CN110424695B

CN110424695B - Efficient automatic floor tile paving equipment

Info

Publication number: CN110424695B
Application number: CN201910758538.1A
Authority: CN
Inventors: 叶周航
Original assignee: Zhuji Zhengdao Technology Co Ltd
Current assignee: Zhuji Zhengdao Technology Co ltd
Priority date: 2019-08-16
Filing date: 2019-08-16
Publication date: 2020-06-30
Anticipated expiration: 2039-08-16
Also published as: CN110424695A; SG10201911264RA

Abstract

The invention discloses efficient automatic floor tile paving equipment which comprises a machine body, wherein a first crank cavity is formed in the machine body, a crank mechanism is arranged in the first crank cavity, a second sliding cavity is formed in the bottom of the second crank cavity, a first pushing mechanism is arranged in the second sliding cavity, a belt cavity is formed in the rear wall of the second sliding cavity, a first conveying belt mechanism is arranged in the belt cavity, a third sliding cavity is formed in the right side of the second sliding cavity, a second pushing mechanism is arranged in the third sliding cavity, a first fixing rod and a compacting mechanism are arranged on the bottom wall of the machine body, the equipment pushes floor tiles to be paved through the first pushing mechanism and the second pushing mechanism, the paved floor tiles are compacted through the compacting mechanism, and the rotation of wheels is controlled through the crank mechanism.

Description

Efficient automatic floor tile paving equipment

Technical Field

The invention relates to the technical field of floor tile laying, in particular to high-efficiency automatic floor tile laying equipment.

Background

Along with the development of economy, the continuous construction in city, people's aesthetic level improves day by day, more and more road surfaces begin to lay the ceramic tile, at present most adopt the mode of traditional artifical laying to lay the ceramic tile, produce a large amount of manpower extravagantly, increase the cost, the laying of ceramic tile needs the long-time operation of bowing or crouching down of operator, produce tired sense extremely easily, influence work efficiency, be not suitable for large-scale ceramic tile laying work, and operator's demands such as feed, rest can reduce operating duration, increase the time limit for a project that the ceramic tile was laid, therefore, it is necessary to design an efficient equipment that can lay the ceramic tile automatically.

Disclosure of Invention

The object of the present invention is to provide an efficient automatic floor tile installation for overcoming the above mentioned drawbacks of the prior art.

According to the embodiment of the invention, the efficient automatic floor tile paving equipment comprises a machine body, wherein a first crank cavity is formed in the position, close to the top, of the machine body, a second crank cavity is formed in the left side of the first crank cavity, crank mechanisms are arranged in the first crank cavity and the second crank cavity, a first sliding cavity is formed in the bottom of the second crank cavity, a slider mechanism is arranged in the first sliding cavity, a glue cavity is formed in the right side of the first sliding cavity, a second sliding cavity is formed in the bottom of the first crank cavity, a first pushing mechanism is arranged in the second sliding cavity, a belt cavity is formed in the rear wall of the second sliding cavity, a first conveying belt mechanism is arranged in the belt cavity, a third sliding cavity is formed in the right side of the second sliding cavity, a second pushing mechanism is arranged in the third sliding cavity, a third crank cavity is formed in the right side of the third sliding cavity, and a power mechanism is arranged in the third crank cavity, a second belt cavity is formed in the top of the third crank cavity, a second belt mechanism is arranged in the second belt cavity, a first fixing rod and a compaction mechanism are arranged on the bottom wall of the machine body, two groups of bottom cavities are formed in the bottom of the machine body, a fourth sliding cavity is formed in the rear wall of the bottom cavity, a jacking mechanism is arranged in the fourth sliding cavity, wheels are arranged on the left outer wall and the right outer wall of the machine body, the rotation of the wheels is controlled by the crank mechanism to enable the machine body to move, the first pushing mechanism and the sliding block mechanism are controlled by the crank mechanism to work, the first pushing mechanism pushes floor tiles downwards, the sliding block mechanism sends glue to the first fixing rod, the second pushing mechanism and the second belt mechanism are controlled by the power mechanism to work, the second pushing mechanism pushes the floor tiles leftwards, and the second belt mechanism drives the first belt mechanism to work, and conveying the floor tiles to the left, and controlling the jacking mechanism to enable the compaction mechanism to descend to be attached to the ground so as to compact the laid floor tiles.

Further technical description, it is two sets of the bottom chamber is seted up in the bottom position department of fuselage, the second dead lever has all set firmly in the bottom intracavity, and is two sets of it has first connecting rod, two sets of all to articulate in the periphery of second dead lever is equipped with the gyro wheel between the first connecting rod to rotate, it has first motor to slide the back wall embedded of chamber to have a fixed, the screw rod that extends around first motor power is connected with, it is equipped with first slide bar to slide in the fourth sliding chamber, the screw rod with first slide bar threaded connection, first slide bar front side extension part extends the bottom intracavity and its end with first connecting rod butt.

In a further technical specification, a first crank shaft extending leftwards and rightwards is rotatably arranged between the first crank cavity and the second crank cavity, a second motor is fixedly embedded in the left wall of the first crank cavity and is in power connection with the first crank shaft, the first crank shaft is provided with a first shaft sleeve in a rotating way on the periphery of the bent part in the second crank cavity, a first push rod is fixedly arranged at the tail end of the bottom of the first shaft sleeve, a first slide block is arranged in the first slide cavity in a sliding manner, the extension part at the lower side of the first push rod extends into the first sliding cavity, the tail end of the first push rod is fixedly connected with the first sliding block, a glue cavity is arranged on the right side of the first sliding cavity, the back wall of the glue cavity is in an open design, a small cavity is communicated and arranged between the glue cavity and the first sliding cavity, a first check valve is fixedly arranged in the small cavity, and a first long cavity is formed in the bottom of the first sliding cavity.

According to the technical specification, a first fixing rod is fixedly arranged on the bottom wall of the machine body, a second long cavity is formed in the first fixing rod and communicated with the first long cavity, an opening is formed in the upper wall of the second long cavity, and a second one-way valve is fixedly arranged in the first long cavity.

According to a further technical specification, a second crank shaft extending up and down is rotatably arranged in the third crank cavity, a third motor is fixedly embedded in the upper wall of the third crank cavity, the third motor is in power connection with the second crank shaft, a second shaft sleeve is rotatably arranged on the periphery of the bent portion in the third crank cavity of the second crank shaft, a second push rod is fixedly arranged at the tail end of the left side of the second shaft sleeve, the left extending portion of the second push rod extends into the third sliding cavity, a second slide block is fixedly arranged at the tail end of the second push rod, the second slide block is slidably arranged in the third sliding cavity, a floor tile cavity is communicated between the third sliding cavity and the second sliding cavity, and the rear wall of the floor tile cavity is in an open design.

According to the technical specification, a second belt cavity is formed in the top of the third crank cavity, the upward extending portion of the second crank shaft extends into the second belt cavity, a first belt wheel is fixedly arranged on the periphery of the second belt cavity, a first transmission shaft extending up and down is arranged in the second belt cavity in a rotating mode, the first transmission shaft is fixedly provided with the first belt wheel on the periphery of the portion, in the second belt cavity, the two groups of first belt wheels are connected through a first transmission belt, the bottom of the floor tile cavity is communicated with the belt cavity, a second connecting rod is rotatably arranged in the belt cavity, a second belt wheel is fixedly arranged on the periphery of the second connecting rod, the downward extending portion of the first transmission shaft extends into the belt cavity, a second belt wheel is fixedly arranged on the periphery of the first transmission shaft, and the two groups of second belt wheels are connected through a second transmission belt.

Further technical description, the belt chamber top intercommunication has been seted up the smooth chamber of second, the smooth intracavity of second slides and is equipped with the third slider, first crank axle is in it is equipped with the third axle sleeve to rotate on the periphery of the curved part in the first crank intracavity, third axle sleeve bottom end has set firmly the third push rod, the third push rod downwardly extending stretches into the smooth intracavity of second and its end with third slider fixed connection.

The technical specification further includes that the first crank shaft extends out of the machine body from left to right, wheels are fixedly arranged at the tail ends of the first crank shaft, third connecting rods are rotatably arranged at the left side and the right side of the machine body, and the two groups of wheels are fixedly arranged at the tail ends of the two groups of third connecting rods.

The invention has the beneficial effects that: this equipment is through controlling power unit, make the work of second pushing mechanism, push the ceramic tile to the second conveyer belt, and arrange the ceramic tile neatly, through control crank mechanism, make the work of first pushing mechanism, the ceramic tile propelling movement who will arrange is subaerial, then construct the ceramic tile of compaction laying through the compactor, polylith ceramic tile can be laid simultaneously to this equipment, greatly increased lays the speed of ceramic tile, and avoided artifical laying to receive the influence of power and cause the problem that laying speed reduces, this equipment can work for a long time, the efficiency is improved, the cost of labor has been practiced thrift, the labour has been liberated, more be applicable to the work of laying on a large scale.

Drawings

FIG. 1 is a schematic view of the internal structure of a high-efficiency automatic floor tile installation of the present invention;

FIG. 2 is an enlarged partial schematic view of A of FIG. 1 in accordance with the present invention;

FIG. 3 is an enlarged partial schematic view of B of FIG. 1 in accordance with the present invention;

FIG. 4 is an enlarged partial schematic view of C of FIG. 1 in accordance with the present invention;

FIG. 5 is a left side view of the transfer jack of the present invention;

fig. 6 is a partial left side view of the bottom position of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 6, the efficient automatic floor tile paving apparatus according to the embodiment of the present invention includes a machine body 10, a first crank chamber 50 is formed at a position of the machine body 10 near a top portion, a second crank chamber 13 is formed at a left side of the first crank chamber 50, crank mechanisms 62 are disposed in the first crank chamber 50 and the second crank chamber 13, a first sliding chamber 20 is formed at a bottom of the second crank chamber 13, a slider mechanism 63 is disposed in the first sliding chamber 20, a glue chamber 17 is formed at a right side of the first sliding chamber 20, a second sliding chamber 30 is formed at a bottom of the first crank chamber 50, a first pushing mechanism 65 is disposed in the second sliding chamber 30, a belt chamber 26 is formed at a rear wall of the second sliding chamber 30, a first belt conveying mechanism 64 is disposed in the belt chamber 26, a third sliding chamber 35 is formed at a right side of the second sliding chamber 30, and a second pushing mechanism 66 is disposed in the third sliding chamber 35, a third crank cavity 38 is formed in the right side of the third sliding cavity 35, a power mechanism 67 is arranged in the third crank cavity 38, a second belt cavity 45 is formed in the top of the third crank cavity 38, a second belt mechanism 68 is arranged in the second belt cavity 45, a first fixing rod 24 and a compacting mechanism 61 are arranged on the bottom wall of the machine body 10, two groups of bottom cavities 52 are formed in the bottom of the machine body 10, a fourth sliding cavity 55 is formed in the rear wall of the bottom cavity 52, a jacking mechanism 60 is arranged in the fourth sliding cavity 55, wheels 46 are arranged on the left outer wall and the right outer wall of the machine body 10, the wheels 46 are controlled to rotate by the crank mechanism 62 to enable the machine body 10 to move, the first pushing mechanism 65 and the sliding block mechanism 63 are controlled by the crank mechanism 62 to work, so that the first pushing mechanism 65 pushes floor tiles downwards, and the sliding block mechanism 63 sends glue to the first fixing rod 24, the power mechanism 67 controls the second pushing mechanism 66 and the second conveyor belt mechanism 68 to work, so that the second pushing mechanism 66 pushes the floor tiles to the left, the second conveyor belt mechanism 68 drives the first conveyor belt mechanism 64 to work, the floor tiles are conveyed to the left, and the jacking mechanism 60 is controlled to lower the compacting mechanism 61 to be close to the ground so as to compact the laid floor tiles.

Advantageously, two sets of the bottom cavities 52 are opened at the bottom position of the body 10, second fixing rods 51 are fixedly arranged in the bottom cavities 52, first connecting rods 11 are hinged on the peripheries of the two sets of the second fixing rods 51, rollers 12 are rotatably arranged between the two sets of the first connecting rods 11, a first motor 56 is fixedly embedded in the rear wall of the fourth sliding chamber 55, the first motor 56 is in power connection with a screw rod 54 extending forwards and backwards, a first sliding rod 53 is arranged in the fourth sliding cavity 55 in a sliding manner, the screw 54 is in threaded connection with the first sliding rod 53, the first slide bar 53 has a front extension extending into the bottom chamber 52 and a distal end abutting the first link 11, by the operation of the first motor 56, the screw 54 is rotated to lower the first sliding rod 53, and the first connecting rod 11 is rotated to lower the roller 12 to compact the tile.

Beneficially, a first crank shaft 14 extending left and right is rotatably disposed between the first crank chamber 50 and the second crank chamber 13, a second motor 49 is fixedly embedded in a left wall of the first crank chamber 50, the second motor 49 is in power connection with the first crank shaft 14, a first sleeve 15 is rotatably disposed on an outer periphery of a curved portion in the second crank chamber 13 of the first crank shaft 14, a first push rod 16 is fixedly disposed at a bottom end of the first sleeve 15, a first slider 21 is slidably disposed in the first sliding chamber 20, a lower side extending portion of the first push rod 16 extends into the first sliding chamber 20, and a tail end of the first push rod is fixedly connected with the first slider 21, a glue chamber 17 is disposed at a right side of the first sliding chamber 20, a rear wall of the glue chamber 17 is designed to be an opening, a small chamber 19 is disposed between the glue chamber 17 and the first sliding chamber 20 in a communicating manner, and a first one-way valve 18 is fixedly disposed in the small chamber 19, the bottom of the first sliding cavity 20 is provided with a first long cavity 23, the glue in the glue cavity 17 flows into the first sliding cavity 20 through the small cavity 19, and the first crank shaft 14 rotates through the operation of the second motor 49, so that the first shaft sleeve 15 rotates, the first push rod 16 drives the first slide block 21 to slide downwards, and the glue enters the first long cavity 23.

Advantageously, a first fixing rod 24 is fixedly arranged on the bottom wall of the machine body 10, a second long cavity 25 is formed in the first fixing rod 24, the second long cavity 25 is communicated with the first long cavity 23, an opening is formed in the upper wall of the second long cavity 25, a second one-way valve 22 is fixedly arranged in the first long cavity 23, glue enters the second long cavity 25 from the first long cavity 23, and the glue drops on the ground to be paved from the opening of the second long cavity 25.

Beneficially, a second crank shaft 39 extending up and down is rotatably disposed in the third crank chamber 38, a third motor 40 is fixedly embedded in an upper wall of the third crank chamber 38, the third motor 40 is in power connection with the second crank shaft 39, the second crank shaft 39 is rotatably disposed on an outer periphery of a curved portion in the third crank chamber 38 and is provided with a second sleeve 37, a second push rod 36 is fixedly disposed at a left end of the second sleeve 37, a left extending portion of the second push rod 36 extends into the third sliding chamber 35 and a second slider 34 is fixedly disposed at a tail end of the second push rod 36, the second slider 34 is slidably disposed in the third sliding chamber 35, a floor tile chamber 47 is disposed between the third sliding chamber 35 and the second sliding chamber 30, a rear wall of the floor tile chamber 47 is designed to be open, and the second crank shaft 39 is rotated by operation of the third motor 40 to rotate the second sleeve 37, the second push rod 36 drives the second slide block 34 to slide leftwards, so as to transport the floor tiles from the floor tile cavity 47 to the first conveyor belt mechanism 64.

Beneficially, a second belt cavity 45 is opened at the top of the third crank cavity 38, an upward extending portion of the second crank shaft 39 extends into the second belt cavity 45 and a first belt pulley 43 is fixedly arranged on the outer periphery thereof, a first transmission shaft 33 extending up and down is rotatably arranged in the second belt cavity 45, the first transmission shaft 33 is fixedly arranged on the outer periphery of a portion in the second belt cavity 45, two sets of the first belt pulleys 43 are connected through a first transmission belt 44, a belt cavity 26 is opened at the bottom of the floor tile cavity 47 in a communicating manner, a second connecting rod 27 is rotatably arranged in the belt cavity 26, a second belt pulley 28 is fixedly arranged on the outer periphery of the second connecting rod 27, a downward extending portion of the first transmission shaft 33 extends into the belt cavity 26 and a second belt pulley 28 is fixedly arranged on the outer periphery thereof, and the two sets of the second belt pulleys 28 are connected through a second transmission belt 29, by operating the third motor 40, the second crank shaft 39 is rotated to rotate the first pulley 43, the first transmission belt 44 drives the first transmission shaft 33 to rotate, the second pulley 28 is rotated to rotate the second transmission belt 29, and the floor tiles are conveyed from right to left.

Beneficially, a second sliding cavity 30 is formed in the top of the belt cavity 26 in a communicating manner, a third sliding block 32 is slidably disposed in the second sliding cavity 30, a third shaft sleeve 48 is rotatably disposed on the periphery of the curved portion of the first crank shaft 14 in the first crank shaft cavity 50, a third push rod 31 is fixedly disposed at the bottom end of the third shaft sleeve 48, the third push rod 31 extends downward into the second sliding cavity 30, and the end of the third push rod 31 is fixedly connected with the third sliding block 32, and when the second motor 49 works, the first crank shaft 14 rotates, the third shaft sleeve 48 rotates, the third push rod 31 drives the third sliding block 32 to slide downward, and the floor tiles are pushed downward for paving.

Advantageously, the first crank shaft 14 extends out of the main body 10 from left to right, and the tail ends of the first crank shaft and the first crank shaft are fixedly provided with wheels 46, the left and right sides of the main body 10 are rotatably provided with third connecting rods 42, two sets of the wheels 46 are fixedly provided at the tail ends of the two sets of the third connecting rods 42, and the second motor 49 is operated to rotate the first crank shaft 14, rotate the wheels 46, and move the main body 10.

When the device is used, the device is placed on the ground where the floor tiles need to be laid, the first sliding rod 53 is lowered by the operation of the first motor 56, the first connecting rod 11 is rotated, the roller 12 is lowered to be attached to the ground, the first crank shaft 14 drives the wheel 46 to rotate by the operation of the second motor 49, the device is advanced, glue is poured into the glue cavity 17, the slider mechanism 63 is driven to operate by the first crank shaft 14, the glue is transported to the first fixing rod 24, the glue is dropped on the ground from the opening of the second long cavity 25, the stacked floor tiles are put into the floor tile cavity 47, the second crank shaft 39 drives the second sleeve 37 to rotate by the operation of the third motor 40, the second sliding block 34 is driven by the second push rod 36 to slide leftwards, the floor tiles in the floor tile cavity 47 are pushed to the second conveyor belt 29, the second crank shaft 39 drives the second conveyor belt mechanism 68 to operate, and the first conveyor mechanism 64 operates, the floor tiles on the second conveyor belt 29 are transported from right to left and aligned in a line, the third shaft sleeve 48 is driven to rotate by the first crank shaft 14, the third push rod 31 drives the third slide block 32 to slide downwards, and the floor tiles aligned on the second conveyor belt 29 are pushed downwards, so that the floor tiles are laid.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. An efficient automatic floor tile equipment, includes the fuselage, its characterized in that: a first crank cavity is formed in the position, close to the top, of the machine body, a second crank cavity is formed in the left side of the first crank cavity, crank mechanisms are arranged in the first crank cavity and the second crank cavity, a first sliding cavity is formed in the bottom of the second crank cavity, a slider mechanism is arranged in the first sliding cavity, a glue cavity is formed in the right side of the first sliding cavity, a second sliding cavity is formed in the bottom of the first crank cavity, a first pushing mechanism is arranged in the second sliding cavity, a belt cavity is formed in the rear wall of the second sliding cavity, a first conveyor belt mechanism is arranged in the belt cavity, a third sliding cavity is formed in the right side of the second sliding cavity, a second pushing mechanism is arranged in the third sliding cavity, a third crank cavity is formed in the right side of the third sliding cavity, a power mechanism is arranged in the third crank cavity, a second belt cavity is formed in the top of the third crank cavity, and a second conveyor belt mechanism is arranged in the second belt cavity, the bottom wall of the machine body is provided with a first fixed rod and a compaction mechanism, the bottom of the machine body is provided with two groups of bottom cavities, the rear wall of the bottom cavity is internally provided with a fourth sliding cavity, the fourth sliding cavity is internally provided with a jacking mechanism, the left and right outer walls of the machine body are respectively provided with a wheel, the rotation of the wheel is controlled by the crank mechanism to enable the machine body to move, the first pushing mechanism and the slide block mechanism are controlled by the crank mechanism to work, the first pushing mechanism pushes floor tiles downwards, the slide block mechanism sends glue to the first fixed rod, the second pushing mechanism and the second conveying belt mechanism are controlled by the power mechanism to work, the second pushing mechanism pushes the floor tiles leftwards, the second conveying belt mechanism drives the first conveying belt mechanism to work, the floor tiles are conveyed leftwards, and the jacking mechanism is controlled, and lowering the compaction mechanism to be close to the ground, and compacting the paved floor tiles.

2. A high efficiency automated tile paving apparatus as recited in claim 1, wherein: two sets of the bottom chamber is seted up in the bottom position department of fuselage, the bottom intracavity has all set firmly the second dead lever, and is two sets of it has first connecting rod, two sets of all to articulate in the periphery of second dead lever rotate between the first connecting rod and be equipped with the gyro wheel, the back wall in the fourth sliding chamber is embedded to have first motor, the screw rod that extends around first motor power is connected with, it is equipped with first slide bar to slide in the fourth sliding chamber, the screw rod with first slide bar threaded connection, first slide bar front side extension part extends bottom intracavity and its end with first connecting rod butt.

3. A high efficiency automated tile paving apparatus as recited in claim 1, wherein: a first crank shaft extending left and right is rotatably arranged between the first crank cavity and the second crank cavity, a second motor is fixedly embedded in the left wall of the first crank cavity and is in power connection with the first crank shaft, the first crank shaft is provided with a first shaft sleeve in a rotating way on the periphery of the bent part in the second crank cavity, a first push rod is fixedly arranged at the tail end of the bottom of the first shaft sleeve, a first slide block is arranged in the first slide cavity in a sliding manner, the extension part at the lower side of the first push rod extends into the first sliding cavity, the tail end of the first push rod is fixedly connected with the first sliding block, a glue cavity is arranged on the right side of the first sliding cavity, the back wall of the glue cavity is in an open design, a small cavity is communicated and arranged between the glue cavity and the first sliding cavity, a first check valve is fixedly arranged in the small cavity, and a first long cavity is formed in the bottom of the first sliding cavity.

4. A high efficiency automatic floor tile installation according to claim 3, wherein: the long chamber of second has set firmly first dead lever on the diapire of fuselage, set up the long chamber of second in the first dead lever, the long chamber of second with first long chamber intercommunication, the upper wall in the long chamber of second is equipped with the opening, first long intracavity has set firmly the second check valve.

5. A high efficiency automated tile paving apparatus as recited in claim 1, wherein: the novel crank shaft is characterized in that a second crank shaft extending up and down is rotatably arranged in the third crank cavity, a third motor is fixedly embedded in the upper wall of the third crank cavity, the third motor is in power connection with the second crank shaft, a second shaft sleeve is rotatably arranged on the periphery of the bent part in the third crank cavity of the second crank shaft, a second push rod is fixedly arranged at the tail end of the left side of the second shaft sleeve, the left extending part of the second push rod extends into the third sliding cavity, a second slide block is fixedly arranged at the tail end of the second push rod, the second slide block is slidably arranged in the third sliding cavity, a floor tile cavity is communicated between the third sliding cavity and the second sliding cavity, and the rear wall of the floor tile cavity is designed to be an opening.

6. A high efficiency automatic floor tile installation according to claim 5, wherein: the second crank shaft is provided with a second crank shaft, a first crank shaft and a second crank shaft, the second crank shaft extends upwards to a certain extent, the second crank shaft extends into the second crank shaft, a first belt wheel is fixedly arranged in the second crank shaft and on the periphery of the second crank shaft, a first transmission shaft extending up and down is arranged in the second crank shaft, the first transmission shaft is fixedly provided with a first belt wheel on the periphery of the portion in the second crank shaft, the first belt wheel is connected with the first crank shaft through a first transmission belt, the bottom of the floor tile cavity is communicated with the belt cavity, a second connecting rod is rotatably arranged in the belt cavity, a second crank shaft is fixedly provided with a second belt wheel on the periphery of the second crank shaft, the downward extending portion of the first crank shaft extends into the belt cavity and on the periphery of the first crank shaft, and the second crank shaft is fixedly provided with a second belt wheel.

7. A high efficiency automated floor tile apparatus according to claim 6, wherein: the smooth chamber of second has been seted up to belt chamber top intercommunication, the smooth intracavity of second slides and is equipped with the third slider, first crank axle is in it is equipped with the third axle sleeve to rotate on the periphery of the curved portion in the first crank intracavity, third axle sleeve bottom end has set firmly the third push rod, third push rod downwardly extending stretches into the smooth intracavity of second and its end with third slider fixed connection.

8. A high efficiency automatic floor tile installation according to claim 7, wherein: the first crank shaft extends out of the machine body from left to right, wheels are fixedly arranged at the tail ends of the first crank shaft, third connecting rods are rotatably arranged at the positions of the left side and the right side of the machine body, and the two groups of wheels are fixedly arranged at the tail ends of the two groups of third connecting rods.