CN111497038A - Indoor arc corner is measured and ceramic tile real-time cutting equipment - Google Patents

Abstract

The invention discloses an indoor arc-shaped corner measuring and real-time ceramic tile cutting device, which comprises a shell, wherein the left upper end in the shell is provided with a corner radius measuring mechanism for measuring the radius of an arc-shaped corner, the right lower end in the shell is provided with a cutting cavity with a forward opening, a real-time ceramic tile cutting mechanism for changing the cutting radius of a ceramic tile in real time is arranged in the cutting cavity, and the front side in the real-time cutting cavity is also provided with a cutting knife lifting mechanism for clamping a cutting knife, and relatively saves the raw materials of the ceramic tiles.

Description

Indoor arc corner is measured and ceramic tile real-time cutting equipment

Technical Field

The invention relates to the field of building measurement, in particular to indoor arc-shaped wall corner measurement and real-time ceramic tile cutting equipment.

Background

In-process to carrying out the fitment indoor, often can paste the ceramic tile to indoor ground, but the corner of some buildings has certain radian, when carrying out the ceramic tile to the corner that has the radian, then needs the manual work to measure the corner to cut out the ceramic tile of same radian radius through the measuring result.

At the present stage, when tiling is carried out to the corner that has the radian, generally measure and artifical cutting to the ceramic tile through the manual work, not only inefficiency can have great error in the in-process of measuring and ceramic tile cutting moreover.

Disclosure of Invention

The invention aims to solve the technical problems of low efficiency, large error and the like when the indoor arc-shaped wall corner measuring and real-time ceramic tile cutting equipment is provided, and the problems of low efficiency, large error and the like when the wall corner with the radian is pasted with the ceramic tiles are solved, so that the efficiency of pasting the ceramic tiles on the wall corner with the radian is improved, and the accuracy of ceramic tile cutting is improved.

The invention is realized by the following technical scheme.

The invention discloses indoor arc-shaped corner measuring and real-time ceramic tile cutting equipment, which comprises a shell, wherein a corner radius measuring mechanism for measuring the radius of an arc-shaped corner is arranged at the upper left end in the shell, a cutting cavity with a forward opening is arranged at the lower right end in the shell, a real-time ceramic tile cutting mechanism for changing the cutting radius of a ceramic tile in real time is arranged in the cutting cavity, and a cutting knife lifting mechanism for clamping a cutting knife is also arranged at the front side in the real-time cutting cavity; the real-time ceramic tile cutting mechanism comprises two push plates positioned at the upper end and the left end in a cutting cavity, two telescopic springs are connected between the upper end face of the push plate at the upper end and the upper cavity wall of the cutting cavity, two telescopic springs are connected between the left end face of the push plate at the left end and the left cavity wall of the cutting cavity, a ceramic tile placing block positioned at the lower side of the push plate at the upper side and positioned at the right side of the push plate at the left side is further arranged in the cutting cavity, a ceramic tile to be cut is placed in the ceramic tile placing block, a rotating rod is arranged on the front end wall at the right end of a shell in a rotating manner, a first torsion spring is connected between the rotating rod and the end wall of the shell, a driven gear is arranged at the rear end of the rotating rod, a rotating block is arranged at the front end of the rotating rod, a sliding groove, the tool fixing block is provided with a diamond cutter penetrating through the front end face and the rear end face of the tool fixing block, and a pressure spring is connected between the rear end face of the front convex head of the diamond cutter and the front end face of the tool fixing block.

Furthermore, the cutting knife lifting mechanism comprises two identical displacement cavities which are positioned in the upper cavity wall of the cutting cavity and the left cavity wall of the cutting cavity, a displacement block capable of moving back and forth is arranged in each of the two displacement cavities, an elastic spring is connected between the rear end face of the displacement block and the rear cavity wall of the displacement cavity, the rear end face of the displacement block at the upper side is connected with one end provided with a rope, a pressing plate positioned at the front side of the cutting cavity is fixedly arranged between the right end face of the displacement block at the left side and the lower end face of the displacement block at the upper side, the rear end face of the pressing plate is abutted against the diamond knife, a sliding cavity with a backward opening is arranged in the pressing plate, a sliding block capable of rotating in the sliding cavity by taking the rotating rod as a rotating center is arranged in the sliding cavity, the sliding block can move left and right in the sliding cavity, and a through hole, the front end face of the telescopic block is fixedly provided with a telescopic rod, the front end of the telescopic rod extends into the through hole, and the left end face of the sliding block is connected with one end provided with a hemp rope.

Furthermore, the wall corner radius measuring mechanism comprises two identical moving cavities which are positioned at the left end and the upper end in the casing, a moving block capable of sliding in the moving cavities is arranged in each of the two moving cavities, a first rack is fixedly arranged on the right end face of the moving block at the upper side and the lower end face of the moving block at the left side, a connecting rod is fixedly arranged on the upper end face of the moving block at the upper side and the left end face of the moving block at the left side, a translation plate is fixedly arranged on the upper end face of the connecting rod at the upper side and the left end face of the connecting rod at the left side, a second rack is fixedly arranged on the lower end face of the right end of the first rack at the upper side, the lower end face of the left end is connected with the other end of the hemp rope, a transmission cavity is arranged in the middle in the casing, a motor is arranged in the wall of the lower, the transmission shaft upper end is equipped with the rotatory gear that the terminal surface meshing is connected before the first rack, it is equipped with that the left end is given birth to and is stretched into the left axis of rotation in the removal intracavity to rotate on the transmission chamber left side wall, the axis of rotation left end be equipped with the left the terminal surface meshing is connected before the first rack rotatory gear, the axis of rotation right-hand member is equipped with and is located the first driven bevel gear of transmission intracavity, be equipped with in the middle of the transmission shaft with the first drive bevel gear that first driven bevel gear meshing is connected, left real-time first rack upper end can move a section distance in the removal piece.

Furthermore, a clapboard is fixedly arranged on the upper cavity wall and the lower cavity wall at the right end of the transmission cavity, an intermediate shaft is rotatably arranged on the clapboard, the left end of the intermediate shaft is connected with a sliding bevel gear through a spline, the left end and the right end in the sliding bevel gear are respectively provided with a sliding cavity with an outward opening, sliding blocks capable of sliding in the sliding cavities are respectively arranged in the two sliding cavities, two reset springs are connected between the right end surface of the sliding block on the right side and the left end surface of the partition plate, the left end surface of the sliding block on the left side is connected with one end provided with a rope, a second driving bevel gear is arranged at the right end of the intermediate shaft, a driven shaft is rotatably arranged on the rear cavity wall at the right end of the transmission cavity, the rear end of the driven shaft is provided with a second driven bevel gear in meshed connection with the second driving bevel gear, and the front end of the sector gear is provided with a sector gear capable of being in meshed connection with the driven gear.

Furthermore, a first opening cavity with an upward opening is arranged in the lower cavity wall of the moving cavity at the upper side, a rotating rod is rotatably arranged on the front cavity wall and the rear cavity wall of the first opening cavity, a rotating gear meshed with the second rack is arranged at the rear end of the rotating rod, a rope winding wheel is arranged at the front end of the rotating rod, the pull rope is wound on the rope winding wheel, a second opening cavity is arranged at the lower side of the left moving cavity, a rotating rod is rotatably arranged on the front cavity wall and the rear cavity wall of the second opening cavity, a friction wheel in friction connection with the right end surface of the first rack is arranged at the rear end of the rotating rod, two winding wheels are arranged at the front end of the rotating rod, two ropes are respectively wound on the two winding wheels, a second torsion spring is arranged between the rotating rod and the rear cavity wall of the second opening cavity, the lower end of the left first rack extends into the external space, the upside the translation board up end and left the translation board left end face contradicts with a wall at corner respectively.

The invention has the beneficial effects that: the ceramic tile cutting device can replace manual work to accurately measure the fillet of the arc-shaped corner, and can synchronously feed the measuring result back to the ceramic tile cutting part while measuring the angle of the corner so as to accurately cut the ceramic tile according to the measuring result, and the cutting knife can always cut along the edge of the ceramic tile when cutting the ceramic tile so as to ensure that the ceramic tile is utilized to the maximum benefit, thereby not only improving the efficiency of cutting the ceramic tile meeting the conditions, but also relatively saving the raw material of the ceramic tile.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic diagram of the structure at A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of the structure at B in FIG. 1 according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram at C-C in fig. 2 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: 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.

The indoor arc-shaped corner measuring and real-time ceramic tile cutting equipment disclosed by the accompanying drawings 1-4 comprises a casing 10, wherein a corner radius measuring mechanism 39 for measuring the radius of an arc-shaped corner is arranged at the upper left end in the casing 10, a cutting cavity 17 with a forward opening is arranged at the lower right end in the casing 10, a real-time ceramic tile cutting mechanism 52 for changing the cutting radius of a ceramic tile in real time is arranged in the cutting cavity 17, a cutting knife lifting mechanism 16 for clamping the cutting knife is further arranged at the front side in the real-time cutting cavity 17, the real-time ceramic tile cutting mechanism 52 comprises two push plates 71 which are arranged at the upper end and the left end in the cutting cavity 17, two telescopic springs 72 are connected between the upper end surface of the push plate 71 at the upper end and the upper wall of the cutting cavity 17, two telescopic springs 72 are connected between the left end surface of the push plate 71 at the left end and the left, still be equipped with one in the cutting chamber 17 and be located the upside push pedal 71 downside and be located the left the ceramic tile on push pedal 71 right side is laid the piece 70, the ceramic tile is laid and is placed the ceramic tile that waits to cut in the piece 70, it is equipped with dwang 63 to rotate on the front end wall of casing 10 right-hand member, dwang 63 with it is equipped with first torsion spring 51 to connect between the casing 10 end wall, dwang 63 rear end is equipped with driven gear 64, dwang 63 front end is equipped with turning block 75, the right-hand member is equipped with opening spout 54 to the right in the turning block 75, be equipped with in the spout 54 can be in the spout 54 the flexible piece 55 of side-to-side motion, be equipped with compression spring 53 between flexible piece 55 left end face and the spout 54 left chamber wall, flexible piece 55 right end face is fixed and is equipped with cutter fixed block 56, be equipped with on the cutter fixed block 56 and, a pressure spring 57 is connected between the rear end surface of the front end raised head of the diamond cutter 58 and the front end surface of the cutter fixing block 56.

Advantageously, the cutting knife lifting mechanism 16 comprises two identical displacement cavities 20 located in the upper cavity wall of the cutting cavity 17 and the left cavity wall of the cutting cavity 17, a displacement block 19 capable of moving back and forth is arranged in each of the two displacement cavities 20, an elastic spring 76 is connected between the rear end surface of the displacement block 19 and the rear cavity wall of the displacement cavity 20, the rear end surface of the displacement block 19 on the upper side is connected with one end provided with a rope 23, a pressing plate 18 located on the front side of the cutting cavity 17 is fixedly arranged between the right end surface of the displacement block 19 on the left side and the lower end surface of the displacement block 19 on the upper side, the rear end surface of the pressing plate 18 is abutted against the diamond knife 58, a sliding cavity 62 with a backward opening is arranged in the pressing plate 18, a sliding block 61 capable of rotating in the sliding cavity 62 by using a rotating rod 63 as a rotating center is arranged in the sliding cavity 62, and the sliding block 61 is capable of moving left and right, a through hole 60 penetrating through the front and the back is formed in the sliding block 61, a telescopic rod 59 with the front end extending into the through hole 60 is fixedly arranged on the front end face of the telescopic block 55, and one end of the hemp rope 42 is connected to the left end face of the sliding block 61.

Beneficially, the corner radius measuring mechanism 39 includes two identical moving cavities 38 located at the left end and the upper end in the housing 10, a moving block 34 capable of sliding in the moving cavities 38 is disposed in each of the two moving cavities 38, a first rack 31 is fixedly disposed on each of the right end surface of the moving block 34 at the upper side and the lower end surface of the moving block 34 at the left side, a connecting rod 35 is fixedly disposed on each of the upper end surface of the moving block 34 at the upper side and the left end surface of the moving block 34 at the left side, a translation plate 36 is fixedly disposed on each of the upper end surface of the connecting rod 35 at the upper side and the left end surface of the connecting rod 35 at the left side, a second rack 45 is fixedly disposed on the lower end surface of the right end of the first rack 31 at the upper side, the other end surface of the hemp rope 42 is connected to the lower end surface of the left end, a transmission cavity 40, the upper end of the motor 22 is connected with a transmission shaft 21 with the upper end extending into the upper side in the movable cavity 38 in a power mode, the upper end of the transmission shaft 21 is provided with a rotating gear 33 in meshed connection with the front end face of the first rack 31, the left cavity wall of the transmission cavity 40 is rotatably provided with a rotating shaft 32 with the left end extending into the left movable cavity 38, the left end of the rotating shaft 32 is provided with the rotating gear 33 in meshed connection with the front end face of the first rack 31 on the left side, the right end of the rotating shaft 32 is provided with a first driven bevel gear 30 located in the transmission cavity 40, the middle of the transmission shaft 21 is provided with a first driving bevel gear 41 in meshed connection with the first driven bevel gear 30, and the upper end of the first real-time rack 31 on the left side can move for.

Advantageously, a partition plate 43 is fixedly arranged on the upper cavity wall and the lower cavity wall at the right end of the transmission cavity 40, an intermediate shaft 80 is rotatably arranged on the partition plate 43, the left end of the intermediate shaft 80 is connected with a sliding bevel gear 66 through a spline, sliding cavities 67 with outward openings are respectively arranged at the left end and the right end in the sliding bevel gear 66, sliding blocks 69 capable of sliding in the sliding cavities 67 are respectively arranged in the two sliding cavities 67, two return springs 68 are connected between the right end surface of the sliding block 69 at the right side and the left end surface of the partition plate 43, the left end surface of the sliding block 69 at the left side is connected with one end provided with a rope 23, the right end of the intermediate shaft 80 is provided with a second driving bevel gear 48, the rear cavity wall at the right end of the transmission cavity 40 is rotatably provided with a driven shaft 50, a second driven bevel gear 49 engaged with the second driving bevel gear 48 is arranged at the rear end of the driven shaft 50, the front end of the sector gear 47 is provided with a sector gear 47 which can be meshed with the driven gear 64.

Beneficially, a first open cavity 12 with an upward opening is arranged in the lower cavity wall of the upper moving cavity 38, a rotating rod 44 is rotatably arranged on the front and rear cavity walls of the first open cavity 12, a rotating gear 11 engaged with the second rack 45 is arranged at the rear end of the rotating rod 44, a rope winding wheel 46 is arranged at the front end of the rotating rod 44, the pull rope 74 is wound on the rope winding wheel 46, a second open cavity 24 is arranged at the lower side of the left moving cavity 38, a rotating rod 29 is rotatably arranged on the front and rear cavity walls of the second open cavity 24, a friction wheel 25 frictionally connected with the right end face of the first rack 31 is arranged at the rear end of the rotating rod 29, two reels 28 are arranged at the front end of the rotating rod 29, two ropes 23 are respectively wound on the two reels 28, a second torsion spring 26 is arranged between the rotating rod 29 and the rear cavity wall of the second open cavity 24, and the lower end of the left first rack 31 extends into the external space, the lower end of the first rack 31 is provided with scales 27, the upper end face of the translation plate 36 on the upper side and the left end face of the translation plate 36 on the left side are respectively abutted against a wall surface of a wall corner 37.

In the initial state, the sliding bevel gear 66 is located at the right side of the first drive bevel gear 41 by the two return springs 68 and is in a non-meshing state with the first drive bevel gear 41.

When the machine shell 10 works, the upper end surface of the upper side translation plate 36 and the left end surface of the left side translation plate 36 are respectively abutted against a wall surface of a wall corner 37 by adjusting the position of the machine shell 10, the machine shell 10 is relatively fixed with the indoor ground, the motor 22 is started, the motor 22 works to drive the transmission shaft 21 and the first driving bevel gear 41 and the rotating gear 33 on the transmission shaft 21 to rotate, the first driving bevel gear 41 drives the first driven bevel gear 30 in meshed connection with the first driving bevel gear to rotate, so as to drive the rotating shaft 32 and the rotating gear 33 on the rotating shaft 32 to rotate, the two rotating gears 33 rotate to respectively drive the two first racks 31 in meshed connection with the first driving bevel gears to move, so as to drive the two moving blocks 34 and the connecting rod 35 to move, and finally drive the two translation plates 36 to approach to the wall corner along the wall surface to move towards the wall corner, when the two translation plates 36 move to the position where the wall, the two rotating gears 33 respectively slip on the rotating shaft 32 and the transmission shaft 21 to stop rotating at the moment, then the positions of the two translation plates 36 are just at two ends of the arc-shaped wall corner, the radius of the arc-shaped wall corner can be read by observing the readings on the scale 27, the hemp rope 42 is tensioned while the first rack 31 on the upper side moves, so that the slider 61 is pulled by the hemp rope 42 to move leftwards, the slider 61 moves leftwards to drive the telescopic rod 59 and the telescopic block 55 to move leftwards, so that the radius of the ceramic tile cut by the diamond cutter 58 is correspondingly adjusted, the radius of the ceramic tile cut by the diamond cutter 58 is kept consistent with the radius of the arc-shaped wall corner, so as to cut the ceramic tile with the corresponding radius, the first rack 31 on the upper side also drives the second rack 45 to move leftwards, so as to drive the rotating gear 11 meshed and connected with the rotating gear to rotate, so as to drive the rotating rod 44 and the, the rope winding wheel 46 rotates to tighten the pull rope 74, the tile placing block 70 and the tile on the tile placing block 70 move under the action of the pull force of the pull rope 74, the transmission ratio when the second rack 45 is meshed with the rotating gear 11 just pulls the tile placing block 70 to move through the pull rope 74, and the right edge of the tile in the tile placing block 70 is kept to be overlapped with the rear end of the diamond cutter 58, so that the accuracy of cutting the tile is guaranteed; the first left rack 31 moves upwards and simultaneously drives the friction wheel 25 which is in friction connection with the right end face of the first rack 31 to rotate, the friction wheel 25 rotates to drive the rotating rod 29 and the two reels 28 on the rotating rod 29 to rotate, the two reels 28 rotate to respectively release the two ropes 23, the sliding bevel gear 66 loses the tension of the ropes 23 and is in a non-meshed state with the first driving bevel gear 41 under the action of the return spring 68, the sliding bevel gear 66 is ensured not to start to cut the ceramic tile before the wall corner radius is not measured, the other rope 23 releases to stop the pulling action on the displacement block 19, the displacement block 19 moves forwards under the action of the elastic spring 76, the diamond cutter 58 is ensured not to be in contact with the surface of the ceramic tile before the wall corner radius is not measured so as to facilitate the movement of the ceramic tile, and the moving block 34 on the left side cannot continue to move after the wall corner radius is measured, the first rack 31 on the left side can also extend into the moving block 34 for a short distance under the rotation action of the rotating gear 33, at the moment, the first rack 31 can move to be separated from frictional contact with the friction wheel 25, the rotating rod 29, the friction wheel 25 on the rotating rod 29 and the two reels 28 are reversely reset under the action of the second torsion spring 26, the two ropes 23 are tensioned again, the sliding bevel gear 66 moves leftwards under the tension action of the ropes 23 and is meshed and connected with the first driving bevel gear 41, the displacement block 19 moves backwards under the tension action of the ropes 23, finally the pressing plate 18 is driven to extrude the diamond cutter 58 backwards, and the rear end of the diamond cutter 58 is abutted against the surface of the tile to prepare for cutting the tile; during cutting, the first driving bevel gear 41 rotates to drive the sliding bevel gear 66 in meshed connection with the first driving bevel gear to rotate, so as to drive the intermediate shaft 80 and the second driving bevel gear 48 at the right end of the intermediate shaft 80 to rotate, the second driving bevel gear 48 rotates to drive the second driven bevel gear 49 in meshed connection with the second driving bevel gear to rotate, so as to drive the driven shaft 50 and the sector gear 47 at the front end of the driven shaft 50 to rotate, when the sector gear 47 rotates to the part in meshed connection with the driven gear 64, the driven gear 64 is driven to rotate, the driven gear 64 rotates to drive the rotating rod 63 and the rotating block 75 on the rotating rod 63 to rotate, the rotating block 75 rotates to drive the cutter fixing block 56 and the diamond cutter 58 on the cutter fixing block 56 to rotate, so as to cut a ceramic tile through the diamond cutter 58, when the sector gear 47 rotates to be in meshed connection with, the rotating rod 63 and the rotating block 75 are reversely rotated and reset under the action of the first torsion spring 51, and the cutting is completed.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides an indoor arc corner is measured and real-time cutting equipment of ceramic tile, includes the casing, its characterized in that: the device comprises a shell, a cutting cavity, a real-time ceramic tile cutting mechanism, a cutter lifting mechanism and a cutter clamping mechanism, wherein the upper left end in the shell is provided with a corner radius measuring mechanism for measuring the radius of an arc-shaped corner, the lower right end in the shell is provided with a cutting cavity with a forward opening, the cutting cavity is internally provided with the real-time ceramic tile cutting mechanism for changing the cutting radius of a ceramic tile in real time, and the front side in the real-time cutting cavity is also provided; the real-time ceramic tile cutting mechanism comprises two push plates positioned at the upper end and the left end in a cutting cavity, two telescopic springs are connected between the upper end face of the push plate at the upper end and the upper cavity wall of the cutting cavity, two telescopic springs are connected between the left end face of the push plate at the left end and the left cavity wall of the cutting cavity, a ceramic tile placing block positioned at the lower side of the push plate at the upper side and positioned at the right side of the push plate at the left side is further arranged in the cutting cavity, a ceramic tile to be cut is placed in the ceramic tile placing block, a rotating rod is arranged on the front end wall at the right end of a shell in a rotating manner, a first torsion spring is connected between the rotating rod and the end wall of the shell, a driven gear is arranged at the rear end of the rotating rod, a rotating block is arranged at the front end of the rotating rod, a sliding groove, the tool fixing block is provided with a diamond cutter penetrating through the front end face and the rear end face of the tool fixing block, and a pressure spring is connected between the rear end face of the front convex head of the diamond cutter and the front end face of the tool fixing block.

2. The indoor arc-shaped corner measuring and real-time ceramic tile cutting equipment as claimed in claim 1, wherein: the cutting knife lifting mechanism comprises two identical displacement cavities positioned in the upper cavity wall of the cutting cavity and the left cavity wall of the cutting cavity, wherein two displacement cavities are internally provided with a displacement block capable of moving back and forth, an elastic spring is connected between the rear end surface of the displacement block and the rear cavity wall of the displacement cavity, the rear end surface of the displacement block at the upper side is connected with one end provided with a rope, a pressing plate positioned at the front side of the cutting cavity is fixedly arranged between the right end surface of the displacement block at the left side and the lower end surface of the displacement block at the upper side, the rear end surface of the pressing plate is abutted against the diamond knife, a sliding cavity with a backward opening is arranged in the pressing plate, a sliding block capable of rotating in the sliding cavity by taking a rotating rod as a rotating center is arranged in the sliding cavity, the sliding block can move left and right in the sliding cavity, a through hole penetrating through the front and back is arranged in the sliding block, and a telescopic rod with a front, the left end face of the sliding block is connected with one end provided with a hemp rope.

3. The indoor arc-shaped corner measuring and real-time ceramic tile cutting equipment as claimed in claim 1, wherein: the wall corner radius measuring mechanism comprises two identical moving cavities which are positioned at the left end and the upper end in the shell, a moving block capable of sliding in the moving cavities is arranged in each of the two moving cavities, a first rack is fixedly arranged on the right end face of the moving block at the upper side and the lower end face of the moving block at the left side, a connecting rod is fixedly arranged on each of the upper end face of the moving block at the upper side and the left end face of the moving block at the left side, a translation plate is fixedly arranged on each of the upper end face of the connecting rod at the upper side and the left end face of the connecting rod at the left side, a second rack is fixedly arranged on the lower end face of the right end of the first rack at the upper side, the lower end face of the left end of the first rack at the upper side is connected with the other end of the hemp rope, a transmission cavity is arranged in the middle, the transmission shaft upper end is equipped with the rotatory gear that the terminal surface meshing is connected before the first rack, it is equipped with that the left end is given birth to and is stretched into the left axis of rotation in the removal intracavity to rotate on the transmission chamber left side wall, the axis of rotation left end be equipped with the left the terminal surface meshing is connected before the first rack rotatory gear, the axis of rotation right-hand member is equipped with and is located the first driven bevel gear of transmission intracavity, be equipped with in the middle of the transmission shaft with the first drive bevel gear that first driven bevel gear meshing is connected, left real-time first rack upper end can move a section distance in the removal piece.

4. The indoor arc-shaped corner measuring and real-time ceramic tile cutting equipment as claimed in claim 3, wherein: the rope-driven gear transmission device is characterized in that partition plates are fixedly arranged on the upper cavity wall and the lower cavity wall of the right end of the transmission cavity, intermediate shafts are arranged on the partition plates in a rotating mode, sliding bevel gears are connected through splines at the left ends of the intermediate shafts, sliding cavities with outward openings are arranged at the left ends and the right ends of the sliding bevel gears, sliding blocks capable of sliding in the sliding cavities are arranged in the sliding cavities, two reset springs are arranged on the right end faces of the sliding blocks on the right side and the left end faces of the partition plates in a connecting mode, one ends provided with ropes are connected to the left end faces of the sliding blocks, second driving bevel gears are arranged at the right ends of the intermediate shafts, driven shafts are arranged on the rear cavity wall of the right end of the transmission cavity in a rotating mode, second driven bevel gears connected with the second driving bevel.

5. The indoor arc-shaped corner measuring and real-time ceramic tile cutting equipment as claimed in claim 3, wherein: a first opening cavity with an upward opening is formed in the lower cavity wall of the moving cavity at the upper side, a rotating rod is arranged on the front cavity wall and the rear cavity wall of the first opening cavity in a rotating mode, a rotating gear connected with the second rack in a meshed mode is arranged at the rear end of the rotating rod, a rope winding wheel is arranged at the front end of the rotating rod, the pull rope is wound on the rope winding wheel, a second opening cavity is formed in the lower side of the left moving cavity, a rotating rod is arranged on the front cavity wall and the rear cavity wall of the second opening cavity in a rotating mode, a friction wheel in friction connection with the right end face of the first rack is arranged at the rear end of the rotating rod, two winding wheels are arranged at the front end of the rotating rod, two ropes are wound on the two winding wheels respectively, a second torsion spring is arranged between the rotating rod and the rear cavity wall of the second opening cavity, the lower, the upside the translation board up end and left the translation board left end face contradicts with a wall at corner respectively.

Images