CN111042490A

CN111042490A - Small-size ceramic tile sizing machine

Info

Publication number: CN111042490A
Application number: CN201911313277.9A
Authority: CN
Inventors: 刘彩文
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-12-19
Filing date: 2019-12-19
Publication date: 2020-04-21
Anticipated expiration: 2039-12-19
Also published as: CN111042490B

Abstract

The invention relates to a ceramic tile sizing machine, in particular to a small ceramic tile sizing machine. The technical problem to be solved is how to provide a small-size ceramic tile sizing machine which can accurately control the thickness of the coating mortar and has high coating speed. The small-sized ceramic tile sizing machine comprises a base, a frame body, a discharging hopper, an inclined plate and the like; the framework is installed at the base top, and the hopper is installed down to the left side in the framework, and framework right side sub-unit connection has the swash plate. The distance between the sleeve and the ceramic tile can be adjusted through the thickness adjusting device, so that the thickness of the mortar to be coated can be accurately controlled, the conveying device can be used for coating the mortar on the ceramic tile, manual operation can be replaced, and the mortar can be quickly coated; the mortar on the ceramic tile can be stirred through the leveling device to level the mortar on the ceramic tile; mortar on the ceramic tile can be extruded through the flattening device, so that the mortar on the ceramic tile can be more smooth.

Description

Small-size ceramic tile sizing machine

Technical Field

The invention relates to a ceramic tile sizing machine, in particular to a small ceramic tile sizing machine.

Background

The ceramic tile is a ceramic product formed by taking refractory metal oxide and semimetal oxide as raw materials and processing the raw materials in a series, is generally applied to the building industry and used for beautifying buildings, and mortar needs to be coated on the ceramic tile when the ceramic tile is stuck on a floor or a wall surface.

At present, generally, workers shovel mortar to a ceramic tile by using a plastering trowel and then paint the mortar uniformly, so that the thickness of the mortar is difficult to see by naked eyes, the thickness of the mortar is difficult to control, and the painting speed is slow.

Aiming at the problems existing at present, the device capable of accurately controlling the thickness of the plastering mortar and high in plastering speed is designed.

Disclosure of Invention

In order to overcome the defects that the thickness of the mortar is difficult to see by naked eyes, the thickness of the mortar is difficult to control, and the coating speed is slow, the technical problems to be solved are as follows: the small-sized tile sizing machine can accurately control the thickness of the mortar to be coated and has high coating speed.

The technical scheme is as follows: a small-sized tile sizing machine comprises a base, a frame body, a blanking hopper, an inclined plate, a first photoelectric sensor, a conveying device, a thickness adjusting device, a lifting device, a sleeve, a sliding pipe, a second photoelectric sensor, a third photoelectric sensor and a steel wire rope, wherein the frame body is arranged at the top of the base, the blanking hopper is arranged at the left side in the frame body, the inclined plate is connected with the lower part of the right side of the frame body, an opening is formed in the right side of the frame body, the first photoelectric sensor is arranged at the top in the opening, the steel wire rope is uniformly connected to the inner side of the opening at intervals, the lifting device is arranged at the right part in the frame body, the sliding pipe is arranged on the lifting device, the sleeve is sleeved on the sliding pipe, the lifting device is used for driving the sleeve to move up and down, the thickness adjusting device is arranged on the sleeve, the sleeve pipe top is equipped with second photoelectric sensor, and third photoelectric sensor installs in the sleeve pipe bottom.

In one embodiment, the system further comprises a control module, an LCD display screen, a setting key, an adding key, a subtracting key and a confirmation key, wherein the LCD display screen, the setting key, the adding key, the subtracting key and the confirmation key are electrically connected with the control module.

In one embodiment, the conveying device comprises a discharging pipe, a spiral conveying rod, a driving motor, a corrugated pipe and a buffer box, wherein the discharging pipe is connected to the left side of the bottom in the frame body and penetrates through the bottom of the frame body, a feeding hole is formed in the upper portion of the right side of the discharging pipe, the spiral conveying rod is rotatably installed in the discharging pipe and penetrates through the bottom of the frame body, the driving motor is installed on the upper portion of the base, the spiral conveying rod is connected with an output shaft of the driving motor, the corrugated pipe is connected to the lower portion of the right side of the discharging pipe, the buffer.

In one embodiment, the thickness adjusting device comprises an electric push rod and a distance sensor, the electric push rod is installed at the top of the sleeve and connected with the sliding pipe, and the distance sensor is installed at the top of the electric push rod.

In one embodiment, the lifting device comprises a square guide rod, a square hole guide sleeve, a servo motor, a reel and a pull rope, the square guide rod is installed on the right portion in the frame body, the square hole guide sleeve is sleeved on the square guide rod, the sliding pipe is connected to the lower portion of the front side of the square hole guide sleeve, the servo motor is installed on the upper portion of the front side of the square hole guide sleeve, the reel is installed on an output shaft of the servo motor, the pull rope is wound on the reel, and the pull rope is connected with the top portion in.

In one embodiment, the frame comprises a frame body, and is characterized by further comprising a floating device, wherein the floating device comprises a hinged rod, a first spring, a scraper, a toothed plate, a side plate and a guide plate, the hinged rod is hinged to the front side and the rear side of the sleeve, the first spring is connected between the hinged rod and the sleeve, the scraper is connected to the right ends of the two hinged rods, the toothed plate is connected to the bottom of the scraper, the side plate is fixedly connected to the top of the scraper, the two guide plates are respectively arranged on the front side and the rear side of.

In one embodiment, the device further comprises a flattening device, the flattening device comprises an inclined rod, a roller, a scraper and a second spring, the inclined rod is connected to the right side of the bottom of the sleeve, the inclined rod is located on the right side of the third photoelectric sensor, the roller is rotatably mounted at the right end of the inclined rod, the scraper is connected to the bottom of the inclined rod, the scraper is in contact with the roller, and the second spring is connected between the scraper and the inclined rod.

In one embodiment, the anti-solidification device further comprises a cross rod, stirring blades and a rotating rod, the cross rod is connected to the upper portion in the blanking hopper, the rotating rod is connected to the cross rod in a rotating mode and connected with the spiral conveying rod, and the stirring blades are mounted on the rotating rod.

In one embodiment, the device further comprises a control box, the top of the frame body is connected with the control box, the LCD display screen, the setting key, the plus key, the minus key and the confirmation key are all arranged on the top of the control box, the control box comprises a switching power supply and a power supply module, the switching power supply can supply power to the device, the output end of the switching power supply is electrically connected with the power supply module, the control module is electrically connected with the power supply module, and the power supply module is connected with a power supply main switch through a circuit; the control module is connected with a 24C02 circuit and a DS1302 clock circuit, the 24C02 circuit is used for storing parameters, the set parameters are stored in the 24C02 circuit, relevant parameters are called out during work, the DS1302 clock circuit provides a time reference, timing can be carried out, and the leap year compensation function is achieved; the first photoelectric sensor, the second photoelectric sensor, the third photoelectric sensor and the distance sensor are electrically connected with the control module; the driving motor, the electric push rod and the servo motor are all connected with the control module through a peripheral circuit.

Compared with the prior art, the invention has the following advantages: the distance between the sleeve and the ceramic tile can be adjusted through the thickness adjusting device, so that the thickness of the mortar to be coated can be accurately controlled, the conveying device can be used for coating the mortar on the ceramic tile, manual operation can be replaced, and the mortar can be quickly coated; the mortar on the ceramic tile can be stirred through the leveling device to level the mortar on the ceramic tile; the mortar on the ceramic tile can be extruded through the flattening device, so that the mortar on the ceramic tile can be more flattened; the mortar in the blanking hopper can be stirred through the anti-solidification device, and the mortar in the blanking hopper is prevented from being solidified.

Drawings

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

Fig. 2 is an enlarged schematic view of part a of the present invention.

Fig. 3 is an enlarged schematic view of part B of the present invention.

Fig. 4 is an enlarged schematic view of the part C of the present invention.

Fig. 5 is a partial top view of the present invention.

Fig. 6 is a circuit diagram of the present invention.

Fig. 7 is a schematic circuit diagram of the present invention.

Wherein the figures include the following reference numerals: 1. the automatic feeding device comprises a base, a frame body, a discharging hopper, a 4 inclined plate, a 5 first photoelectric sensor, a 6 opening, a 61 control box, a 62 LCD display screen, a 7 conveying device, a 71 discharging pipe, a 72 feeding hole, a 73 spiral conveying rod, a 74 driving motor, a 75 corrugated pipe, a 76 buffer box, a 8 thickness adjusting device, an 81 electric push rod, a 83 distance sensor, a 9 lifting device, a 91 square guide rod, a 92 square hole guide sleeve, a 93 servo motor, a 94 winding wheel, a 95 pull rope, a 10 sleeve, a 101 sliding pipe, a 102 second photoelectric sensor, a 103 third photoelectric sensor, a 104 steel wire rope, a 11 leveling device, a 111 hinged rod, a 112 first spring, a 113 scraper, a 114 toothed plate, a 115 side plate, a 116 guide plate, a 12 leveling device, a 121 inclined rod, a 122 roller, a 123 scraper, a 124 second spring, 13. the anti-solidification device comprises a cross rod 131, a stirring blade 132, a rotating rod 133.

Detailed Description

Although the present invention may be described with respect to particular applications or industries, those skilled in the art will recognize the broader applicability of the invention. Those of ordinary skill in the art will recognize other factors such as: terms such as above, below, upward, downward, and the like are used to describe the accompanying drawings and are not meant to limit the scope of the invention, which is defined by the appended claims. Such as: any numerical designation of first or second, and the like, is merely exemplary and is not intended to limit the scope of the invention in any way.

Example 1

A small-sized tile sizing machine is shown in figures 1 and 3 and comprises a base 1, a frame body 2, a blanking hopper 3, an inclined plate 4, a first photoelectric sensor 5, a conveying device 7, a thickness adjusting device 8, a lifting device 9, a sleeve 10, a sliding pipe 101, a second photoelectric sensor 102, a third photoelectric sensor 103 and a steel wire rope 104, wherein the frame body 2 is installed at the top of the base 1, the blanking hopper 3 is installed at the left side in the frame body 2, the inclined plate 4 is connected to the lower part of the right side of the frame body 2, the frame body 2 is connected with the inclined plate 4 in a bolt connection mode, an opening 6 is formed in the right side of the frame body 2, the first photoelectric sensor 5 is installed at the top in the opening 6, the steel wire ropes 104 are evenly connected to the inner side of the opening 6 at intervals, the lifting device 9 is arranged at the right part in the frame body 2, the sliding pipe 101 is arranged on the lifting, be equipped with thickness adjusting device 8 on sleeve pipe 10, thickness adjusting device 8 is used for adjusting the thickness of paining the mortar, and the bottom left side is equipped with conveyor 7 in framework 2, and conveyor 7 is used for carrying the mortar to the slide 101 in, and the sleeve pipe 10 top is equipped with second photoelectric sensor 102, and third photoelectric sensor 103 installs in sleeve pipe 10 bottom.

As shown in fig. 1, fig. 6 and fig. 7, the system further comprises a control module, an LCD display screen 62, a set key, an add key, a subtract key and a confirm key, wherein the LCD display screen 62, the set key, the add key, the subtract key and the confirm key are electrically connected with the control module.

The staff presses the power master switch, power on this equipment, use or when needing to adjust relevant parameter for the first time, the staff sets up the operational parameter of relevant automatically controlled equipment and sensor through the set key, add the key, subtract a key and enter the interface of setting by the enter of set key, the interface is displayed on LCD display screen 62, then press and add a key and subtract a key and set up relevant parameter or trade, after setting up, the staff presses the enter key and confirms and quit and set up the interface, the parameter that has set up passes through control module and saves in the 24C02 circuit, the staff presses the power master switch again, cut off the power supply with this equipment. When mortar needs to be coated on a ceramic tile, a worker pours the mortar into the blanking hopper 3 and then presses the power supply main switch to electrify the equipment, the control module controls the first photoelectric sensor 5 to work, when the first-time use is carried out or no mortar exists in the conveying device 7, the worker presses the confirmation key for 3 seconds, the control module controls the conveying device 7 to work for 4 seconds, the conveying device 7 can convey the mortar in the blanking hopper 3 into the sliding pipe 101, the mortar flows into the sleeve 10, after 4 seconds, the control module controls the conveying device 7 to stop working, the worker can put the ceramic tile into the opening 6, the inclined plate 4 and the steel wire rope 104 can block the ceramic tile, the first photoelectric sensor 5 detects the ceramic tile, the first photoelectric sensor 5 sends out a signal, the control module receives the signal and then controls the thickness adjusting device 8 to work, the thickness adjusting device 8 can adjust the distance between the sleeve 10 and the ceramic tile, therefore, the thickness of the mortar can be accurately controlled, after the mortar is adjusted, the control module controls the thickness adjusting device 8 to stop working, the control module controls the conveying device 7 to work, the conveying device 7 can convey the mortar in the discharging hopper 3 into the sliding pipe 101, the mortar flows into the sleeve 10 and then is coated on the ceramic tile, and therefore manual operation can be replaced, the mortar can be rapidly coated, the control module controls the lifting device 9 to work, the lifting device 9 drives the sliding pipe 101 to move upwards, the sleeve 10 is driven to move upwards, the mortar can be coated on each area of the ceramic tile, the sleeve 10 can move upwards, the second photoelectric sensor 102 and the third photoelectric sensor 103 can also move upwards, the control module controls the second photoelectric sensor 102 to work, the second photoelectric sensor 102 detects the ceramic tile, when the second photoelectric sensor 102 cannot detect the ceramic tile, when the ceramic tile is completely painted, the second photoelectric sensor 102 sends a signal, the control module receives the signal and then controls the conveying device 7 to stop working, the control module controls the lifting device 9 to drive the sliding pipe 101 to move downwards, the second photoelectric sensor 102 and the third photoelectric sensor 103 move downwards, the control module controls the third photoelectric sensor 103 to work, when the third photoelectric sensor 103 detects the frame body 2, the third photoelectric sensor 103 sends a signal, the control module receives the signal and then controls the lifting device 9 to stop working, the control module controls the second photoelectric sensor 102 and the third photoelectric sensor 103 to stop working, and a worker can take out the ceramic tile painted with mortar from the opening 6 and then put another ceramic tile into the opening 6 to continue to paint mortar on the ceramic tile. When mortar is not required to be smeared, a worker presses the power supply main switch to power off the equipment.

As shown in fig. 1 and 2, the conveying device 7 includes a discharging pipe 71, a spiral conveying rod 73, a driving motor 74, a corrugated pipe 75 and a buffer tank 76, the discharging pipe 71 is connected to the left side of the bottom in the frame body 2, the frame body 2 is connected to the discharging pipe 71 through a bolt, the discharging pipe 71 passes through the bottom of the frame body 2, a feeding port 72 is opened on the upper portion of the right side of the discharging pipe 71, the spiral conveying rod 73 is rotatably installed in the discharging pipe 71, the spiral conveying rod 73 passes through the bottom of the frame body 2, the driving motor 74 is installed on the upper portion of the base 1, the spiral conveying rod 73 is connected to an output shaft of the driving motor 74, the spiral conveying rod 73 is connected to the driving motor 74 through a coupling, the corrugated pipe 75 is connected to the lower portion of.

The mortar is poured into the discharging hopper 3 by a worker, the mortar flows into the discharging pipe 71, when the mortar is used for the first time, the worker presses the confirmation key for 3 seconds, the control module controls the driving motor 74 to work for 4 seconds, the driving motor 74 drives the spiral conveying rod 73 to rotate, the spiral conveying rod 73 can convey the mortar in the discharging pipe 71 into the corrugated pipe 75, the mortar flows into the buffer box 76 and then flows into the sleeve 10 through the sliding pipe 101, after 4 seconds, the control module controls the driving motor 74 to stop working, when the control module controls the thickness adjusting device 8 to stop working, the control module controls the driving motor 74 to work at the same time, the driving motor 74 drives the spiral conveying rod 73 to rotate, and the spiral conveying rod 73 can convey the mortar in the discharging pipe 71 into the sleeve 10 and then be coated on the ceramic tile. When the second photoelectric sensor 102 does not detect the tile, which indicates that the tile is completely painted, the second photoelectric sensor 102 sends a signal, and the control module receives the signal and controls the driving motor 74 to stop working.

As shown in fig. 3, the thickness adjusting device 8 includes an electric push rod 81 and a distance sensor 83, the electric push rod 81 is installed on the top of the sleeve 10, the sleeve 10 is connected with the electric push rod 81 through a bolt connection, the electric push rod 81 is connected with the slide pipe 101, and the distance sensor 83 is installed on the top of the electric push rod 81.

When the first photoelectric sensor 5 detects a tile, the first photoelectric sensor 5 sends a signal, the control module receives the signal and then controls the distance sensor 83 to work, the distance sensor 83 can detect the distance between the tile and the distance sensor 83, if the distance value detected by the distance sensor 83 is lower than the preset value in the control module, the distance sensor 83 sends a signal, the control module receives the signal and then controls the electric push rod 81 to shorten, so that the electric push rod 81 moves leftwards, so that the sleeve 10 and the distance sensor 83 can move leftwards, the distance between the sleeve 10 and the tile is prolonged, the thickness of the coating mortar can be adjusted, when the distance value detected by the distance sensor 83 reaches the preset value in the control module, the distance sensor 83 sends a signal, the control module receives the signal and then controls the electric push rod 81 to stop shortening, if the distance value detected by the distance sensor 83 is higher than the preset value in the control module, the distance sensor 83 sends a signal, the control module receives the signal and then controls the electric push rod 81 to extend, so that the electric push rod 81 moves rightwards, the sleeve 10 and the distance sensor 83 can move rightwards, the distance between the sleeve 10 and the ceramic tile is shortened, when the distance value detected by the distance sensor 83 reaches a preset value in the control module, the distance sensor 83 sends a signal, and the control module receives the signal and then controls the electric push rod 81 to stop extending.

As shown in fig. 1 and 3, the lifting device 9 includes a square guide rod 91, a square guide sleeve 92, a servo motor 93, a reel 94 and a pull rope 95, the square guide rod 91 is installed at the right part in the frame 2, the frame 2 is connected with the square guide rod 91 through a bolt connection mode, the square guide rod 91 is sleeved with the square guide sleeve 92, a slide pipe 101 is connected to the lower part of the front side of the square guide sleeve 92, the servo motor 93 is installed on the upper part of the front side of the square guide sleeve 92, the square guide sleeve 92 is connected with the servo motor 93 through a bolt connection mode, the reel 94 is installed on an output shaft of the servo motor 93, the servo motor 93 is connected with the reel 94 through a key connection mode, the pull rope 95 is wound on the reel 94, and the pull rope 95.

When control module control driving motor 74 during operation, control module control servo motor 93 time delay 4 seconds anticlockwise rotation simultaneously, at this moment, the mortar is carried in the bellows 75, then flow into in the baffle-box 76, flow into in sleeve pipe 10 through slide pipe 101 again, scribble at last on the ceramic tile, 4 seconds later, control module control servo motor 93 anticlockwise rotation, servo motor 93 drives reel 94 anticlockwise rotation, stay cord 95 rolling is on reel 94, make reel 94 and servo motor 93 rebound, thereby drive square hole guide pin bushing 92 rebound, and then drive slide pipe 101 rebound, sleeve pipe 10 rebound thereupon, make the mortar can scribble and scribble in every region of ceramic tile. When the second photoelectric sensor 102 cannot detect a tile, the second photoelectric sensor 102 sends a signal, the control module receives the signal and then controls the servo motor 93 to rotate clockwise, the servo motor 93 drives the reel 94 to rotate clockwise to reel the reel 94, so that the reel 94 and the servo motor 93 move downwards, the sleeve 10 moves downwards along with the reel, meanwhile, the control module controls the third photoelectric sensor 103 to work, when the third photoelectric sensor 103 detects the frame body 2, the third photoelectric sensor 103 sends a signal, and the control module receives the signal and then controls the servo motor 93 to stop rotating clockwise.

Example 2

On the basis of embodiment 1, as shown in fig. 3, 4 and 5, the present embodiment further includes a floating device 11, the floating device 11 includes a hinge rod 111, a first spring 112, a scraper 113, a toothed plate 114, a side plate 115 and a guide plate 116, the hinge rod 111 is hinged to both the front and rear sides of the casing 10, the first spring 112 is connected between the hinge rod 111 and the casing 10, the scraper 113 is connected to the right end of the two hinge rods 111, the toothed plate 114 is connected to the bottom of the scraper 113, the side plate 115 is fixedly connected to the top of the scraper 113, the guide plate 116 is two, and the front and rear sides on the right side in the frame 2 are respectively disposed.

When sleeve 10 moved upwards, sleeve 10 drove hinge rod 111 rebound to drive scraper blade 113 rebound, and then drive pinion rack 114 and curb plate 115 rebound, pinion rack 114 and curb plate 115 can stir the mortar on the ceramic tile, trowel the mortar on the ceramic tile, under the effect of first spring 112, can make pinion rack 114 and curb plate 115 stir the mortar on the ceramic tile all the time.

As shown in fig. 3 and 4, the pressing device 12 is further included, the pressing device 12 includes an inclined rod 121, a roller 122, a scraper 123 and a second spring 124, the inclined rod 121 is connected to the right side of the bottom of the sleeve 10, the sleeve 10 is connected to the inclined rod 121 through a welding connection mode, the inclined rod 121 is located on the right side of the third photoelectric sensor 103, the roller 122 is rotatably installed at the right end of the inclined rod 121, the scraper 123 is connected to the bottom of the inclined rod 121, the scraper 123 is in contact with the roller 122, and the second spring 124 is connected between the scraper 123 and the inclined rod 121.

When the sleeve 10 moves upwards, the sleeve 10 drives the diagonal rod 121 to move upwards, so as to drive the roller 122 to move upwards, the roller 122 can extrude mortar on the tile, the mortar on the tile can be smoother, and the scraper 123 can scrape the mortar on the roller 122.

As shown in fig. 1, the anti-solidification device 13 is further included, the anti-solidification device 13 includes a cross bar 131, stirring blades 132 and a rotating rod 133, the cross bar 131 is connected to the upper portion in the lower hopper 3, the rotating rod 133 is rotatably connected to the cross bar 131, the rotating rod 133 is connected to the spiral conveying rod 73, and the stirring blades 132 are mounted on the rotating rod 133.

When the screw conveying rod 73 rotates, the screw conveying rod 73 drives the rotating rod 133 to rotate, so as to drive the stirring blade 132 to rotate, and the stirring blade 132 can stir the mortar in the discharging hopper 3, so that the mortar in the discharging hopper 3 is prevented from being solidified.

As shown in fig. 1, 6 and 7, the portable electronic device further comprises a control box 61, the top of the frame body 2 is connected with the control box 61, the LCD display screen 62, the setting key, the plus key, the minus key and the confirmation key are all arranged on the top of the control box 61, the control box 61 comprises a switching power supply and a power supply module, the switching power supply can supply power to the portable electronic device, the output end of the switching power supply is electrically connected with the power supply module, the control module is electrically connected with the power supply module, and the power supply module is connected with a power supply main switch through a circuit; the control module is connected with a 24C02 circuit and a DS1302 clock circuit, the 24C02 circuit is used for storing parameters, the set parameters are stored in the 24C02 circuit, relevant parameters are called out during work, the DS1302 clock circuit provides a time reference, timing can be carried out, and the leap year compensation function is achieved; the first photoelectric sensor 5, the second photoelectric sensor 102, the third photoelectric sensor 103 and the distance sensor 83 are electrically connected with the control module; the driving motor 74, the electric push rod 81 and the servo motor 93 are all connected with the control module through peripheral circuits.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a small-size ceramic tile starching machine, includes base, framework, hopper and swash plate down, and the framework is installed at the base top, and hopper under installing in the left side in the framework, framework right side sub-unit connection have the swash plate, and the framework right side is opened there is opening, characterized by: still including first photoelectric sensor, conveyor, thickness adjusting device, elevating gear, the sleeve pipe, the slide pipe, second photoelectric sensor, third photoelectric sensor and wire rope, first photoelectric sensor is installed at the top in the opening, the inboard evenly spaced of opening is connected with wire rope, the right part is equipped with elevating gear in the framework, the last slide pipe that is equipped with of elevating gear, the cover has the sleeve pipe on the slide pipe, elevating gear is used for driving the sleeve pipe and reciprocates, be equipped with thickness adjusting device on the sleeve pipe, thickness adjusting device is used for adjusting the thickness of paining the mortar, bottom left side is equipped with conveyor in the framework, conveyor is used for carrying the mortar to the slide pipe in, the sleeve pipe top is equipped with second photoelectric sensor, third photoelectric sensor installs in the sleeve pipe bottom.

2. A compact tile grouter as recited in claim 1, further comprising: the device also comprises a control module, an LCD display screen, a setting key, an adding key, a subtracting key and a confirmation key, wherein the LCD display screen, the setting key, the adding key, the subtracting key and the confirmation key are all electrically connected with the control module.

3. A compact tile grouter as recited in claim 2, further comprising: conveyor is including the discharging pipe, the auger delivery pole, driving motor, bellows and baffle box, bottom left side is connected with the discharging pipe in the framework, the discharging pipe passes the framework bottom, open on discharging pipe right side upper portion has the feed inlet, the auger delivery pole is installed to the interior rotary type of discharging pipe, the auger delivery pole passes the framework bottom, driving motor installs in base upper portion, auger delivery pole and driving motor's output shaft, discharging pipe right side sub-unit connection has the bellows, be connected with the baffle box on the bellows, baffle box and slip pipe are connected.

4. A compact tile grouter as recited in claim 3, further comprising: the thickness adjusting device comprises an electric push rod and a distance sensor, the electric push rod is installed at the top of the sleeve and connected with the sliding pipe, and the distance sensor is installed at the top of the electric push rod.

5. A compact tile grouter as recited in claim 4, further comprising: the lifting device comprises a square guide rod, a square hole guide sleeve, a servo motor, a reel and a pull rope, the square guide rod is installed on the right portion in the frame body, the square hole guide sleeve is sleeved on the square guide rod, a sliding pipe is connected to the lower portion of the front side of the square hole guide sleeve, the servo motor is installed on the upper portion of the front side of the square hole guide sleeve, the reel is installed on an output shaft of the servo motor, the pull rope is wound on the reel, and the pull rope is connected with the top in.

6. A small size tile sizing machine according to claim 5, wherein: still including floating the device, floating the device including hinge bar, first spring, scraper blade, pinion rack, curb plate and baffle, both sides are all articulated to be connected with the hinge bar around the sleeve pipe, are connected with first spring between hinge bar and the sleeve pipe, and two hinge bar right-hand members are connected with the scraper blade, and the scraper blade bottom is connected with the pinion rack, and the curb plate rigid coupling is in the scraper blade top, and the baffle is two, divides to locate both sides around on the right side in the frame.

7. A compact tile grouter as recited in claim 6, further comprising: still including flattening device, flattening device is connected with the down tube on sleeve pipe bottom right side including down tube, cylinder, scraper and second spring, and the down tube is located the third photoelectric sensor right side, and the cylinder is installed to down tube right-hand member rotary type, and the down tube bottom is connected with the scraper, and scraper and cylinder contact are connected with the second spring between scraper and the down tube.

8. A compact tile grouter as recited in claim 7, further comprising: still including preventing the solidification equipment, prevent that the solidification equipment is connected with the horizontal pole including horizontal pole, stirring vane and bull stick in the lower hopper upper portion, and the rotation type is connected with the bull stick on the horizontal pole, and the bull stick is connected with the screw conveyor pole, installs stirring vane on the bull stick.

9. A compact tile grouter as recited in claim 8, further comprising: the control box is connected to the top of the frame body, the LCD display screen, the setting key, the plus key, the minus key and the confirmation key are all arranged on the top of the control box, a switching power supply and a power supply module are arranged in the control box, the switching power supply can supply power to the equipment, the output end of the switching power supply is electrically connected with the power supply module, the control module is electrically connected with the power supply module, and the power supply module is connected with a power supply main switch through a circuit; the control module is connected with a 24C02 circuit and a DS1302 clock circuit, the 24C02 circuit is used for storing parameters, the set parameters are stored in the 24C02 circuit, relevant parameters are called out during work, the DS1302 clock circuit provides a time reference, timing can be carried out, and the leap year compensation function is achieved; the first photoelectric sensor, the second photoelectric sensor, the third photoelectric sensor and the distance sensor are electrically connected with the control module; the driving motor, the electric push rod and the servo motor are all connected with the control module through a peripheral circuit.