CN114517569A

CN114517569A - Building ceramic tile lays reinforcing apparatus

Info

Publication number: CN114517569A
Application number: CN202210184413.4A
Authority: CN
Inventors: 叶秋榕
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-02-28
Filing date: 2022-02-28
Publication date: 2022-05-20

Abstract

The invention relates to a reinforcing device, in particular to a building tile laying reinforcing device. Need to design one kind and can not need the people to promote to consolidate the ceramic tile is beaten the reality, and is more laborsaving, still convenient building ceramic tile lays reinforcing apparatus. The utility model provides a reinforcing apparatus is laid to building ceramic tile, includes gyro wheel, casing and connecting rod etc. and the cross-under of bilateral symmetry rotary type has the connecting rod between the casing front and back both sides lower part, and both ends all the rigid coupling have the gyro wheel around the connecting rod. The ceramic tile fixing device is characterized in that the driving mechanism is started to operate to drive the left connecting rod to rotate positively, the left connecting rod to rotate positively drives the left roller to rotate positively, the left roller drives the device to move rightwards through the right roller, meanwhile, the driving mechanism also drives the swinging mechanism to operate, the swinging mechanism operates to drive the round ball to swing up and down through the swinging rod, the round ball swings up and down to knock the ceramic tile to fix the ceramic tile, and therefore an operator does not need to push the ceramic tile to knock the ceramic tile to fix the ceramic tile, and the ceramic tile fixing device is labor-saving and convenient.

Description

Building ceramic tile lays reinforcing apparatus

Technical Field

The invention relates to a reinforcing device, in particular to a building tile laying reinforcing device.

Background

In the construction, collect impurity subaerial for convenient people, do not influence the surrounding environment, need lay the ceramic tile subaerial, the ceramic tile is laid well the back, in order to guarantee that the ceramic tile is more firm, does not influence people's walking, needs to strike the ceramic tile real reinforcement.

Chinese patent application No. CN201911241783.1 discloses a linkage driving type flattening apparatus for laying tiles; the worm is driven to rotate by the servo motor, the worm drives the worm wheel to rotate, the coaxial second gear also rotates and drives the first gear to rotate, so that the lifting assembly works, the first sliding rod and the second sliding rod are limited by the first bulge and the second bulge and synchronously do up-and-down lifting movement, the flattening assembly is driven to do lifting movement by a connecting rod, and the laid ceramic tiles are flattened conveniently and quickly; the cleaning assembly is also arranged, the driving shaft rotates along with the worm, and the driven shaft is driven to rotate through the rotation of the gear in the gear box, so that the rotation of the plurality of cleaning heads is completed, and the ceramic tiles are cleaned; a rolling component is also arranged, and a press roller is adopted to roll the ceramic tile for the second time, so as to further level the ceramic tile; rotate a screw rod through a hand wheel to drive the pulley and go up and down, conveniently adjust the position of compression roller, above-mentioned patent is nevertheless can be consolidated the ceramic tile is beaten to reality, still needs the people to promote with the hand and beats the reality with the ceramic tile and consolidate, and is harder, still troublesome.

The invention aims to solve the problems in the patent, and provides a building tile laying and reinforcing device which can be used for reinforcing a tile without being pushed by people, is labor-saving and is convenient.

Disclosure of Invention

In order to overcome the defects that although the tile can be tamped for reinforcement, the tile needs to be tamped for reinforcement by pushing with hands, and the device is labor-saving and convenient for laying and reinforcing the building tile, the device can be used for tamping and reinforcing the tile without pushing with hands.

The invention is realized by the following technical approaches:

the utility model provides a building ceramic tile lays reinforcing apparatus, including the gyro wheel, a housing, the connecting rod, the swinging arms, the ball, actuating mechanism and swing mechanism, the cross-under of bilateral symmetry rotary type has the connecting rod between the casing front and back both sides lower part, both ends all rigid coupling has the gyro wheel around the connecting rod, swing mechanism is installed to the casing inboard, the last rigid coupling of swing mechanism has the swinging arms, placing of swinging arms internal sliding formula is used for striking the real three ball that carries out the reinforcement with the ceramic tile, install the actuating mechanism who is used for driving the swing mechanism function between left side connecting rod and the casing, actuating mechanism is connected with swing mechanism.

Further, the driving mechanism comprises a fixing ring, a motor, a driving shaft, a transmission component, a short shaft, a first driving bevel gear, a first bevel gear, a fixing block, a second driving bevel gear, a rotating shaft, a second bevel gear, a third bevel gear, a fixing plate and a guide rod, the rear side of the left connecting rod is fixedly connected with the first bevel gear along the circumferential direction, the lower part of the rear side in the shell is fixedly connected with the fixing plate, the short shaft is rotatably connected with the front part of the fixing plate in a penetrating way, the first driving bevel gear for driving the first bevel gear to rotate forwards is fixedly sleeved on the left end of the short shaft, the fixing block is fixedly connected with the upper part of the rear side in the shell in a rotating way, the rotating shaft is rotatably connected with the front part of the fixing shaft in a penetrating way, the second bevel gear is fixedly sleeved on the upper part of the rotating shaft, the guide rod is fixedly connected with the guide rod on the front side of the bottom of the fixing block, the third bevel gears are fixedly sleeved on the front ends of the guide rod and the bottom ends of the rotating shaft, the two third bevel gears are meshed, and the rear ends of the guide rod are connected with the swinging mechanism, a fixing ring is fixedly connected to the left side of the upper portion of the rear side face in the shell, the fixing ring is located on the left side of the fixing block, a motor is installed on the inner side of the fixing ring along the circumferential direction, a driving shaft is fixedly connected to the end portion of an output shaft of the motor, a second driving bevel gear used for driving a second bevel gear to rotate reversely is fixedly installed at the right end of the driving shaft in a fixing sleeve mode, the second driving bevel gear is meshed with the second bevel gear, a transmission assembly is connected between the left side of the driving shaft and the right side of the short shaft and comprises two belt pulleys and a flat belt, one of the belt pulleys is fixedly sleeved on the left side of the driving shaft, the other belt pulley is fixedly sleeved on the right side of the short shaft, and the flat belt is wound between the two belt pulleys.

Further, the swing mechanism comprises a driving rod, a mounting frame, a connecting frame, a tooth-lacking bevel gear, a fourth bevel gear, a rotating rod, a fixing frame, a friction ball, a first spring, a linkage assembly and a torsion spring, the mounting frame is fixedly connected between the upper parts of the front side surface and the rear side surface in the housing, the fixing frame for driving the rotating rod to rotate in a positive and negative alternate mode is rotatably connected in the middle of the mounting frame in a penetrating way, the right side of the fixing frame is fixedly connected with the rotating rod, the torsion spring is wound between the outer right side of the fixing frame and the middle part of the right side surface of the mounting frame, the rotating rod is rotatably placed in the fixing frame, three friction balls are slidably connected on the right side of the rotating rod along the embedded type with uniform circumferential intervals, the friction ball is in contact with the inner side of the fixing frame, the first spring is connected between the inner side of the friction ball and the inner side of the rotating rod, the fourth bevel gear is fixedly sleeved on the left side surface of the mounting frame, the connecting frame is fixedly connected with the connecting frame in a penetrating way, a linkage assembly is connected between the rear end of the driving rod and the rear end of the guide rod, the linkage assembly is composed of two belt pulleys and a flat belt, one belt pulley is fixedly sleeved at the rear end of the driving rod, the other belt pulley is fixedly sleeved at the rear end of the guide rod, the flat belt is wound between the two belt pulleys, the front end of the driving rod is fixedly connected with a tooth-missing bevel gear for driving a fourth bevel gear to rotate, and the tooth-missing bevel gear is meshed with the left-side fourth bevel gear.

Furthermore, the ceramic tile flattening mechanism comprises guide rods, a second spring, a connecting block, a mounting disc, a long rod, contact wheels, volute springs and a limiting plate, wherein the two guide rods are fixedly connected with the right sides of the lower parts of the front side surface and the rear side surface in the shell in an embedded manner, the connecting block is sleeved between the two guide rods on the front side and between the two guide rods on the rear side in a sliding manner, the mounting disc is fixedly connected in the middle of the connecting block in a penetrating manner, the long rod is rotatably connected between the right sides of the lower parts of the front side surface and the rear side surface of the shell in a penetrating manner and penetrates through the mounting discs on the front side surface and the rear side surface, the six contact wheels for flattening the warped ceramic tiles are fixedly sleeved on the long rod at uniform intervals, the second spring is symmetrically connected between the outer side of the top of the connecting block and the inner side of the shell, the second spring is sleeved on the guide rods, the lower right side of the lower part of the outer front side surface of the shell is fixedly connected with the limiting plate, the limiting plate is positioned above the long rod, a volute spring is connected between the bottom of the limit plate and the front side of the long rod.

Further, the ceramic tile flattening device comprises a flattening auxiliary mechanism for flattening ceramic tiles, wherein the flattening auxiliary mechanism comprises a reel, a pull wire, a connecting plate, a first piston rod, a first piston cylinder, an air guide disc, a second piston cylinder, a second piston rod, a hinged plate, a pressure plate, vertical rods and a third spring, the air guide disc is installed in the middle of the right sides of the front side face and the rear side face in the shell, the first piston cylinder is fixedly connected to one end of the air guide disc, the second piston cylinder is fixedly connected to the other end of the air guide disc, the first piston rod is placed in the first piston cylinder in a sliding mode, the connecting plate is fixedly connected to the top of the first piston rod, the reel is fixedly sleeved on the front side and the rear side of each long rod, the pull wire for driving the connecting plate to move downwards is wound on the reel, the tail end of the pull wire is fixedly connected with the left side of the bottom of the connecting plate, the second piston rod is placed in the second piston cylinder in a sliding mode, and the two vertical rods are fixedly connected to the lower portions of the front side and the rear side face in the shell in an embedded mode, the sliding type sleeves are arranged between two front vertical rods and between two rear vertical rods to form a hinged plate, the inner sides of the bottoms of the hinged plates at the front side and the rear side are fixedly connected with a pressure plate for flattening a ceramic tile, the outer sides of the tops of the hinged plates at the front side and the rear side are connected with the inner side of the shell through bilateral symmetry, the third springs are sleeved on the vertical rods, and the tops of the hinged plates are fixedly connected with the bottom ends of the second piston rods.

Furthermore, still including being used for playing the cushioning effect's buffer gear, buffer gear is including the buffer block, the collar, guide post and fourth spring, the outer front and back both sides of swinging arms all rigid coupling have the collar, the even spaced slidingtype cross-under in circumference has six guide posts on the collar, all the rigid coupling has the buffer block that is used for flattening the ceramic tile between the six guide post outer ends of front side and between the six guide post outer ends of rear side, the buffer block medial surface contacts with the ball, the even spaced six fourth springs that are connected with between front side buffer block trailing flank and the front side collar leading flank, the even spaced six fourth springs that are connected with between rear side buffer block leading flank and the rear side collar trailing flank, the fourth spring cover is on the guide post.

Further, including being used for the clean mechanism with impurity removal, clean mechanism is including belt assembly, axis of rotation and brush wheel, the cross-under of rotary type has the axis of rotation between the left side of both sides lower part around the casing, the axis of rotation front side has the brush wheel that is used for cleaing away the concrete on the ceramic tile along circumference rigid coupling, be connected with belt assembly between axis of rotation front side and the left side connecting rod front side, belt assembly comprises two belt pulleys and flat belt, the fixed suit of one of them belt pulley is in left side connecting rod front side, the fixed suit of another belt pulley is in the axis of rotation front side, flat belt winds between two belt pulleys.

Furthermore, the material of the ball is rubber.

The invention has the remarkable advantages that:

1. starting actuating mechanism function and driving left side connecting rod corotation, left side connecting rod corotation drives left side gyro wheel corotation, and the left side gyro wheel drives this device through the right side gyro wheel and moves right, and simultaneously, actuating mechanism still drives the swing mechanism function, and the swing mechanism function drives the ball luffing motion through the swinging arms, and the ball luffing motion is hit the real ceramic tile through the buffer block and is consolidated, so, need not operating personnel to promote to hit the real ceramic tile and consolidate, and is more laborsaving, still convenient.

2. When flattening mechanism and ceramic tile contact, then explain the ceramic tile unevenness, there is the perk phenomenon, flatten the mechanism and remove to move the ceramic tile that will perk and flatten, so, can avoid the ceramic tile of perk to be strikeed by the ball and lead to the breakage.

3. When the contact wheel contacts with the tilted ceramic tile, the long rod rotates forward to drive the flattening auxiliary mechanism to operate, the flattening auxiliary mechanism operates to flatten the tilted ceramic tile preliminarily, and thus, the tilted ceramic tile can be flattened better.

Drawings

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

FIG. 2 is a first partial cross-sectional structural schematic of the present invention.

FIG. 3 is a second partial sectional structural view of the present invention.

Fig. 4 is a third partial sectional structural schematic view of the present invention.

Fig. 5 is a schematic view of a fourth partial sectional structure of the present invention.

FIG. 6 is a schematic view of a fifth partial sectional structure of the present invention.

Fig. 7 is an enlarged schematic view of part a of the present invention.

Fig. 8 is a schematic view of a first partial body structure according to the present invention.

Fig. 9 is an enlarged view of part B of the present invention.

FIG. 10 is a schematic view of a second partial body structure according to the present invention.

FIG. 11 is a sixth partial sectional structural view of the present invention.

Fig. 12 is an enlarged schematic view of part C of the present invention.

Fig. 13 is a perspective view of a third embodiment of the present invention.

Fig. 14 is a seventh partial sectional structural view of the present invention.

Fig. 15 is a partial sectional structural view of an eighth embodiment of the present invention.

Labeled as: 1-roller, 2-shell, 21-connecting rod, 3-oscillating rod, 31-ball, 4-driving mechanism, 41-fixed ring, 42-motor, 43-driving shaft, 44-driving component, 45-short shaft, 46-first driving bevel gear, 47-first bevel gear, 48-fixed block, 49-second driving bevel gear, 410-rotating shaft, 411-second bevel gear, 412-third bevel gear, 413-fixed plate, 414-guide rod, 5-oscillating mechanism, 51-driving rod, 52-mounting frame, 53-connecting frame, 54-missing bevel gear, 55-fourth bevel gear, 56-rotating rod, 57-mounting frame, 58-friction ball, 59-first spring, 510-linkage component, 511-torsion spring, 6-flattening mechanism, 61-guide rod, 62-second spring, 63-connecting block, 64-mounting plate, 65-long rod, 66-contact wheel, 67-spiral spring, 68-limit plate, 7-flattening auxiliary mechanism, 71-reel, 72-stay, 73-connecting plate, 74-first piston rod, 75-first piston cylinder, 76-air guide plate, 78-second piston cylinder, 79-second piston rod, 710-hinge plate, 711-pressure plate, 712-vertical rod, 713-third spring, 8-buffer mechanism, 81-buffer block, 82-mounting ring, 83-guide column, 84-fourth spring, 9-cleaning mechanism, 91-belt component, 92-rotating shaft, 93-Brush wheel.

Detailed Description

The invention is further explained by combining the drawings in the specification, and the embodiments of the invention are given by combining the drawings in the specification.

Example 1

A building tile laying and reinforcing device comprises a roller 1, a shell 2, a connecting rod 21, a swing rod 3, a round ball 31, a driving mechanism 4 and a swing mechanism 5, please refer to fig. 1-7, the connecting rod 21 is connected between the lower parts of the front side and the rear side of the shell 2 in a left-right symmetrical rotating mode in a penetrating mode, the roller 1 is installed at the front end and the rear end of the connecting rod 21 in a welding connection mode, the swing mechanism 5 is installed on the inner side of the shell 2, the swing rod 3 is fixedly connected to the swing mechanism 5, three round balls 31 are placed in the swing rod 3 in a sliding mode, the round balls 31 are made of rubber, when the round balls 31 swing, the tile can be actually knocked and reinforced, the driving mechanism 4 is installed between the left connecting rod 21 and the shell 2, the driving mechanism 4 is connected with the swing mechanism 5, and when the driving mechanism 4 operates, the driving mechanism 4 can drive the swing mechanism 5 to operate.

The driving mechanism 4 includes a fixing ring 41, a motor 42, a driving shaft 43, a transmission assembly 44, a short shaft 45, a first driving bevel gear 46, a first bevel gear 47, a fixing block 48, a second driving bevel gear 49, a rotating shaft 410, a second bevel gear 411, a third bevel gear 412, a fixing plate 413 and a guide rod 414, as shown in fig. 1, 2, 4 and 5, the first bevel gear 47 is installed on the rear side of the left connecting rod 21 along the circumferential direction in a welding connection manner, the fixing plate 413 is installed on the left side of the lower portion of the rear side surface in the housing 2 in a welding connection manner, the short shaft 45 is rotatably connected in front of the fixing plate 413 in a penetrating manner, the first driving bevel gear 46 is fixedly sleeved on the left end of the short shaft 45, when the first driving bevel gear 46 is engaged with the first bevel gear 47 in the forward rotation manner, the first driving bevel gear 46 can drive the first forward rotation bevel gear 47, the fixing block 48 is installed on the left side of the upper portion of the rear side surface in the housing 2 in a welding connection manner, a rotating shaft 410 is rotatably connected in front of the fixed block 48 in a penetrating manner, a second bevel gear 411 is fixedly sleeved on the upper portion of the rotating shaft 410, a guide rod 414 is installed on the front side of the bottom of the fixed block 48 in a welding connection manner, third bevel gears 412 are fixedly sleeved on the front end of the guide rod 414 and the bottom end of the rotating shaft 410, the two third bevel gears 412 are meshed with each other, the rear end of the guide rod 414 is connected with the swing mechanism 5, a fixed ring 41 is installed on the left side of the upper portion of the rear side face in the shell 2 in a welding connection manner, the fixed ring 41 is positioned on the left side of the fixed block 48, a motor 42 is installed on the inner side of the fixed ring 41 along the circumferential direction, a driving shaft 43 is fixedly connected to the output shaft end of the motor 42, a second driving bevel gear 49 is fixedly sleeved on the right end of the driving shaft 43, the second driving bevel gear 49 is meshed with the second bevel gear 411, when the second driving bevel gear 49 rotates forwardly, the second driving bevel gear 49 can drive the second bevel gear 411 to rotate reversely, a transmission component 44 is connected between the left side of the driving shaft 43 and the right side of the short shaft 45, the transmission assembly 44 is composed of two belt pulleys and a flat belt, wherein one belt pulley is fixedly sleeved on the left side of the driving shaft 43, the other belt pulley is fixedly sleeved on the right side of the short shaft 45, and the flat belt is wound between the two belt pulleys.

The swing mechanism 5 includes a driving rod 51, a mounting frame 52, a connecting frame 53, a tooth-missing bevel gear 54, a fourth bevel gear 55, a rotating rod 56, a fixing frame 57, friction balls 58, a first spring 59, a linkage component 510 and torsion springs 511, as shown in fig. 2, fig. 6 and fig. 7, the mounting frame 52 is installed between the upper portions of the front and rear side surfaces in the casing 2 in a welding connection manner, the fixing frame 57 is rotatably connected in the middle of the mounting frame 52 in a penetrating manner, the right side of the fixing frame 57 is installed with the swing rod 3 in a welding connection manner, when the fixing frame 57 rotates forward and backward alternately, the fixing frame 57 can drive the swing rod 3 to rotate forward and backward alternately, the torsion springs 511 are wound between the outer right side of the fixing frame 57 and the middle of the right side surface of the mounting frame 52, the rotating rod 56 is rotatably placed in the fixing frame 57, and the right side of the rotating rod 56 is slidably connected with three friction balls 58 in an embedded manner at uniform intervals along the circumferential direction, the friction ball 58 contacts the inner side of the fixed frame 57, the first spring 59 is arranged between the inner side of the friction ball 58 and the inner side of the rotating rod 56 in a welding connection mode, the fourth bevel gears 55 are fixedly sleeved on the left and right sides of the rotating rod 56, the connecting frame 53 is arranged at the rear part of the left side surface of the mounting frame 52 in a welding connection mode, the driving rod 51 is rotatably connected to the left part of the connecting frame 53 in a penetrating mode, the linkage component 510 is connected between the rear end of the driving rod 51 and the rear end of the guide rod 414, the linkage component 510 is composed of two belt pulleys and a flat belt, one belt pulley is fixedly sleeved at the rear end of the driving rod 51, the other belt pulley is fixedly sleeved at the rear end of the guide rod 414, a flat belt is wound between the two belt pulleys, the front end of the driving rod 51 is provided with a tooth-missing bevel gear 54 in a welding connection mode, the tooth-missing bevel gear 54 is meshed with a left-side fourth bevel gear 55, when the missing-tooth bevel gear 54 rotates reversely, the missing-tooth bevel gear 54 can drive the fourth bevel gear 55 to rotate.

Firstly, an operator puts the device on a ceramic tile, a roller 1 contacts the ceramic tile, then a driving mechanism 4 is started, the driving mechanism 4 operates to drive a left connecting rod 21 to rotate forwards, the left connecting rod 21 rotates forwards to drive a left roller 1 to rotate forwards, the left roller 1 rotates forwards to drive a shell 2 to move rightwards through the right roller 1, the shell 2 moves rightwards to drive a swinging mechanism 5 to move rightwards, the swinging mechanism 5 moves rightwards to drive a swinging rod 3 to move rightwards, the swinging rod 3 moves rightwards to drive a spherical ball 31 to move rightwards, meanwhile, the driving mechanism 4 also drives the swinging mechanism 5 to operate, the swinging mechanism 5 operates to drive the swinging rod 3 to rotate forwards and backwards alternately, the swinging rod 3 rotates forwards and backwards to drive the spherical ball 31 to swing upwards and downwards alternately, the ceramic tile can be knocked and compacted to be consolidated, and the spherical ball 31 is made of rubber, so that the ceramic tile can be better consolidated, the process is repeated, and the round ball 31 continuously moves rightwards and swings upwards and downwards to tamp and reinforce the ceramic tile. After the tiles are reinforced, the driving mechanism 4 is closed, the driving mechanism 4 stops driving the left connecting rod 21 to rotate positively, the left connecting rod 21 stops driving the left roller 1 to rotate positively, the left roller 1 stops driving the shell 2 to move rightwards through the right roller 1, the device also stops moving rightwards, meanwhile, the driving mechanism 4 stops driving the swing mechanism 5 to operate, the swing mechanism 5 stops driving the swing rod 3 to rotate in a positive-negative alternating mode, and the swing rod 3 stops driving the ball 31 to rotate in a positive-negative alternating mode.

When the device is placed on a ceramic tile, the motor 42 is started to rotate positively, the motor 42 drives the driving shaft 43 to rotate positively, the driving shaft 43 drives the second driving bevel gear 49 to rotate positively, the second driving bevel gear 49 drives the second bevel gear 411 to rotate positively, the second bevel gear 411 drives the rotating shaft 410 to rotate positively, the rotating shaft 410 drives the front-side third bevel gear 412 to rotate positively, the front-side third bevel gear 412 drives the rear-side third bevel gear 412 to rotate negatively, the rear-side third bevel gear 412 drives the guide rod 414 to rotate negatively, the guide rod 414 rotates negatively to drive the swing mechanism 5 to operate, so that the ceramic tile 31 swings up and down to knock the ceramic tile for strengthening, meanwhile, the driving shaft 43 also drives the transmission assembly 44 to rotate positively, the transmission assembly 44 drives the short shaft 45 to rotate positively, the short shaft 45 drives the first driving bevel gear 46 to rotate positively, and the first driving bevel gear 46 is meshed with the first bevel gear 47, first drive bevel gear 46 drives first bevel gear 47 corotation, and first bevel gear 47 corotation drives left side connecting rod 21 corotation, and left side connecting rod 21 corotation drives left side gyro wheel 1 corotation, just also makes this device move just also right, just also makes ball 31 move right more comprehensive strike the ceramic tile and consolidate. When all the tiles are compacted and reinforced, the motor 42 is turned off, the motor 42 stops driving the short shaft 45 to rotate forward through the transmission assembly 44, the first driving bevel gear 46 stops driving the first bevel gear 47 to rotate forward, the device stops moving rightward, meanwhile, the guide rod 414 stops driving the swing mechanism 5 to operate, and the ball 31 stops swinging up and down.

When the motor 42 is started, the guide rod 414 rotates reversely to drive the linkage component 510 to rotate reversely, the linkage component 510 rotates reversely to drive the driving rod 51 to rotate reversely, the driving rod 51 rotates reversely to drive the missing-tooth bevel gear 54 to rotate reversely, the missing-tooth bevel gear 54 rotates reversely to drive the left-side fourth bevel gear 55 to rotate forward, the left-side fourth bevel gear 55 rotates forward to drive the rotating rod 56 to rotate forward, the rotating rod 56 rotates forward to drive the friction ball 58 to rotate forward, the friction ball 58 rotates forward to drive the fixing frame 57 to rotate forward, the torsion spring 511 is compressed, the friction ball 58 can more stably drive the fixing frame 57 to rotate forward due to the action of the first spring 59, the fixing frame 57 rotates forward to drive the swinging rod 3 to rotate forward, the swinging rod 3 rotates forward to drive the ball 31 to rotate forward to knock the tile to be strengthened, when the missing-tooth bevel gear 54 rotates reversely continuously to be disengaged with the left-side fourth bevel gear 55, the fixing frame 57 rotates reversely to drive the swinging rod 3 to swing upward and reset due to the action of the torsion spring 511, meanwhile, the fixed frame 57 drives the rotating rod 56 to rotate reversely through the friction ball 58, the rotating rod 56 drives the fourth bevel gear 55 to rotate reversely and reset, when the toothless bevel gear 54 rotates reversely and is engaged with the right fourth bevel gear 55 continuously, the toothless bevel gear 54 drives the right fourth bevel gear 55 to rotate reversely, the right fourth bevel gear 55 rotates reversely and drives the rotating rod 56 to rotate reversely, the rotating rod 56 rotates reversely and drives the fixed frame 57 to rotate reversely through the friction ball 58, the torsion spring 511 is stretched, the fixed frame 57 rotates reversely and drives the ball 31 to swing downwards through the swinging rod 3, the ball 31 swings downwards and is contacted with the ceramic tiles, the ceramic tiles are knocked and reinforced by the ball 31, when the toothless bevel gear 54 rotates reversely and is disengaged with the right fourth bevel gear 55 continuously, the fixed frame 57 rotates positively and drives the ball 31 to swing upwards and reset through the swinging rod 3 due to the action of the torsion spring 511, meanwhile, the rotating rod 56 drives the fourth bevel gear 55 to rotate positively and reset, repeating the above steps, the round ball 31 can continuously swing up and down to tamp the tile for reinforcement. When the motor 42 is turned off, the guide rod 414 stops driving the linkage assembly 510 to rotate reversely, the fixing frame 57 stops driving the swing rod 3 to rotate forward and backward alternately, and the ball 31 stops swinging up and down.

Example 2

On the basis of embodiment 1, the tile flattening device further comprises a flattening mechanism 6, wherein the flattening mechanism 6 comprises a guide rod 61, a second spring 62, a connecting block 63, a mounting plate 64, a long rod 65, a contact wheel 66, a volute spring 67 and a limiting plate 68, as shown in fig. 2, 8, 9 and 10, two guide rods 61 are installed at the right sides of the lower portions of the front side and the rear side in the shell 2 in an embedded manner in a welding connection manner, the connecting block 63 is sleeved between the two guide rods 61 at the front side and between the two guide rods 61 at the rear side in a sliding manner, the mounting plate 64 is fixedly penetrated in the middle of the connecting block 63, the long rod 65 is rotatably penetrated between the lower portions of the front side and the rear side of the shell 2, the long rod 65 penetrates through the mounting plates 64 at the front side and the rear side, six contact wheels 66 are fixedly sleeved on the long rod 65 at uniform intervals, when the contact wheels 66 move rightwards to contact with tiles, the raised tiles can be flattened by the contact wheels 66, bilateral symmetry is connected with second spring 62 between the connecting block 63 top outside and the casing 2 inboard, and second spring 62 cover is on guide bar 61, and limiting plate 68 is installed through welded connection's mode in casing 2 outer leading flank lower part right side, and limiting plate 68 is located stock 65 top, is connected with volute spiral spring 67 between limiting plate 68 bottom and the stock 65 front side.

The auxiliary flattening mechanism 7 further comprises an auxiliary flattening mechanism 7, the auxiliary flattening mechanism 7 comprises a reel 71, a pull wire 72, a connecting plate 73, a first piston rod 74, a first piston cylinder 75, an air guide disc 76, a second piston cylinder 78, a second piston rod 79, a hinged plate 710, a pressure plate 711, a vertical rod 712 and a third spring 713, please refer to fig. 2, fig. 11 and fig. 12, the air guide disc 76 is mounted in the middle of the right side of the front side and the right side of the inner side of the shell 2, the first piston cylinder 75 is mounted at one end of the air guide disc 76 in a welded connection mode, the second piston cylinder 78 is mounted at the other end of the air guide disc 76 in a welded connection mode, the first piston rod 74 is placed in the first piston cylinder 75 in an inward sliding mode, the connecting plate 73 is mounted at the top of the first piston rod 74 in a welded connection mode, the reel 71 is fixedly mounted on the front side and the rear side of the long rod 65, the pull wire 72 is wound on the reel 71, and the tail end of the pull wire 72 is fixedly connected with the left side of the bottom of the pull wire 73, when the pulling wire 72 is rolled, the pulling wire 72 can drive the connecting plate 73 to move downwards, the second piston rod 79 is placed in a sliding mode in the second piston cylinder 78, two vertical rods 712 are fixedly connected to the right sides of the lower portions of the front side surface and the rear side surface in the shell 2 in an embedded mode, a hinge plate 710 is sleeved between the two vertical rods 712 on the front side and between the two vertical rods 712 on the rear side in a sliding mode, a pressing plate 711 is installed on the inner sides of the bottoms of the hinge plates 710 on the front side and on the rear side in a welding connection mode, when the pressing plate 711 moves downwards, the pressing plate 711 can flatten tiles, third springs 713 are symmetrically connected between the outer sides of the tops of the hinge plates 710 on the front side and the inner sides of the shell 2 in a left-right mode, the third springs 713 are sleeved on the vertical rods 712, and the tops of the hinge plates 710 and the bottom ends of the second piston rods 79 are installed in a welding connection mode.

When the shell 2 moves rightwards, the shell 2 also drives the guide rod 61 to move rightwards, the guide rod 61 moves rightwards to drive the connecting block 63 to move rightwards, the connecting block 63 moves rightwards to drive the long rod 65 to move rightwards, the long rod 65 moves rightwards to drive the contact roller 66 to move rightwards to contact with a ceramic tile, and then when the contact roller 66 moves rightwards to contact with the ceramic tile, the phenomenon of tilting of the ceramic tile is shown, the contact roller 66 moves rightwards to press down the ceramic tile, due to the action of the second spring 62, the contact roller 66 can be in closer contact with the ceramic tile, meanwhile, the contact roller 66 moves rightwards to rotate forwards through the ceramic tile, the contact roller 66 rotates forwards to drive the long rod 65 to rotate forwards, the scroll spring 67 is compressed, after the ceramic tile is flattened, the contact roller 66 moves rightwards to move away from the ceramic tile, due to the action of the scroll spring 67, the long rod 65 rotates backwards to drive the contact roller 66 to rotate backwards to reset, and the process is repeated, when the contact roller 66 contacts with the ceramic tile, the tilting of the tile is indicated, and the tilted tile is pressed flat by the contact wheel 66. When the shell 2 stops moving rightwards, the shell 2 stops driving the guide rod 61 to move rightwards, the guide rod 61 stops driving the connecting block 63 to move rightwards, the connecting block 63 stops driving the mounting disc 64 to move rightwards, and the mounting disc 64 stops driving the contact wheel 66 to move rightwards through the long rod 65. Therefore, the tilting ceramic tile can be prevented from being broken due to the fact that the tilting ceramic tile is knocked by the round balls 31.

When the shell 2 moves rightwards, the shell 2 moves rightwards to drive the vertical rod 712 to move rightwards, the vertical rod 712 moves rightwards to drive the hinged plate 710 to move rightwards, the hinged plate 710 moves rightwards to drive the pressure plate 711 to move rightwards, and further, when the contact wheel 66 moves rightwards to contact with the tilted ceramic tiles, the contact wheel 66 rotates forwards through the ceramic tiles, the contact wheel 66 rotates forwards to drive the long rod 65 to rotate forwards, the long rod 65 also drives the reel 71 to rotate forwards, the reel 71 rotates forwards to roll up the pull wire 72, the pull wire 72 rolls up to drive the connecting plate 73 to move downwards, the connecting plate 73 moves downwards to drive the first piston rod 74 to move downwards, the first piston rod 74 moves downwards to push air in the first piston cylinder 75 into the air guide disc 76, the air in the air guide disc 76 is discharged into the second piston cylinder 78, the air drives the second piston rod 79 to move downwards as the air is discharged into the second piston cylinder 78, the second piston rod 79 moves downwards to drive the hinged plate 710 to move downwards, the third spring 713 is stretched, the hinge plate 710 moves downwards to drive the pressing plate 711 to move downwards, the pressing plate 711 moves downwards to be in contact with the tilted ceramic tiles, the tilted ceramic tiles are initially flattened by the pressing plate 711, and then the ceramic tiles are completely flattened by the contact wheel 66. When the tiles are pressed flat, the contact wheel 66 is separated from the tiles, the long rod 65 rotates reversely to drive the contact wheel 66 to rotate reversely and reset under the action of the volute spring 67, the long rod 65 rotates reversely to drive the reel 71 to rotate reversely and reset, the reel 71 rotates reversely to release the pull wire 72, the hinged plate 710 moves upwards to reset under the action of the third spring 713, the hinged plate 710 drives the second piston rod 79 to move upwards to reset, the second piston rod 79 moves upwards to reset, air in the second piston cylinder 78 is discharged into the first piston cylinder 75 through the air guide plate 76, the air in the first piston cylinder 75 pushes the first piston rod 74 to move upwards, the first piston rod 74 moves upwards to drive the connecting plate 73 to move upwards to reset, and the connecting plate 73 moves upwards to reset to drive the pull wire 72 to move upwards to reset. Therefore, the tilted ceramic tiles can be better flattened.

Example 3

On the basis of the embodiment 1 and the embodiment 2, the tile pressing device further comprises a buffer mechanism 8, the buffer mechanism 8 comprises a buffer block 81, a mounting ring 82, guide posts 83 and a fourth spring 84, please refer to fig. 2, 3, 13 and 14, the mounting ring 82 is mounted on the front side and the rear side of the swing rod 3 in a welding connection manner, six guide posts 83 are slidably connected to the mounting ring 82 along the circumferential direction at uniform intervals, the buffer blocks 81 are mounted between the outer ends of the front six guide posts 83 and the outer ends of the rear six guide posts 83 in a welding connection manner, when the buffer blocks 81 are in contact with the tiles, the buffer blocks 81 can flatten the tiles, the inner side surface of the buffer block 81 is in contact with the round balls 31, the rear side surface of the front buffer block 81 is in uniform interval connection with the front side surface of the front mounting ring 82, the front side surface of the rear buffer block 81 is in uniform interval connection with the rear side surface of the rear mounting ring 82, the six fourth springs 84 are connected between the front side surface of the rear buffer block 81 and the rear mounting ring 82, the fourth spring 84 is fitted over the guide post 83.

The ceramic tile cleaning machine is characterized by further comprising a cleaning mechanism 9, wherein the cleaning mechanism 9 comprises a belt component 91, a rotating shaft 92 and a brush wheel 93, please refer to fig. 2 and fig. 15, the rotating shaft 92 is rotatably connected between the left sides of the lower portions of the front side and the rear side of the shell 2 in a penetrating mode, the brush wheel 93 is installed on the front side of the rotating shaft 92 in a circumferential direction in a welding connection mode, when the brush wheel 93 rotates forwards, concrete on a ceramic tile can be removed through the brush wheel 93, the belt component 91 is connected between the front side of the rotating shaft 92 and the front side of the left connecting rod 21, the belt component 91 consists of two belt pulleys and a flat belt, one belt pulley is fixedly sleeved on the front side of the left connecting rod 21, the other belt pulley is fixedly sleeved on the front side of the rotating shaft 92, and the flat belt is wound between the two belt pulleys.

When the swing rod 3 rotates forward and backward alternately, the swing rod 3 drives the mounting ring 82 to swing up and down, the mounting ring 82 swings up and down to drive the guide post 83 to swing up and down, the guide post 83 swings up and down to drive the buffer block 81 to swing up and down, when the buffer block 81 swings up and down to contact with a tile, the ball 31 tamps the tile through the buffer block 81 to reinforce, and the buffer block 81 can be in closer contact with the tile due to the action of the fourth spring 84. When the swing rod 3 stops rotating forward and backward alternately, the swing rod 3 stops driving the mounting ring 82 to swing up and down, and the mounting ring 82 stops driving the buffer block 81 to swing up and down through the guide post 83. Therefore, the round ball 31 can better tamp the ceramic tile for reinforcement.

When the connecting rod 21 rotates forwards, the connecting rod 21 drives the belt assembly 91 to rotate forwards, the belt assembly 91 rotates forwards to drive the rotating shaft 92 to rotate forwards, the rotating shaft 92 rotates forwards to drive the brush wheel 93 to rotate forwards, and the brush wheel 93 rotates forwards to remove impurities on the ceramic tile. When the connecting rod 21 stops rotating forwards, the connecting rod 21 stops driving the belt assembly 91 to rotate forwards, the belt assembly 91 stops driving the rotating shaft 92 to rotate forwards, and the rotating shaft 92 stops driving the brush wheel 93 to rotate forwards. Therefore, the influence of a large amount of impurities left on the ceramic tile on the environment can be avoided.

Finally, it is necessary to state that: the above-mentioned contents are only used to help understanding the technical solution of the present invention, and should not be interpreted as limiting the scope of the present invention; insubstantial modifications and adaptations of the invention as described above will occur to those skilled in the art and are intended to be within the scope of the invention as claimed.

Claims

1. The utility model provides a building ceramic tile lays reinforcing apparatus, including gyro wheel (1), casing (2), connecting rod (21), swinging arms (3) and ball (31), the cross-under of bilateral symmetry rotary type has connecting rod (21) between casing (2) front and back both sides lower part, both ends all rigid coupling has gyro wheel (1) around connecting rod (21), placing of swinging arms (3) inward sliding formula is used for striking the reality with the ceramic tile and carries out three ball (31) of consolidating, a serial communication port, still including actuating mechanism (4) and swing mechanism (5), swing mechanism (5) are installed to casing (2) inboard, swing mechanism (5) are connected with swinging arms (3), install actuating mechanism (4) that are used for driving swing mechanism (5) function between left side connecting rod (21) and casing (2), actuating mechanism (4) are connected with swing mechanism (5).

2. The building tile laying and reinforcing device according to claim 1, wherein the driving mechanism (4) comprises a fixing ring (41), a motor (42), a driving shaft (43), a transmission component (44), a short shaft (45), a first driving bevel gear (46), a first bevel gear (47), a fixing block (48), a second driving bevel gear (49), a rotating shaft (410), a second bevel gear (411), a third bevel gear (412), a fixing plate (413) and a guide rod (414), the rear side of the left connecting rod (21) is fixedly connected with the first bevel gear (47) along the circumferential direction, the left side of the lower part of the inner rear side surface of the shell (2) is fixedly connected with the fixing plate (413), the short shaft (45) is rotatably connected with the front part of the fixing plate (413) in a penetrating manner, the first driving bevel gear (46) for driving the first bevel gear (47) to rotate is fixedly sleeved on the left end of the short shaft (45), the fixing block (48) is fixedly connected with the left side of the upper part of the inner rear side surface of the shell (2), a rotating shaft (410) is rotatably connected in the front of the fixing block (48) in a penetrating manner, a second bevel gear (411) is fixedly sleeved on the upper portion of the rotating shaft (410) in a rotating manner, a guide rod (414) is fixedly connected to the front side of the bottom of the fixing block (48), the front end of the guide rod (414) and the bottom end of the rotating shaft (410) are fixedly sleeved with third bevel gears (412), the two third bevel gears (412) are meshed with each other, the rear end of the guide rod (414) is connected with a swinging mechanism (5), a fixing ring (41) is fixedly connected to the left side of the upper portion of the rear side face in the shell (2), the fixing ring (41) is positioned on the left side of the fixing block (48), a motor (42) is circumferentially installed on the inner side of the fixing ring (41), a driving shaft (43) is fixedly connected to the end of an output shaft of the motor (42), a second driving bevel gear (49) for driving the second bevel gear (411) to rotate reversely is fixedly sleeved on the right end of the driving shaft (43), and the second driving bevel gear (49) is meshed with the second bevel gear (411), a transmission assembly (44) is connected between the left side of the driving shaft (43) and the right side of the short shaft (45), the transmission assembly (44) is composed of two belt pulleys and a flat belt, one belt pulley is fixedly sleeved on the left side of the driving shaft (43), the other belt pulley is fixedly sleeved on the right side of the short shaft (45), and the flat belt is wound between the two belt pulleys.

3. The building tile laying and reinforcing device according to claim 2, wherein the swing mechanism (5) comprises a driving rod (51), a mounting frame (52), a connecting frame (53), a tooth-missing bevel gear (54), a fourth bevel gear (55), a rotating rod (56), a fixing frame (57), a friction ball (58), a first spring (59), a linkage component (510) and a torsion spring (511), the mounting frame (52) is fixedly connected between the upper parts of the front side surface and the rear side surface in the shell (2), the fixing frame (57) for driving the swing rod (3) to rotate forward and backward alternately is rotatably connected in the middle of the mounting frame (52) in a penetrating way, the right side of the fixing frame (57) is fixedly connected with the swing rod (3), the torsion spring (511) is wound between the outer right side of the fixing frame (57) and the middle of the right side surface of the mounting frame (52), the rotating rod (56) is rotatably placed in the fixing frame (57), three friction balls (58) are connected with the right side of a rotating rod (56) in an embedded sliding mode at uniform intervals along the circumferential direction, the friction balls (58) are in contact with the inner side of a fixing frame (57), a first spring (59) is connected between the inner side of each friction ball (58) and the inner side of the rotating rod (56), fourth bevel gears (55) are fixedly sleeved on the left and right sides of the rotating rod (56), a connecting frame (53) is fixedly connected with the rear portion of the left side face of the mounting frame (52), a driving rod (51) is rotatably connected with the left portion of the connecting frame (53) in a penetrating mode, a linkage assembly (510) is connected between the rear end of the driving rod (51) and the rear end of a guide rod (414), the linkage assembly (510) is composed of two belt pulleys and a flat belt, one belt pulley is fixedly sleeved at the rear end of the driving rod (51), the other belt pulley is fixedly sleeved at the rear end of the guide rod (414), the flat belt is wound between the two belt pulleys, a tooth-lacking bevel gear (54) for driving the fourth bevel gear (55) to rotate is fixedly connected at the front end of the driving rod (51), the toothless bevel gear (54) is meshed with a left fourth bevel gear (55).

4. The building tile laying and reinforcing device according to claim 3, further comprising a flattening mechanism (6) for flattening raised tiles, wherein the flattening mechanism (6) comprises guide rods (61), a second spring (62), a connecting block (63), a mounting plate (64), a long rod (65), a contact wheel (66), a volute spring (67) and a limiting plate (68), two guide rods (61) are fixedly connected to the right sides of the lower parts of the front and rear sides in the shell (2) in an embedded manner, the connecting block (63) is sleeved between the two guide rods (61) at the front side and between the two guide rods (61) at the rear side in a sliding manner, the mounting plate (64) is fixedly connected to the middle part of the connecting block (63) in a penetrating manner, the long rod (65) is rotatably connected between the right sides of the lower parts of the front and rear sides of the shell (2) in a penetrating manner, and the long rod (65) penetrates through the mounting plates (64) at the front and rear sides, the fixed cover of even interval is equipped with six contact wheels (66) that are used for flattening the ceramic tile of perk on stock (65), bilateral symmetry is connected with second spring (62) between connecting block (63) top outside and casing (2) inboard, second spring (62) cover is on guide bar (61), casing (2) outer leading flank lower part right side rigid coupling has limiting plate (68), limiting plate (68) are located stock (65) top, be connected with volute spiral spring (67) between limiting plate (68) bottom and stock (65) front side.

5. The building tile laying and reinforcing device according to claim 4, further comprising a flattening auxiliary mechanism (7) for flattening tiles, wherein the flattening auxiliary mechanism (7) comprises a reel (71), a pull wire (72), a connecting plate (73), a first piston rod (74), a first piston cylinder (75), an air guide disc (76), a second piston cylinder (78), a second piston rod (79), a hinged plate (710), a pressure plate (711), a vertical rod (712) and a third spring (713), the air guide disc (76) is arranged in the middle of the right sides of the front side surface and the rear side surface in the shell (2), one end of the air guide disc (76) is fixedly connected with the first piston cylinder (75), the other end of the air guide disc (76) is fixedly connected with the second piston cylinder (78), the first piston rod (74) is arranged in the first piston cylinder (75) in a sliding manner, the connecting plate (73) is fixedly connected to the top of the first piston rod (74), reel (71) are fixedly sleeved on the front side and the rear side of a long rod (65), a pull wire (72) used for driving a connecting plate (73) to move downwards is wound on the reel (71), the tail end of the pull wire (72) is fixedly connected with the left side of the bottom of the connecting plate (73), a second piston rod (79) is placed in a second piston cylinder (78) in an inward sliding mode, two vertical rods (712) are fixedly connected with the lower right sides of the front side and the rear side in a shell (2) in an embedded mode, a hinge plate (710) is sleeved between the two vertical rods (712) on the front side and between the two vertical rods (712) on the rear side in a sliding mode, pressing plates (711) used for flattening tiles are fixedly connected to the inner sides of the bottoms of the hinge plates (710) on the front side and the rear side, third springs (713) are symmetrically connected between the outer sides of the tops of the front side and the inner sides of the hinge plate (2), the third springs (713) are sleeved on the vertical rods (712), and the tops of the hinges (710) are fixedly connected with the bottoms of the second piston rods (79).

6. The building tile laying and reinforcing device according to claim 5, further comprising a buffering mechanism (8) for buffering, wherein the buffering mechanism (8) comprises buffering blocks (81), mounting rings (82), guide posts (83) and fourth springs (84), the mounting rings (82) are fixedly connected to the front side and the rear side of the outer portion of the swing rod (3), six guide posts (83) are slidably penetrated on the mounting rings (82) at even intervals along the circumferential direction, the buffering blocks (81) for flattening the tiles are fixedly connected between the outer ends of the six guide posts (83) on the front side and between the outer ends of the six guide posts (83) on the rear side, the inner side of each buffering block (81) is in contact with the round balls (31), the six fourth springs (84) are uniformly connected between the rear side of the buffering block (81) and the front side of the mounting ring (82) at even intervals, and the six fourth springs are connected between the front side of the buffering block (81) and the mounting ring (82) on the rear side (84) And the fourth spring (84) is sleeved on the guide post (83).

7. The building tile laying and reinforcing device according to claim 6, further comprising a cleaning mechanism (9) for removing impurities, wherein the cleaning mechanism (9) comprises a belt component (91), a rotating shaft (92) and a brush wheel (93), the rotating shaft (92) is rotatably connected between the left sides of the lower portions of the front side and the rear side of the shell (2) in a penetrating manner, the brush wheel (93) for removing concrete on the tile is fixedly connected to the front side of the rotating shaft (92) along the circumferential direction, the belt component (91) is connected between the front side of the rotating shaft (92) and the front side of the left connecting rod (21), the belt component (91) comprises two belt pulleys and a flat belt, one belt pulley is fixedly sleeved on the front side of the left connecting rod (21), the other belt pulley is fixedly sleeved on the front side of the rotating shaft (92), and the flat belt is wound between the two belt pulleys.

8. A building tile laying and reinforcing device according to claim 7, wherein said ball (31) is made of rubber.