CN112720781B - Floor tile manufacturing device for archaize building processing - Google Patents

Abstract

The invention relates to a floor tile manufacturing device, in particular to a floor tile manufacturing device for archaize building processing. The technical problem to be solved by the invention is to provide the floor tile manufacturing device for processing the archaize building, which can be used for vibrating and tamping the brick materials, avoid holes from being generated on the brick, and improve the quality of the brick. In order to solve the technical problems, the invention provides a floor tile manufacturing device for archaize building processing, which comprises: a first placing plate is connected to one side of the top of the base; the two mounting frames are symmetrically connected to the base; the second placing plate is connected to one side, far away from the first placing plate, of the base; and the positioning frame is connected to the top of the second placing plate. According to the invention, the mould can be automatically transmitted to the vibration mechanism through the driving mechanism and the feeding mechanism, and the driving mechanism drives the vibration mechanism to work so as to vibrate the mould, so that concrete is paved in the mould.

Description

Floor tile manufacturing device for archaize building processing

Technical Field

The invention relates to a floor tile manufacturing device, in particular to a floor tile manufacturing device for archaize building processing.

Background

The patent publication number is searched: the patent of CN110103317A discloses a brick processingequipment for building, including brickmaking machine, its characterized in that: the brick making machine is characterized in that a power cavity is formed in the brick making machine, a power device brick making device is arranged in the power cavity, a motor gear is arranged at the lower end of the power cavity, a stirring cavity is arranged at the lower end of the motor gear, a blanking device is arranged in the stirring cavity and used for rotating, a cavity communicated with the outside is formed in the left end wall of the motor gear, a conveying cavity is formed in the lower end wall of the cavity, a feeding device is arranged in the stirring cavity and used for making bricks through the power device to control rotation and movement, a driving groove is formed in the lower end of the conveying cavity, a driving device is arranged in the driving groove, a brick making cavity is formed in the lower end of the driving groove, a brick making device is arranged in the brick making cavity, the feeding device can be connected to the driving device through the power, the brick making device cannot be tamped when the brick making device is used for manufacturing, holes are easy to produce the bricks, the bricks are poor in hardness, the brick making process cannot meet quality requirements, the brick making process is complex, and the forming efficiency is low.

How to design a floor tile manufacturing device for archaize building processing, which can vibrate and tamp brick materials, avoid holes generated by bricks and improve the quality of the bricks, is a problem to be solved at present.

Disclosure of Invention

(1) Technical problem to be solved

The invention aims to overcome the defects that the existing brick making equipment cannot perform vibration tamping on brick materials during brick making, the manufactured bricks are easy to generate holes, the hardness of the bricks is poor, and the quality requirement cannot be met.

(2) Technical proposal

In order to solve the technical problems, the invention provides a floor tile manufacturing device for archaize building processing, which comprises: a first placing plate is connected to one side of the top of the base; the two mounting frames are symmetrically connected to the base; the second placing plate is connected to one side, far away from the first placing plate, of the base; the positioning frame is connected to the top of the second placing plate; a lifting mechanism mounted on the base; a drive mechanism mounted on the base; the vibration mechanism is connected between the driving mechanism and the lifting mechanism; and the feeding mechanism is connected between the mounting frame and the driving mechanism.

Preferably, the lifting mechanism comprises: the support posts are at least two and are connected to the top of the base; a lifting column slidably connected to the column; the vibrating plate is arranged at the top of the lifting column in a training stage; and a return spring connected between the vibration plate and the support column.

Preferably, the driving mechanism comprises: the servo motor is connected to the base; the fixed block is provided with two fixed blocks, and the two fixed blocks are symmetrically connected to the base; the two first transmission rods are respectively connected to the two fixed blocks in a rotary mode; the diamond-shaped rod is connected between the two first transmission rods; and the belt transmission assembly is connected between the output shaft of the servo motor and the first transmission rod.

Preferably, the vibration mechanism comprises: an inner diamond sleeve slidingly connected to the diamond rod; a cam connected to one end of the inner diamond-shaped sleeve; a disc rotatably connected to the inner diamond sleeve; a guide rail connected to the top of the base; the slide bar is connected to the guide rail in a sliding manner and is connected with the disc; and the contact ball is connected to the bottom of the vibration plate and is in contact fit with the convex disc.

Preferably, the feed mechanism includes: the two fixed rails are respectively connected to the mounting frames on the two sides; a slider slidably coupled to the fixed rail; an elastic member connected between the slider and an end of the fixed rail; the rack is connected to the bottom of the sliding block; the two sector gears are respectively connected to the first transmission rods at the two sides and meshed with the racks; a wedge block slidably coupled to the rack; and the common spring is connected between the wedge block and the rack.

Preferably, still including blanking mechanism, blanking mechanism is including: the discharging frame is connected between the fixed rails at two sides, and a discharging port is formed in the right side of the bottom of the discharging frame; the second transmission rod is rotationally connected to the discharging frame; the stirring shaft is rotationally connected in the discharging frame; the transmission belt is connected between the stirring shaft and the second transmission rod; the bevel gears are provided with two bevel gears, the two bevel gears are respectively connected to the second transmission rod and the first transmission rod, and the two bevel gears are meshed; the rotating rod is rotationally connected to the outer wall of the discharging frame; the baffle is connected to the bottom of the rotating rod and used for blocking the blanking port; and the first torsion spring is connected between the rotating rod and the outer wall of the discharging frame.

Preferably, the device also comprises a material blocking mechanism, and the material blocking mechanism comprises: the limiting plate is connected to the top of the vibration plate; and the second torsion spring is connected between the limiting plate and the vibration plate.

Preferably, the vibration plate is slightly higher than the first placement plate and slightly lower than the second placement plate.

(3) Advantageous effects

1. According to the invention, the mould can be automatically transmitted to the vibration mechanism through the driving mechanism and the feeding mechanism, the driving mechanism drives the vibration mechanism to work and vibrate the mould, so that concrete is paved in the mould, and the floor tile manufacturing effect is improved.

2. Can make things convenient for the mould to add concrete through blanking mechanism, reduce artificial intensity of labour, improve work efficiency, but also can stir the concrete, avoid the concrete to park for a long time and lead to solidification.

3. The vibration plate can be prevented from moving when vibrating through the material blocking mechanism, the vibration effect of the mold is guaranteed, and concrete can be prevented from falling on the vibration plate after the mold is moved.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of a first part of the present invention.

Fig. 3 is a schematic perspective view of a second part of the present invention.

Fig. 4 is a schematic perspective view of a third part of the present invention.

Fig. 5 is a schematic view of a third partial perspective view of the present invention.

Fig. 6 is a partial enlarged view of the portion a of the present invention.

Fig. 7 is a schematic perspective view of a blanking mechanism of the present invention.

Fig. 8 is a partial enlarged view of the portion B of the present invention.

The marks in the drawings are: the device comprises a base, a first placing plate, a 3-mounting frame, a 4-second placing plate, a 41-locating frame, a 5-lifting mechanism, a 51-supporting column, a 52-lifting column, a 53-vibrating plate, a 54-reset spring, a 6-driving mechanism, a 61-servo motor, a 62-fixed block, a 63-first transmission rod, a 64-diamond-shaped rod, a 65-belt transmission assembly, a 7-vibrating mechanism, a 71-convex disc, a 72-inner diamond-shaped sleeve, a 73-disc, a 74-guide rail, a 75-sliding rod, a 76-contact ball, an 8-feeding mechanism, a 81-fixed rail, a 82-sliding block, a 83-elastic piece, a 84-rack, a 85-sector gear, a 86-common spring, a 87-wedge block, a 9-blanking mechanism, a 91-discharging frame, a 92-second transmission rod, a 93-stirring shaft, a 94-bevel gear, a 95-rotating rod, a 96-baffle, a 97-first torsion spring, a 98-transmission belt, a 10-blocking mechanism, a 101-limiting plate and a 102-second torsion spring.

Detailed Description

The invention is further described below with reference to the drawings and examples.

Example 1

The utility model provides a ceramic tile making devices that archaize building processing was used, as shown in fig. 1-5, including base 1, first board 2 of placing, mounting bracket 3, board 4 is placed to the second, locating frame 41, elevating system 5, actuating mechanism 6, vibration mechanism 7 and feed mechanism 8, base 1 top right side is connected with first board 2 of placing, both sides all are connected with mounting bracket 3 around in the middle of the base 1, base 1 top left side is connected with the second and places board 4, the top that the board 4 was placed to the second is connected with locating frame 41, elevating system 5 is installed in the middle of the base 1 top, actuating mechanism 6 is installed in the left of base 1 top, be connected with vibration mechanism 7 between actuating mechanism 6 and the elevating system 5, be connected with feed mechanism 8 between mounting bracket 3 and the actuating mechanism 6.

The lifting mechanism 5 comprises a support column 51, a lifting column 52, a vibrating plate 53 and a return spring 54, wherein four support columns 51 are connected in the middle of the top of the base 1, the lifting column 52 is connected to the tops of the four support columns 51 in a sliding mode, the vibrating plate 53 is connected between the tops of the four lifting columns 52, the return spring 54 is connected between the bottom of the vibrating plate 53 and the top of the support column 51, and the return spring 54 is sleeved on the outer side of the lifting column 52.

The driving mechanism 6 comprises a servo motor 61, fixed blocks 62, first transmission rods 63, diamond rods 64 and a belt transmission assembly 65, wherein the servo motor 61 is installed on the left side of the top of the base 1, the fixed blocks 62 are connected to the front side and the rear side of the middle of the base 1, the first transmission rods 63 are connected to the two fixed blocks 62 in a rotating mode, the diamond rods 64 are connected between the two first transmission rods 63, and the belt transmission assembly 65 is connected between an output shaft of the servo motor 61 and the first transmission rods 63.

The vibration mechanism 7 comprises a convex disc 71, an inner diamond-shaped sleeve 72, a disc 73, a guide rail 74, a sliding rod 75 and a contact ball 76, wherein the inner diamond-shaped sleeve 72 is connected to the diamond-shaped rod 64 in a sliding manner, the convex disc 71 is connected to the outer side of the front portion of the inner diamond-shaped sleeve 72, the disc 73 is connected to the rear portion of the outer side of the inner diamond-shaped sleeve 72 in a rotating manner, the guide rail 74 is connected to the top of the base 1, the sliding rod 75 is connected to the guide rail 74 in a sliding manner, the sliding rod 75 is connected to the disc 73, the contact ball 76 is connected to the bottom of the vibration plate 53, and the contact ball 76 is in contact fit with the convex disc 71.

The feeding mechanism 8 comprises a fixed rail 81, a sliding block 82, an elastic piece 83, a rack 84, a sector gear 85, a common spring 86 and a wedge block 87, wherein the fixed rail 81 is connected to the mounting frames 3 on the front side and the rear side, the sliding block 82 is connected to the fixed rail 81 in a sliding mode, the elastic piece 83 is connected between the sliding block 82 and the fixed rail 81, the rack 84 is connected to the bottom of the sliding block 82, the sector gear 85 is connected to the first transmission rod 63, the sector gear 85 is meshed with the rack 84, the wedge block 87 is connected to the left portion of the rack 84 in a sliding mode, and the common spring 86 is connected between the wedge block 87 and the rack 84.

When the device is required to be used for manufacturing the archaized floor tile, the die is placed in the positioning frame 41 on the second placing plate 4, the servo motor 61 is started to work, the servo motor 61 drives the first transmission rod 63 to rotate through the belt transmission assembly 65, the first transmission rod 63 rotates to drive the sector gear 85 to rotate, the sector gear 85 rotates to drive the rack 84 to move leftwards, the sliding block 82 moves leftwards along with the first transmission rod 82, the elastic piece 83 is compressed, the die is blocked by the positioning frame 41 and cannot be pushed leftwards by the wedge block 87, the wedge block 87 moves inwards to the rack 84, the common spring 86 compresses, when the wedge block 87 moves to the left side of the die, the wedge block 87 is used for ejecting the wedge block 87 under the action of the common spring 86, the sector gear 85 is separated from the rack 84, the sliding block 82 and the rack 84 are driven to reset under the action of the elastic piece 83, the rack 84 resets and drives the die to move rightwards to the upper part of the vibration plate 53, at the moment, people can pour concrete into the die, when the first transmission rod 63 rotates, the diamond 64 rotates to drive the convex disc 71 to move leftwards, the convex disc 71 rotates, the convex disc 71 is matched with the ball 76 moves upwards, the convex disc 73 is not contacted with the ball 73 to move backwards, and the vibration disc 73 can be contacted with the vibration disc 73, and the vibration disc is not contacted with the vibration disc 73, and then the vibration disc 73 can move backwards, and the vibration disc 73 is required to move backwards, and the vibration disc 73 is not to move backwards and can be contacted with the vibration disc 73. When the vibration plate 53 needs to be driven to vibrate continuously, the sliding rod 75 is pulled forwards to enable the convex disc 71 to be in contact with the contact ball 76, when the antique floor tile needs to be manufactured continuously, another die is placed in the positioning frame 41, the die is driven to move rightwards through the wedge block 87, the die on the vibration plate 53 is pushed rightwards to the first placing plate 2 by the left die, and then people can take away the die on the first placing plate 2.

Example 2

On the basis of embodiment 1, as shown in fig. 7-8, the blanking mechanism 9 is further included, the blanking mechanism 9 includes a blanking frame 91, a second transmission rod 92, a stirring shaft 93, a bevel gear 94, a rotating rod 95, a baffle 96, a first torsion spring 97 and a transmission belt 98, the blanking frame 91 is connected between the fixed rails 81 on two sides, a blanking port is opened on the right side of the bottom of the blanking frame 91, the second transmission rod 92 is rotatably connected to the front side of the blanking frame 91, the stirring shaft 93 is rotatably connected to the stirring shaft 93 in the blanking frame 91, the transmission belt 98 is connected between the top of the stirring shaft 93 and the top of the second transmission rod 92, bevel gears 94 are connected to the bottom end of the second transmission rod 92 and the first transmission rod 63 on the front side, the two bevel gears 94 are meshed, the rotating rod 95 is rotatably connected to the outer wall of the blanking frame 91, the baffle 96 is connected to the bottom of the rotating rod 95, the baffle 96 blocks the blanking port, and the first torsion spring 97 is connected between the rotating rod 95 and the outer wall of the blanking frame 91.

Pouring concrete into the blowing frame 91, the first transmission rod 63 drives the second transmission rod 92 to rotate through the bevel gear 94 when rotating, the second transmission rod 92 rotates to drive the stirring shaft 93 to rotate through the transmission belt 98, the stirring shaft 93 rotates to stir the concrete in the blowing frame 91, the concrete is prevented from being parked for a long time to be solidified, when the concrete needs to be poured into the mould on the vibration plate 53, the rotating rod 95 drives the baffle 96 to rotate, the baffle 96 does not block the blanking port of the blowing frame 91, the first torsion spring 97 compresses, the concrete in the blowing frame 91 flows out through the blanking port, after a proper amount of concrete is poured into the mould, the rotating rod 95 is loosened, and the baffle 96 is driven to reset under the action of the first torsion spring 97 to block the blanking port.

Example 3

On the basis of embodiment 2, as shown in fig. 5-6, the vibration plate comprises a material blocking mechanism 10, wherein the material blocking mechanism 10 comprises a limiting plate 101 and a second torsion spring 102, the right side of the top of the vibration plate 53 is rotationally connected with two limiting plates 101, the two limiting plates 101 are symmetrically arranged in front-back direction, and the second torsion spring 102 is connected between the limiting plates 101 and the vibration plate 53.

Limiting plate 101 can prevent vibrations board 53 mould right movement when vibrations, guarantees the vibrations effect to the mould, can avoid concrete to fall on vibrations board 53 moreover, and when left mould promotes the mould on vibrations board 53 when moving right, the mould on right side promotes two limiting plates 101 rotation, and second torsion spring 102 compresses, then takes away the mould on the board 2 of placing, and limiting plate 101 resets under the effect of second torsion spring 102.

The foregoing examples have shown only the preferred embodiments of the invention, which are described in more detail and are not to be construed as limiting the scope of the invention. It should be noted that modifications, improvements and substitutions can be made by those skilled in the art without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (2)

1. The utility model provides a floor tile manufacturing installation that archaize building processing was used which characterized in that includes:

a first placing plate (2) is connected to one side of the top of the base (1);

the two mounting frames (3) are arranged, and the two mounting frames (3) are symmetrically connected to the base (1);

a second placing plate (4) connected to the base (1) at a side away from the first placing plate (2);

a positioning frame (41) connected to the top of the second placing plate (4);

a lifting mechanism (5) mounted on the base (1);

a drive mechanism (6) mounted on the base (1);

a vibration mechanism (7) connected between the driving mechanism (6) and the lifting mechanism (5);

the feeding mechanism (8) is connected between the mounting frame (3) and the driving mechanism (6);

the lifting mechanism (5) comprises:

the support posts (51) are at least two, and the support posts (51) are connected to the top of the base (1);

a lifting column (52) slidably connected to the column (51);

a vibration plate (53) connected to the top of the lifting column (52);

a return spring (54) connected between the vibration plate (53) and the stay (51);

the driving mechanism (6) comprises:

a servo motor (61) connected to the base (1);

the fixing blocks (62) are provided with two fixing blocks, and the two fixing blocks (62) are symmetrically connected to the base (1);

the two first transmission rods (63) are arranged, and the two first transmission rods (63) are respectively connected to the two fixed blocks (62) in a rotary mode;

a diamond-shaped rod (64) connected between the two first transmission rods (63);

a belt transmission assembly (65) connected between the output shaft of the servo motor (61) and the first transmission rod (63);

the vibration mechanism (7) comprises:

an inner diamond sleeve (72) slidably connected to the diamond rod (64);

a cam (71) connected to one end of the inner diamond-shaped sleeve (72);

a disk (73) rotatably connected to the inner diamond-shaped sleeve (72);

a guide rail (74) connected to the top of the base (1);

a slide bar (75) slidably connected to the guide rail (74), the slide bar (75) being connected to the disc (73);

a contact ball (76) connected to the bottom of the vibration plate (53), the contact ball (76) being in contact engagement with the cam (71);

the feed mechanism (8) comprises:

the two fixed rails (81) are arranged, and the two fixed rails (81) are respectively connected to the mounting frames (3) on the two sides;

a slider (82) slidably connected to the fixed rail (81);

an elastic member (83) connected between the slider (82) and the end of the fixed rail (81);

a rack (84) connected to the bottom of the slider (82);

the two sector gears (85) are arranged, the two sector gears (85) are respectively connected to the first transmission rods (63) at the two sides, and the sector gears (85) are meshed with the racks (84);

a wedge (87) slidably connected to the rack (84);

a normal spring (86) connected between the wedge block (87) and the rack (84);

still including blanking mechanism (9), blanking mechanism (9) are including:

the discharging frame (91) is connected between the fixed rails (81) on two sides, and a discharging port is formed in the right side of the bottom of the discharging frame (91);

a second transmission rod (92) which is rotatably connected to the discharging frame (91);

a stirring shaft (93) rotatably connected in the discharging frame (91);

a transmission belt (98) connected between the stirring shaft (93) and the second transmission rod (92);

the bevel gears (94) are arranged, the two bevel gears (94) are respectively connected to the second transmission rod (92) and the first transmission rod (63), and the two bevel gears (94) are meshed;

the rotating rod (95) is rotationally connected to the outer wall of the discharging frame (91);

the baffle plate (96) is connected to the bottom of the rotating rod (95), and the baffle plate (96) blocks the blanking port;

a first torsion spring (97) connected between the rotating rod (95) and the outer wall of the discharging frame (91);

the device also comprises a blocking mechanism (10), wherein the blocking mechanism (10) comprises:

a limiting plate (101) connected to the top of the vibration plate (53);

and a second torsion spring (102) connected between the limiting plate (101) and the vibration plate (53).

2. The floor tile making device for archaized building processing according to claim 1, wherein the vibration plate (53) is slightly higher than the first placing plate (2) and slightly lower than the second placing plate (4).

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