baffle, and the connecting sleeve's lateral wall has connect the track slider soon, the track slider is provided with the orbit slide rail with transport mechanism's connection position, the track slider is kept away from connecting sleeve's one end and has been connect the butt piece soon, and the lateral wall butt of butt piece have with conveyer belt lateral wall fixed connection's motion piece.

Preferably, the rotary guide plates are arranged in two groups, the position distribution of the two groups of rotary guide plates is symmetrical about the conveyor belt, the track sliding block forms a sliding structure with the track sliding rail through the rotary guide plates and the connecting sleeve, and the track sliding rail is rectangular in shape.

Preferably, the forming frames are provided with two groups, the two groups of forming frames are symmetrical about the transfer mechanism, the conveyor belt forms an intermittent sliding structure through the abutting blocks, the moving blocks and the rotating base, and the intermittent sliding length of the conveyor belt is equal to the horizontal length of the track sliding rail.

The scheme also provides a use method of the light-weight glass container rapid forming equipment, which comprises the following steps:

s1, when the device is used, firstly, intermittent feeding operation is carried out on the glass blank, the glass blank is placed on a conveyor belt, in a transfer mechanism, a transfer motor works to drive a rotary guide plate to rotate, so that the rotary guide plate rotates and drives a track slide block to slide along a track slide rail through a connecting sleeve, the track slide block drives a butting block to butt against a moving block on the side wall of the conveyor belt, so that the butting block moves to drive the conveyor belt to intermittently slide, and the intermittent feeding operation of the glass blank is realized;

s2, then, transferring the glass blank, wherein in the rotating base, the rotating motor works to drive the rotating guide disc to rotate, and the rotating guide disc rotates to drive the intermittent turntable to rotate intermittently through the guide post and the guide chute, so that the rotating guide disc rotates to drive the limiting guide rail to slide along the limiting post, and the glass blank is transferred;

s3, then, the glass blank is clamped, in the rotating base, the rotating disc intermittently rotates to drive the rotating pore plate to intermittently rotate, the rotating pore plate rotates to drive the clamping frame to slide along the guide rail, and the clamping operation of the clamping frame is realized through the concave part of the guide rail;

s4, then, the rotating motor continues to work, the glass blank is transferred to the forming frame, then the glass blank is preformed, in the forming frame, the forming motor works to drive the telescopic connecting plate to move through the threaded rod, the telescopic connecting plate moves to drive the two sets of rotating bent plates to rotate relatively through the two sets of rotating hole grooves, so that the rotating bent plates rotate to drive the two sets of forming dies connected with the die push rods to move relatively through the sliding hole plates, the die closing operation of the forming dies is realized, meanwhile, the telescopic connecting plate moves to drive the rotating connecting plate to rotate through the moving hole plates, the rotating connecting plate rotates to drive the supporting connecting rods to move through the supporting hole plates, the supporting connecting rods move to drive the forming frames connected with the moving slide blocks to slide along the limiting slide rails, and the preforming operation of the glass blank is realized.

And S5, finally, the rotating motor continues to work to sequentially transfer the glass blank to a forming station and a blanking station, and then the formed glass is placed on a conveyor belt to realize the forming operation of the glass blank.

Compared with the prior art, the invention provides light-weight glass container rapid forming equipment, which has the following beneficial effects:

1. according to the light-weight glass container rapid forming equipment, the rotating bent plates are arranged, the telescopic connecting plate moves to drive the two groups of rotating bent plates to rotate relatively through the two groups of rotating hole grooves, so that the rotating bent plates rotate to drive the two groups of forming molds connected with the mold push rods to move relatively through the sliding hole plates, and the mold closing operation of the forming molds is realized;

2. according to the light-weight glass container rapid forming equipment, the moving slide block is arranged, in the forming frame, the telescopic connecting plate moves to drive the rotating connecting plate to rotate through the moving pore plate, the rotating connecting plate rotates to drive the supporting connecting rod to move through the supporting pore plate, and the supporting connecting rod moves to drive the forming frame connected with the moving slide block to slide along the limiting slide rail, so that the glass blank is preformed;

3. according to the light-weight glass container rapid forming equipment, the guide post and the guide sliding chute are arranged, the rotating guide disc rotates in the rotating base to drive the intermittent rotary disc to rotate intermittently through the guide post and the guide sliding chute, so that the rotating guide disc rotates to drive the limiting guide rail to slide along the limiting post, and the transfer operation of glass blanks is realized;

4. according to the light-weight glass container rapid forming equipment, the guide rail is arranged, the rotating disc intermittently rotates to drive the rotating pore plate to intermittently rotate in the rotating base, the rotating pore plate rotates to drive the clamping frame to slide along the guide rail, and clamping operation of the clamping frame is realized through the concave part of the guide rail;

5. this lightweight glass container rapid prototyping equipment through setting up track slider and orbit slide rail, in the transport mechanism, rotatory baffle rotates and drives the track slider through the connecting sleeve and slide along the orbit slide rail, and the track slider drives the motion piece looks butt of butt piece and conveyer belt lateral wall to make the motion of butt piece drive the conveyer belt intermittent type slip, realize the intermittent type material loading operation to the glass stock.

Drawings

FIG. 1 is a schematic view of an overall first perspective structure of a lightweight glass container rapid prototyping apparatus according to the present invention;

FIG. 2 is a schematic view of an overall second perspective structure of a lightweight glass container rapid prototyping apparatus according to the present invention;

FIG. 3 is a schematic view of a connection structure of a transfer mechanism of a lightweight glass container rapid prototyping apparatus provided by the present invention;

FIG. 4 is a schematic view of a first perspective structure of a rotating base of a light-weight glass container rapid prototyping apparatus according to the present invention;

FIG. 5 is a second perspective structural view of a rotating base of the apparatus for rapid forming of lightweight glass containers according to the present invention;

FIG. 6 is a schematic view of a clamping frame connection structure of a lightweight glass container rapid prototyping apparatus according to the present invention;

FIG. 7 is a first view structural diagram of a forming frame of a lightweight glass container rapid forming apparatus according to the present invention;

fig. 8 is a second perspective structural diagram of a forming frame of the rapid forming apparatus for lightweight glass containers according to the present invention.

In the figure: 1. forming a frame; 2. molding the motor; 3. a threaded rod; 4. a telescopic connecting plate; 5. rotating the hole slot; 6. rotating the bent plate; 7. sliding the orifice plate; 8. a mold push rod; 9. forming a mould; 10. moving the orifice plate; 11. rotating the connecting plate; 12. supporting the orifice plate; 13. a support link; 14. a moving slide block; 15. a limiting slide rail; 16. forming a frame; 17. rotating the base; 1701. a rotating electric machine; 1702. rotating the guide disc; 1703. a guide post; 1704. an intermittent rotary table; 1705. a guide chute; 1706. a limiting column; 1707. limiting a guide rail; 1708. rotating the disc; 1709. rotating the orifice plate; 1710. a clamping frame; 1711. a guide rail; 18. a conveyor belt; 19. a transfer mechanism; 1901. a transfer motor; 1902. rotating the guide plate; 1903. a connecting sleeve; 1904. a track slider; 1905. a track slide rail; 1906. a butting block; 1907. and (5) moving blocks.

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.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-8, a lightweight glass container rapid prototyping device, includes a modeling frame 1, a flexible connecting plate 4, a rotating curved plate 6, a sliding orifice plate 7, a mold push rod 8, a rotating connecting plate 11, a support connecting rod 13, a limit slide rail 15 and a modeling frame 16, wherein the top end of the modeling frame 1 is fixedly connected with a modeling motor 2, the output end of the modeling motor 2 is provided with a threaded rod 3 for driving the flexible connecting plate 4 to horizontally slide, both ends of the flexible connecting plate 4 are movably connected with a rotating orifice groove 5 for driving the rotating curved plate 6 to horizontally rotate, so that the rotating curved plate 6 rotates to drive a modeling mold 9 fixedly connected with the mold push rod 8 to horizontally slide through the sliding orifice plate 7, the top end of the flexible connecting plate 4 is fixedly connected with a moving orifice plate 10 for driving the rotating connecting plate 11 to vertically swing, the top end of the rotating connecting plate 11 is movably connected with a support orifice plate 12 for driving the support connecting rod 13 to move, one end of the support connecting rod 13 far away from the support orifice plate 12 is screwed with a moving slide block 14 for driving the forming frame 16 to slide along a limit slide rail 15.

Further, the lateral wall fixedly connected with rotating base 17 of shaping frame 1, and rotating base 17 keeps away from shaping frame 1's lateral wall fixedly connected with conveyer belt 18, and one side fixedly connected with transport mechanism 19 of conveyer belt 18 is through setting up rotating base 17, is favorable to realizing the conversion operation of glass stock station, through setting up transport mechanism 19, is favorable to realizing the intermittent type pay-off operation of glass stock.

Furthermore, two sets of rotating bent plates 6 are arranged, the position relation of the two sets of rotating bent plates 6 is symmetrical about the telescopic connecting plate 4, the moving slide block 14 forms a sliding structure through the supporting orifice plate 12 and the supporting connecting rod 13 and the limiting slide rail 15, the bottom end of the limiting slide rail 15 is coincident with the vertical central axis of the forming mold 9, the two sets of rotating bent plates 6 are arranged, the telescopic connecting plate 4 is favorable to move to drive the two sets of rotating bent plates 6 to rotate relatively through the two sets of rotating orifice grooves 5, so that the rotating bent plates 6 rotate to drive the two sets of forming molds 9 connected with the mold push rods 8 to move relatively through the sliding orifice plate 7, the control operation of closing the two sets of forming molds 9 is realized, the telescopic connecting plate 4 is favorable to move to drive the rotating connecting plate 11 to rotate through the moving orifice plate 10, the rotating connecting plate 11 rotates to drive the supporting connecting rod 13 to move through the supporting orifice plate 12, the supporting connecting rod 13 moves to drive the forming frame 16 connected with the moving slide block 14 to slide along the limiting slide rail 15, the control operation of the movement of the forming frame 16 is realized.

Further, the rotating base 17 comprises a rotating motor 1701, a rotating guide disc 1702, a guide post 1703, an intermittent turntable 1704, a guide chute 1705, a limit post 1706, a limit guide rail 1707, a rotating disc 1708, a rotating orifice plate 1709, a holding frame 1710 and a guide rail 1711, wherein the top end of the rotating base 17 is fixedly connected with the rotating motor 1701, the rotating guide disc 1702 is installed at the output end of the rotating motor 1701, the guide post 1703 is fixedly connected with the top end edge of the rotating guide disc 1702, the side wall of the guide post 1703 is provided with the intermittent turntable 1704, the guide chute 1705 is arranged at the connecting part of the guide post 1703 and the intermittent turntable 1704, the limit post 1706 is fixedly connected with the bottom end of the intermittent turntable 1704, the limit guide rail 1707 is arranged at the connecting part of the limit post 1706 and the rotating guide disc 1702, the rotating disc 1708 is fixedly connected with the top end of the intermittent turntable 1704, and the side wall of the rotating orifice plate 1709 is fixedly connected with the rotating disc 1709, inner wall swing joint of rotatory orifice plate 1709 has holding frame 1710, and holding frame 1710 keeps away from the one end sliding connection of rotatory orifice plate 1709 and rotating base 17 lateral wall fixedly connected with guide rail 1711, through setting up rotating base 17, it drives intermittent type carousel 1704 intermittent type rotation through guide post 1703 and direction spout 1705 to rotate guide plate 1702, so that it slides along spacing post 1706 to make to rotate guide plate 1702 rotate to drive spacing guide rail 1707, be favorable to rotating plate 1708 intermittent type to change and drive rotatory orifice plate 1709 intermittent type rotation, rotatory orifice plate 1709 rotates and drives holding frame 1710 and slide along guide rail 1711, the concavity part through guide rail 1711, realize the operation of pressing from both sides of holding frame 1710.

Furthermore, the intermittent turntable 1704 forms an intermittent rotation structure through the guide column 1703, the guide chute 1705 and the rotating base 17, the intermittent rotation angle of the intermittent turntable 1704 is 90 °, the limit guide rail 1707 forms a sliding structure through the rotation guide disc 1702 and the limit column 1706, the limit column 1706 is provided with four groups, the centers of the four groups of limit columns 1706 are overlapped with the circle center of the intermittent turntable 1704, the rotation guide disc 1702 is favorably rotated to drive the intermittent turntable 1704 to rotate intermittently through the guide column 1703 and the guide chute 1705, so that the rotation guide disc 1702 rotates to drive the limit guide rail 1707 to slide along the limit column 1706, and the control operation of the movement of the intermittent turntable 1704 is realized.

Further, rotatory orifice plate 1709 is provided with four groups, and the position distribution of four groups of rotatory orifice plates 1709 is the angular circle distribution such as about the centre of a circle of rolling disc 1708, holding frame 1710 constitutes sliding construction through rotating between orifice plate 1709 and the guide rail 1711, and the center of holding frame 1710 coincides mutually with forming die 9's center, guide rail 1711 is provided with four groups of concave positions, be favorable to rolling disc 1708 intermittent type to change and drive rotatory orifice plate 1709 intermittent type and rotate, rotatory orifice plate 1709 rotates and drives holding frame 1710 and slide along guide rail 1711, the control operation of realization to the motion of holding frame 1710.

Further, the transfer mechanism 19 includes a transfer motor 1901, a rotating guide plate 1902, a connecting sleeve 1903, a track slider 1904, a track slide rail 1905, an abutting block 1906 and a moving block 1907, a side wall of the transfer mechanism 19 is fixedly connected with the transfer motor 1901, the rotating guide plate 1902 is installed at an output end of the transfer motor 1901, the connecting sleeve 1903 is sleeved on an outer wall of the rotating guide plate 1902, the track slider 1904 is screwed on a side wall of the connecting sleeve 1903, the track slide rail 1905 is arranged at a connecting portion of the track slider 1904 and the transfer mechanism 19, the abutting block 1906 is screwed on one end of the track slider 1904 far away from the connecting sleeve 1903, the side wall of the abutting block 1906 abuts on the moving block 1907 fixedly connected with a side wall of the conveyor belt 18, by arranging the transfer mechanism 19, the rotating guide plate 1902 is facilitated to rotate, the track slider 1904 is driven to slide along the track slide rail 1905 by the connecting sleeve 1903, the track slider 1904 drives the block 1906 to abut on the moving block 1907 on the side wall of the conveyor belt 18, so that the abutment block 1906 moves to drive the conveyor belt 18 to intermittently slide, thereby realizing the intermittent feeding operation of the glass blanks.

Further, the two sets of rotating guide plates 1902 are arranged, the position distribution of the two sets of rotating guide plates 1902 is symmetrical with respect to the conveyor belt 18, the track slider 1904 forms a sliding structure with the track slide rail 1905 through the rotating guide plates 1902 and the connecting sleeves 1903, and the track slide rail 1905 is rectangular in shape, so that the rotating guide plates 1902 rotate and the track slider 1904 is driven to slide along the track slide rail 1905 through the connecting sleeves 1903, and the control operation of the movement of the track slider 1904 is realized.

Further, the forming frame 1 is provided with two sets, and two sets of forming frames 1 form an intermittent sliding structure through the abutting block 1906 and the moving block 1907 with the rotating base 17 about the symmetrical conveyer belt 18 of the transfer mechanism 19, and the intermittent sliding length of the conveyer belt 18 is equal to the horizontal length of the track slide rail 1905, which is beneficial for the track slider 1904 to drive the abutting block 1906 to abut against the moving block 1907 of the side wall of the conveyer belt 18, so that the abutting block 1906 moves to drive the conveyer belt 18 to intermittently slide, and the control operation of the movement of the conveyer belt 18 is realized.

The embodiment also provides a use scheme of the light-weight glass container rapid forming equipment, and the device comprises the following steps:

s1, when the device is used, firstly, intermittent feeding operation is carried out on the glass blanks, the glass blanks are placed on the conveyor belt 18, in the transfer mechanism 19, the transfer motor 1901 works to drive the rotary guide plate 1902 to rotate, so that the rotary guide plate 1902 rotates to drive the track slide block 1904 to slide along the track slide rail 1905 through the connecting sleeve 1903, the track slide block 1904 drives the abutting block 1906 to abut against the moving block 1907 on the side wall of the conveyor belt 18, so that the abutting block 1906 moves to drive the conveyor belt 18 to intermittently slide, and the intermittent feeding operation of the glass blanks is realized;

s2, next, transferring the glass blank, in the rotating base 17, the rotating motor 1701 drives the rotating guide disc 1702 to rotate, the rotating guide disc 1702 rotates to drive the intermittent turntable 1704 to rotate intermittently through the guide column 1703 and the guide chute 1705, so that the rotating guide disc 1702 rotates to drive the limit guide rail 1707 to slide along the limit column 1706, and the glass blank is transferred;

s3, then, the glass blank is clamped, in the rotating base 17, the rotating disc 1708 intermittently rotates to drive the rotating orifice plate 1709 to intermittently rotate, the rotating orifice plate 1709 rotates to drive the clamping frame 1710 to slide along the guide rail 1711, and the clamping operation of the clamping frame 1710 is realized through the concave part of the guide rail 1711;

s4, the rotary motor 1701 continues to operate, the glass blank is transferred to the forming frame 1, and then the glass blank is subjected to the preforming operation, in the forming frame 1, a forming motor 2 works to drive a telescopic connecting plate 4 to move through a threaded rod 3, the telescopic connecting plate 4 moves to drive two groups of rotating bent plates 6 to rotate relatively through two groups of rotating hole grooves 5, so that the rotating bending plate 6 rotates to drive the two groups of forming dies 9 connected with the die push rod 8 to move relatively through the sliding pore plate 7, the die closing operation of the forming dies 9 is realized, meanwhile, the telescopic connecting plate 4 moves to drive the rotary connecting plate 11 to rotate through the moving orifice plate 10, the rotary connecting plate 11 rotates to drive the support connecting rod 13 to move through the support orifice plate 12, and the support connecting rod 13 moves to drive the forming frame 16 connected with the moving slide block 14 to slide along the limiting slide rail 15, so that the glass blank is preformed.

S5, finally, the rotary motor 1701 continues to work to sequentially transfer the glass blank to the forming station and the blanking station, and then the formed glass is placed on the conveyor 18 to realize the forming operation of the glass blank.

The working principle of the invention is as follows: when the device is used, firstly, intermittent feeding operation is carried out on glass blanks, the glass blanks are placed on a conveyor belt 18, in a transfer mechanism 19, a transfer motor 1901 works to drive a rotary guide plate 1902 to rotate, so that the rotary guide plate 1902 rotates to drive a track slide block 1904 to slide along a track slide rail 1905 through a connecting sleeve 1903, the track slide block 1904 drives an abutting block 1906 to abut against a moving block 1907 on the side wall of the conveyor belt 18, and the abutting block 1906 moves to drive the conveyor belt 18 to intermittently slide, so that intermittent feeding operation on the glass blanks is realized;

then, transferring the glass blanks, wherein in the rotating base 17, the rotating motor 1701 drives the rotating guide disc 1702 to rotate, the rotating guide disc 1702 rotates to drive the intermittent turntable 1704 to rotate intermittently through the guide column 1703 and the guide chute 1705, so that the rotating guide disc 1702 rotates to drive the limiting guide rail 1707 to slide along the limiting column 1706, and the glass blanks are transferred;

then, the glass blank is clamped, in the rotating base 17, the rotating disc 1708 intermittently rotates to drive the rotating orifice plate 1709 to intermittently rotate, the rotating orifice plate 1709 rotates to drive the clamping frame 1710 to slide along the guide rail 1711, and the clamping operation of the clamping frame 1710 is realized through the concave part of the guide rail 1711;

then, the rotary motor 1701 continues to operate, the glass blank is transferred to the forming frame 1, and then the glass blank is subjected to a preforming operation, in the forming frame 1, a forming motor 2 works to drive a telescopic connecting plate 4 to move through a threaded rod 3, the telescopic connecting plate 4 moves to drive two groups of rotating bent plates 6 to rotate relatively through two groups of rotating hole grooves 5, so that the rotating bending plate 6 rotates to drive the two groups of forming dies 9 connected with the die push rod 8 to move relatively through the sliding pore plate 7, the die closing operation of the forming dies 9 is realized, meanwhile, the telescopic connecting plate 4 moves to drive the rotary connecting plate 11 to rotate through the moving orifice plate 10, the rotary connecting plate 11 rotates to drive the support connecting rod 13 to move through the support orifice plate 12, and the support connecting rod 13 moves to drive the forming frame 16 connected with the moving slide block 14 to slide along the limiting slide rail 15, so that the glass blank is preformed.

Finally, the rotary motor 1701 continues to operate to sequentially transfer the glass blank to the forming station and the blanking station, and then the formed glass is placed on the conveyor 18 to realize the forming operation of the glass blank.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.