CN114635555A

CN114635555A - Based on construction is with quantitative feed mechanism

Info

Publication number: CN114635555A
Application number: CN202210287900.3A
Authority: CN
Inventors: 胡宏青; 辛建峰; 乔福成; 刘春燕; 翟艳军; 李龙; 曹宗胜; 王日清
Original assignee: Shanxi Sixth Construction Group Co ltd
Current assignee: Shanxi Sixth Construction Group Co ltd
Priority date: 2022-03-22
Filing date: 2022-03-22
Publication date: 2022-06-17
Anticipated expiration: 2042-03-22
Also published as: CN114635555B

Abstract

The invention relates to the field of building construction, in particular to a quantitative feeding mechanism for building construction. The technical problem is that: the existing equipment enables the end part of the ceramic tile located at the top to stretch out through pushing, so that constructors can take the ceramic tile, the ceramic tile located above the ceramic tile in the pushing process can scrape the ceramic tile below the ceramic tile, and the attractiveness of the ceramic tile is seriously affected. The technical scheme is as follows: a quantitative feeding mechanism for building construction comprises a first support frame, a lifting assembly and the like; the middle part of the right side of the first support frame is provided with a lifting component. Realized during the use that automatic will wholly fold ceramic tile transportation to eminence, automatic the ceramic tile tip that will be located the top simultaneously stretches out, and the constructor of being convenient for gets the material, accomplishes automatic unloading operation to avoided scraping colored phenomenon because of the ceramic tile that the friction leads to, automatic simultaneously fixes a position whole folding ceramic tile, is blockked when avoiding the relative splint upward movement of ceramic tile of skew, and is fixed and spacing to whole folding ceramic tile automatically when taking place the skew phenomenon simultaneously.

Description

Based on construction is with quantitative feed mechanism

Technical Field

The invention relates to the field of building construction, in particular to a quantitative feeding mechanism for building construction.

Background

The building construction refers to the production activity in the engineering construction implementation stage, is the construction process of various buildings, when pasting tiles on indoor walls, a helper is needed to hand over the tiles from the ground to a constructor standing on a high-foot stool, then the constructor pastes the tiles at the high position of the wall surface, and the risk of tile falling exists in the handing-over process, so the prior art provides a high-foot stool with a lifting mechanism, which is used for replacing the helper to transport the tiles to the high position, the prior equipment can only transport the whole stack of tiles to the high position, so that the constructor is difficult to take the relatively thin tiles piece by piece, if the end part of the topmost tile is pushed out to be convenient for the constructor to take, the tile positioned above the constructor in the pushing process can scrape flowers on the tiles below the tile, the attractiveness of the tiles is seriously affected, meanwhile, when the existing equipment has a rope breakage phenomenon, the tiles in the building can drop sharply, resulting in chipping and damage to the tile.

Therefore, a quantitative feeding mechanism for building construction needs to be designed.

Disclosure of Invention

The invention provides a quantitative feeding mechanism for building construction, aiming at overcoming the defects that the end part of the topmost ceramic tile is extended out to be convenient for a constructor to take by pushing the existing equipment, the ceramic tile positioned above the equipment can scrape the ceramic tile below the equipment in the pushing process, and the attractiveness of the ceramic tile is seriously affected.

The technical implementation scheme of the invention is as follows: a quantitative feeding mechanism for building construction comprises a first support frame, wheels, a level sensor, a speed sensor, a feeding assembly, a driving assembly, a fixing assembly, a protection assembly and a lifting assembly; four wheels are fixedly connected to the lower side of the first support frame; the middle part of the right side of the first support frame is provided with a lifting assembly for lifting; a feeding assembly for feeding the tiles one by one is arranged at the lower part of the right side of the lifting assembly; a driving component for driving is arranged at the upper part of the front side of the feeding component; the middle part of the feeding assembly is provided with a fixing assembly for positioning and fixing the ceramic tile; a protection component for preventing the ceramic tiles from sliding is arranged at the upper part of the right side of the feeding component; a horizontal sensor is fixedly connected to the lower part of the right side of the feeding assembly; and a speed sensor is fixedly connected to the lower part of the right side of the feeding assembly and is positioned below the horizontal sensor.

Preferably, the feeding assembly comprises a storage box, a sliding plate, a first connecting block, a first elastic telescopic rod, a first limiting rod, a first linkage plate, a spring, a first telescopic cylinder, a clamping plate, a second connecting block, a multi-stage hydraulic rod and a push plate; a storage box is arranged at the lower part of the right side of the ascending component; the left part and the right part of the upper side of the storage box are both connected with a sliding plate in a sliding manner; the front parts of the back sides of the two sliding plates are fixedly connected with a first connecting block; two first elastic telescopic rods are fixedly connected to the front part of the inner side of the storage box; the telescopic ends of the two first elastic telescopic rods are fixedly connected with the corresponding first connecting blocks respectively; two first limiting rods are fixedly connected to the upper sides of the two sliding plates; each two corresponding first limiting rods are connected with a first linkage plate in a sliding mode; the four first limiting rods are respectively sleeved with a spring, the upper ends of the springs are fixedly connected with the corresponding first limiting rods, and the lower ends of the springs are fixedly connected with the corresponding first linkage plates; two first telescopic cylinders are fixedly connected to the back sides of the two first linkage plates; the telescopic ends of each two corresponding first telescopic cylinders are fixedly connected with a clamping plate, and rubber pads are arranged on opposite sides of the two clamping plates; two second connecting blocks are fixedly connected to the middle of the lower side of the storage box; the lower parts of the two second connecting blocks are fixedly connected with a multi-stage hydraulic rod; the telescopic ends of the two multi-stage hydraulic rods are fixedly connected with a push plate.

Preferably, the driving assembly comprises a first pushing block, a second pushing block, a rack, a first motor and a straight gear; the upper part of the front side of the storage box is connected with two first push blocks in a sliding manner, and the rear sides of the first push blocks are inclined planes; the front parts of the lower sides of the two first push blocks are fixedly connected with a second push block; the middle parts of the upper sides of the two first push blocks are fixedly connected with a rack; two first motors are arranged at the upper part of the front side of the storage box and are positioned at the inner sides of the two first push blocks; the output shafts of the two first motors are fixedly connected with a straight gear; the two straight gears are respectively meshed with the corresponding racks.

Preferably, the fixing component comprises a second telescopic cylinder, a first linkage frame, a second elastic telescopic rod, a second limiting rod and a fixing plate; a second telescopic cylinder is fixedly connected to the middle part of the left side and the middle part of the right side of the storage box; the telescopic ends of every two corresponding second telescopic cylinders penetrate through the storage box and are fixedly connected with a first linkage frame; the outer edges of the opposite sides of the two first linkage frames are fixedly connected with four second elastic telescopic rods; the telescopic ends of every two adjacent upper and lower second elastic telescopic rods are fixedly connected with a second limiting rod; two first link gear side middle parts in opposite directions all have a fixed plate inherently, and two fixed plate sides in opposite directions all are provided with the rubber pad.

Preferably, the protection assembly comprises a second support frame, an electric sliding rail, an electric sliding block, a baffle and a bending plate; a second support frame is fixedly connected to the middle part of the right side of the storage box; an electric sliding rail is fixedly connected to the upper side of the second supporting frame; the electric sliding rail is connected with an electric sliding block in a sliding way; the upper side of the electric sliding block is fixedly connected with a baffle; the right side of the baffle is fixedly connected with a bending plate.

Preferably, the ascending assembly comprises a first connecting plate, a guide rail plate, a sliding block, a first rope, a first pulley frame, a second motor, a hollow cylinder, a second connecting plate, a third elastic telescopic rod, a limiting plate, a first linkage block, a second rope, a fourth elastic telescopic rod and a second linkage block; a first connecting plate is fixedly connected to the lower part of the right side of the first support frame; a guide rail plate is fixedly connected between the upper part of the right side of the first support frame and the middle part of the right side of the first connecting plate; the guide rail plate is connected with a sliding block in a sliding way; a first rope is fixedly connected to the left part of the upper side of the sliding block; a first pulley frame is fixedly connected to the upper part of the right side of the first support frame; a second motor is arranged on the upper side of the wheel positioned on the right front side; an output shaft of the second motor is fixedly connected with a hollow cylinder; the first rope is fixedly connected with the hollow cylinder by bypassing the upper side of the first pulley yoke; the middle part of the guide rail plate is fixedly connected with a second connecting plate; two third elastic telescopic rods are fixedly connected to the left side and the right side of the second connecting plate; each two corresponding telescopic ends of the third elastic telescopic rods are fixedly connected with a limiting plate, and the two limiting plates are arranged in a bilateral symmetry manner; the middle parts of the opposite sides of the two limiting plates are fixedly connected with a first linkage block; the two first linkage blocks are both contacted with the second connecting plate; a fourth elastic telescopic rod is fixedly connected to the middle part of the left side and the middle part of the right side of the second connecting plate; the telescopic ends of the two fourth elastic telescopic rods are fixedly connected with a second linkage block; the two second linkage blocks are respectively contacted with the corresponding first linkage blocks; the two second linkage blocks are both contacted with the second connecting plate; the front parts of the lower sides of the two second linkage blocks are fixedly connected with a second rope; the lower ends of the two second ropes penetrate through the guide rail plate and are connected with the guide rail plate in a sliding mode.

Preferably, sliding block inner wall left side and inner wall right side all are provided with a barb piece to the barb is down, and two barb pieces set up for bilateral symmetry moreover.

Preferably, the back sides of the two limiting plates are provided with upward barbs.

Preferably, the upper side of the first linkage block is an inclined plane, and the lower side of the second linkage block is an inclined plane.

Preferably, the lifting device further comprises a buffering assembly, the buffering assembly is mounted at the lower part of the right side of the lifting assembly, and the buffering assembly comprises a fifth elastic telescopic rod, a second linkage frame, a sixth elastic telescopic rod, a second linkage plate, a third telescopic cylinder, a third linkage plate, a third rope and a second pulley frame; the lower part of the front side and the lower part of the rear side of the guide rail plate are fixedly connected with a fifth elastic telescopic rod; the telescopic ends of the two fifth elastic telescopic rods are fixedly connected with a second linkage frame; two sixth elastic telescopic rods are fixedly connected to the upper sides of the two second linkage frames; the telescopic ends of every two corresponding sixth elastic telescopic rods are fixedly connected with a second linkage plate; a third telescopic cylinder is fixedly connected to the middle of the left side of the first connecting plate; the telescopic end of the third telescopic cylinder is fixedly connected with a third linkage plate; two third ropes are fixedly connected to the upper side of the third linkage plate; two second pulley frames are fixedly connected to the lower portion of the guide rail plate, and the two second pulley frames are located below the two fifth elastic telescopic rods; the third rope bypasses the upper side of the corresponding second pulley frame and is fixedly connected with the corresponding second linkage frame; and the two second ropes penetrate through the guide rail plate and are fixedly connected with the third linkage plate.

The invention has the beneficial effects that: realized during the use that automatic will wholly fold ceramic tile transportation to eminence, automatic ceramic tile tip that will be located the top stretches out simultaneously, the constructor of being convenient for gets the material, accomplish automatic unloading operation, and the ceramic tile that has avoided leading to because of the friction scrapes the flower phenomenon, automatic whole ceramic tile of folding is fixed a position simultaneously, be blockked when avoiding the relative splint upward movement of ceramic tile of skew, automatic whole ceramic tile of folding is fixed and spacing when taking place the skew phenomenon simultaneously, avoid the ceramic tile landing to ground to break into pieces, it is spacing to block the sliding block automatically when first rope emergence fracture phenomenon still to have realized, thereby slow down the receiver, simultaneously slow down the receiver through four sixth elastic telescopic rod automatically, further improve the security.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a schematic view of a portion of the structure of the present invention;

FIG. 4 is a schematic structural view of a loading assembly and a driving assembly of the present invention;

FIG. 5 is a schematic structural view of a feeding assembly and a guard assembly of the present invention;

FIG. 6 is a top view of the loading assembly and drive assembly of the present invention;

FIG. 7 is a first structural schematic of the securing assembly of the present invention;

FIG. 8 is a second construction of the fixing assembly of the present invention;

FIG. 9 is a top view of the fixing assembly of the present invention;

FIG. 10 is a front view of the riser assembly of the present invention;

FIG. 11 is an enlarged view of the invention at A;

FIG. 12 is an enlarged view of the invention at B;

FIG. 13 is a schematic view of the structure of the cushioning assembly of the present invention.

Reference numbers in the drawings: 1-a first support frame, 2-wheels, 3-a horizontal sensor, 4-a speed sensor, 201-a storage box, 202-a sliding plate, 203-a first connecting block, 204-a first elastic telescopic rod, 205-a first limiting rod, 206-a first linkage plate, 207-a spring, 208-a first telescopic cylinder, 209-a clamping plate, 2010-a second connecting block, 2011-a multi-stage hydraulic rod, 2012-a pushing plate, 301-a first pushing block, 302-a second pushing block, 303-a rack, 304-a first motor, 305-a straight gear, 401-a second telescopic cylinder, 402-a first linkage frame, 403-a second elastic telescopic rod, 404-a second limiting rod, 405-a fixing plate, 501-a second support frame and 502-an electric sliding rail, 503-electric sliding block, 504-baffle, 505-bending plate, 601-first connecting plate, 602-guide rail plate, 603-sliding block, 604-first rope, 605-first pulley frame, 606-second motor, 607-hollow cylinder, 608-second connecting plate, 609-third elastic expansion link, 6010-limiting plate, 6011-first linkage block, 6012-second rope, 6013-fourth elastic expansion link, 6014-second linkage block, 701-fifth elastic expansion link, 702-second linkage frame, 703-sixth elastic expansion link, 704-second linkage plate, 705-third expansion cylinder, 706-third linkage plate, 707-third rope, 708-second pulley frame.

Detailed Description

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

Example 1

A quantitative feeding mechanism for building construction is disclosed, as shown in figures 1-9, comprising a first support frame 1, wheels 2, a level sensor 3, a speed sensor 4, a feeding assembly, a driving assembly, a fixing assembly, a protection assembly and a lifting assembly; four wheels 2 are fixedly connected to the lower side of the first support frame 1; the middle part of the right side of the first support frame 1 is provided with a lifting component; the lower part of the right side of the ascending component is provided with a feeding component; the upper part of the front side of the feeding assembly is provided with a driving assembly; the middle part of the feeding assembly is provided with a fixing assembly; the upper part of the right side of the feeding assembly is provided with a protection assembly; the lower part of the right side of the feeding component is fixedly connected with a horizontal sensor 3; the lower part of the right side of the feeding assembly is fixedly connected with a speed sensor 4, and the speed sensor 4 is positioned below the horizontal sensor 3.

The feeding assembly comprises a storage box 201, a sliding plate 202, a first connecting block 203, a first elastic telescopic rod 204, a first limiting rod 205, a first linkage plate 206, a spring 207, a first telescopic cylinder 208, a clamping plate 209, a second connecting block 2010, a multi-stage hydraulic rod 2011 and a push plate 2012; a storage box 201 is arranged at the lower part of the right side of the ascending component; a sliding plate 202 is slidably connected to each of the upper left portion and the upper right portion of the storage box 201; the front parts of the two sliding plates 202 on the opposite sides are both connected with a first connecting block 203 through bolts; two first elastic telescopic rods 204 are fixedly connected to the front part of the inner side of the storage box 201; the telescopic ends of the two first elastic telescopic rods 204 are fixedly connected with the corresponding first connecting blocks 203 respectively; two first limiting rods 205 are welded on the upper sides of the two sliding plates 202; each two corresponding first limiting rods 205 are connected with a first linkage plate 206 in a sliding manner; the four first limiting rods 205 are respectively sleeved with a spring 207, the upper ends of the springs 207 are fixedly connected with the corresponding first limiting rods 205, and the lower ends of the springs 207 are fixedly connected with the corresponding first linkage plates 206; two first telescopic cylinders 208 are fixedly connected to the back sides of the two first linkage plates 206; the telescopic ends of every two corresponding first telescopic cylinders 208 are fixedly connected with a clamping plate 209, and the opposite sides of the two clamping plates 209 are provided with rubber pads; two second connecting blocks 2010 are connected to the middle part of the lower side of the storage box 201 through bolts; a multi-stage hydraulic rod 2011 is fixedly connected to the lower parts of the two second connecting blocks 2010; the telescopic ends of the two multi-stage hydraulic rods 2011 are fixedly connected with push plates 2012.

The driving assembly comprises a first pushing block 301, a second pushing block 302, a rack 303, a first motor 304 and a spur gear 305; two first push blocks 301 are connected to the upper portion of the front side of the storage box 201 in a sliding mode, and the rear sides of the first push blocks 301 are inclined planes; the front parts of the lower sides of the two first push blocks 301 are fixedly connected with a second push block 302; the middle parts of the upper sides of the two first push blocks 301 are fixedly connected with a rack 303; two first motors 304 are mounted at the upper part of the front side of the storage box 201, and the two first motors 304 are positioned at the inner sides of the two first push blocks 301; a spur gear 305 is fixedly connected to the output shafts of the two first motors 304; the two spur gears 305 are respectively engaged with the corresponding racks 303.

The fixing component comprises a second telescopic cylinder 401, a first linkage frame 402, a second elastic telescopic rod 403, a second limiting rod 404 and a fixing plate 405; a second telescopic cylinder 401 is fixedly connected to the middle of the left side and the middle of the right side of the storage box 201; the telescopic ends of every two corresponding second telescopic cylinders 401 penetrate through the storage box 201 and are fixedly connected with a first linkage frame 402; four second elastic telescopic rods 403 are fixedly connected to the outer edges of the opposite sides of the two first linkage frames 402; the telescopic ends of every two adjacent upper and lower second elastic telescopic rods 403 are fixedly connected with a second limiting rod 404; two fixed plates 405 are fixed to the middle of two first link frames 402 opposite sides, and rubber pads are arranged on two fixed plates 405 opposite sides.

The protection component comprises a second support frame 501, an electric slide rail 502, an electric slide block 503, a baffle 504 and a bending plate 505; the middle part of the right side of the storage box 201 is connected with a second support frame 501 through bolts; an electric sliding rail 502 is fixedly connected to the upper side of the second support frame 501; an electric sliding block 503 is connected on the electric sliding rail 502 in a sliding manner; a baffle 504 is fixedly connected to the upper side of the electric sliding block 503; a bent plate 505 is welded to the right side of the baffle 504.

When the device is prepared for work, the device is pushed to the front of an indoor wall, then a constructor puts a bundle of tiles into the storage box 201, then the fixing ropes on the tiles are cut off, then the fixing ropes are drawn out, the tiles stacked in order can generate a deflection phenomenon in the drawing process, at the moment, the second telescopic cylinder 401 drives the first linkage frame 402 to move towards the tiles, the first linkage frame 402 drives the second elastic telescopic rod 403 to move, the second elastic telescopic rod 403 drives the second limiting rod 404 to move towards the tiles, so that the four second limiting rods 404 simultaneously move towards the tiles, the tiles are positioned in the middle of the storage box 201 in the whole stack of tiles positioning, and viewed from top, the tiles are positioned between the two clamping plates 209, so that the deflected tiles are prevented from being blocked when moving upwards relative to the clamping plates 209, then the ascending component drives the storage box 201 to move upwards to the right part at the upper side of the first support frame 1, and the storage box 201 drives the parts related to move, thereby transporting the ceramic tile to the high position of the first supporting frame 1, then two multi-stage hydraulic rods 2011 simultaneously drive the push plate 2012 to move upwards, the push plate 2012 pushes the whole stack of ceramic tiles to move upwards, so that the ceramic tile positioned at the top is positioned in the middle of the gap between the two clamping plates 209, then the first telescopic cylinder 208 drives the clamping plates 209 to move towards the ceramic tile, so that the two clamping plates 209 clamp the ceramic tile, the first motor 304 is started, the first motor 304 drives the spur gear 305 to rotate, the spur gear 305 drives the rack 303 to move backwards, the rack 303 drives the first push block 301 to move backwards to contact the first linkage plate 206, the first push block 301 continues to move backwards to push the first linkage plate 206 to move upwards, the first linkage plate 206 slides upwards on the first limiting rod 205 and compresses the spring 207, the first linkage plate 206 drives the first telescopic cylinder 208 to move upwards, the first telescopic cylinder 208 drives the clamping plates 209 to move upwards, so that the two clamping plates 209 simultaneously drive the topmost ceramic tile to move upwards, so that the topmost ceramic tile stops contacting the ceramic tile below the topmost ceramic tile, meanwhile, the first push block 301 drives the second push block 302 to move backwards to contact the sliding plate 202, the sliding plate 202 drives parts on the sliding plate to move backwards, and the first elastic telescopic rod 204 is stretched, so that the two clamping plates 209 drive the topmost ceramic tile to move backwards, so that the rear end of the topmost ceramic tile extends backwards, thereby being convenient for a constructor on the first support frame 1 to take out the topmost ceramic tile, and simultaneously avoiding the phenomenon of scraping of the ceramic tile caused by friction, when the constructor takes out the topmost ceramic tile, the first telescopic cylinder 208 drives the clamping plates 209 to move away from the ceramic tile stack, the first motor 304 drives the spur gear 305 to rotate backwards, so that the first push block 301 and the second push block 302 move forwards to return to the original position, the spring 207 drives the first clamping plate 206 to move downwards to return to the original position, the first elastic expansion link 204 drives the sliding plate 202 to move back to the original position, thereby completing the reset operation, then the operations are repeated to carry out the blanking operation on the ceramic tiles positioned at the top in sequence, when the device has the phenomenon of toppling, the horizontal sensor 3 detects that toppling occurs, then the second expansion cylinder 401 drives the first linkage frame 402 to move towards the ceramic tiles, the first linkage frame 402 drives the fixed plates 405 to move towards the ceramic tiles, thereby leading the two fixed plates 405 to clamp the whole stack of ceramic tiles, meanwhile, the electric slide block 503 moves leftwards on the electric slide rail 502, the electric slide block 503 drives the baffle 504 to move leftwards, leading the baffle 504 to move to the upper part of the ceramic tiles to limit the position, meanwhile, the baffle 504 drives the bending plate 505 to move leftwards to the rear side of the ceramic tiles, avoiding the ceramic tiles from sliding backwards, realizing the automatic transportation of the whole stack of ceramic tiles to the high place during the use, and simultaneously automatically extending out the end part of the ceramic tiles positioned at the top, be convenient for constructor gets the material, accomplish automatic unloading operation to avoided scraping colored phenomenon because of the ceramic tile that the friction leads to, automatic simultaneously is fixed a position to stacking the ceramic tile, is blockked when the relative splint 209 upward movement of ceramic tile of avoiding the skew, is fixed and spacing to stacking the ceramic tile automatically when the phenomenon of taking place the skew simultaneously, avoids the ceramic tile landing to ground to break into pieces.

Example 2

On the basis of embodiment 1, as shown in fig. 1 to 3 and fig. 10 to 13, the ascending assembly includes a first connecting plate 601, a guide rail plate 602, a sliding block 603, a first rope 604, a first pulley frame 605, a second motor 606, a hollow cylinder 607, a second connecting plate 608, a third stretch telescopic rod 609, a limiting plate 6010, a first linkage block 6011, a second rope 6012, a fourth stretch telescopic rod 6013, and a second linkage block 6014; the lower part of the right side of the first support frame 1 is connected with a first connecting plate 601 through a bolt; a guide rail plate 602 is fixedly connected between the upper part of the right side of the first support frame 1 and the middle part of the right side of the first connecting plate 601; a sliding block 603 is slidably connected on the guide rail plate 602; a first rope 604 is fixedly connected to the left part of the upper side of the sliding block 603; a first pulley yoke 605 is fixedly connected to the upper part of the right side of the first support frame 1; a second motor 606 is arranged on the upper side of the wheel 2 positioned on the right front side; an output shaft of the second motor 606 is fixedly connected with a hollow cylinder 607; the first rope 604 bypasses the upper side of the first pulley yoke 605 and is fixedly connected with the hollow cylinder 607; a second connecting plate 608 is fixedly connected to the middle part of the guide rail plate 602; two third elastic telescopic rods 609 are fixedly connected to the left side and the right side of the second connecting plate 608; each two corresponding telescopic ends of the third elastic telescopic rods 609 are fixedly connected with a limiting plate 6010, and the two limiting plates 6010 are arranged in a bilateral symmetry manner; the middle parts of the opposite sides of the two limiting plates 6010 are welded with a first linkage block 6011; both first link blocks 6011 are in contact with the second connecting plate 608; a fourth elastic expansion link 6013 is fixedly connected to the middle part of the left side and the middle part of the right side of the second connecting plate 608; the telescopic ends of the two fourth elastic telescopic rods 6013 are fixedly connected with a second linkage block 6014; the two second linkage blocks 6014 are respectively in contact with the corresponding first linkage blocks 6011; both second link blocks 6014 are in contact with second connecting plate 608; a second rope 6012 is fixedly connected to the front parts of the lower sides of the two second linkage blocks 6014; the lower ends of the two second ropes 6012 both penetrate through the guide rail plate 602 and are connected with it in a sliding manner; the left side of the inner wall of the sliding block 603 and the right side of the inner wall are both provided with a barb block, the barb faces downwards, and the two barb blocks are arranged in a bilateral symmetry manner; upward barbs are arranged on the opposite sides of the two limiting plates 6010; the upper side of the first link block 6011 is an inclined surface, and the lower side of the second link block 6014 is an inclined surface.

The lifting mechanism further comprises a buffering assembly, the buffering assembly is mounted at the lower part of the right side of the lifting assembly, and the buffering assembly comprises a fifth elastic telescopic rod 701, a second linkage frame 702, a sixth elastic telescopic rod 703, a second linkage plate 704, a third telescopic cylinder 705, a third linkage plate 706, a third rope 707 and a second pulley frame 708; a fifth elastic telescopic rod 701 is fixedly connected to the lower part of the front side and the lower part of the rear side of the guide rail plate 602; the telescopic ends of the two fifth elastic telescopic rods 701 are fixedly connected with a second linkage frame 702; two sixth elastic telescopic rods 703 are fixedly connected to the upper sides of the two second linkage frames 702; the telescopic ends of every two corresponding sixth elastic telescopic rods 703 are fixedly connected with a second linkage plate 704; a third telescopic cylinder 705 is fixedly connected to the middle of the left side of the first connecting plate 601; a telescopic end of the third telescopic cylinder 705 is fixedly connected with a third linkage plate 706; two third ropes 707 are fixedly connected to the upper side of the third linkage plate 706; two second pulley frames 708 are fixedly connected to the lower portion of the guide rail plate 602, and the two second pulley frames 708 are located below the two fifth elastic telescopic rods 701; the third rope 707 bypasses the upper side of the corresponding second pulley frame 708 and is fixedly connected with the corresponding second linkage frame 702; two second cables 6012 are each fixedly connected to the third linkage plate 706 through the rail plate 602.

The operation of lifting the storage box 201 in the first embodiment is as follows: the second motor 606 is started, the second motor 606 drives the hollow cylinder 607 to rotate, the hollow cylinder 607 winds the first rope 604, the first rope 604 pulls the sliding block 603 to move upwards under the guiding action of the first pulley yoke 605, and the sliding block 603 drives the storage box 201 to move upwards; when the first rope 604 is broken, the storage box 201 drives the sliding block 603 to slide downwards rapidly, the speed sensor 4 detects that the movement speed is increased suddenly, at this time, the third telescopic cylinder 705 drives the third link plate 706 to move downwards, the third link plate 706 drives the two second ropes 6012 to move downwards, the second rope 6012 drives the second link block 6014 to move downwards, and the fourth elastic telescopic rod 6013 is stretched, so that the second link block 6014 pushes the first link block 6011 to move away from the second connecting plate 608, the first link block 6011 drives the limiting plate 6010 to move, and stretches the third elastic telescopic rod 609, so that the two limiting plates 6010 move back to back, so that the sawteeth of the two limiting plates 6010 are clamped into the sawteeth blocks on the inner sides of the sliding block 603, so as to block and limit the sliding block 603, and at the same time, the third link plate 706 pulls the third rope 707 to move, under the guiding action of the second pulley frame 708, the third rope 707 pulls the second linkage frame 702 to move, the second linkage frame 702 drives parts on the second linkage frame to move towards the inner side, the fifth elastic expansion rod 701 is compressed, the two second linkage plates 704 move to the lower side of the storage box 201, the storage box 201 descends rapidly to impact the two second linkage plates 704, then the storage box 201 decelerates the storage box through the four sixth elastic expansion rods 703, the sliding block 603 is automatically stopped and limited when the first rope 604 breaks during use, the storage box 201 decelerates, meanwhile, the storage box 201 is automatically decelerated through the four sixth elastic expansion rods 703, and the safety is further improved.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims

1. A quantitative feeding mechanism for building construction comprises a first support frame (1), wheels (2), a level sensor (3) and a speed sensor (4); four wheels (2) are fixedly connected to the lower side of the first support frame (1); the method is characterized in that: the device also comprises a feeding assembly, a driving assembly, a fixing assembly, a protection assembly and a lifting assembly; the middle part of the right side of the first support frame (1) is provided with a lifting component for lifting; a feeding assembly for feeding the tiles one by one is arranged at the lower part of the right side of the lifting assembly; a driving component for driving is arranged at the upper part of the front side of the feeding component; the middle part of the feeding assembly is provided with a fixing assembly for positioning and fixing the ceramic tile; a protection component for preventing the ceramic tiles from sliding is arranged at the upper part of the right side of the feeding component; a horizontal sensor (3) is fixedly connected to the lower part of the right side of the feeding assembly; and a speed sensor (4) is fixedly connected to the lower part of the right side of the feeding assembly, and the speed sensor (4) is positioned below the horizontal sensor (3).

2. The quantitative feeding mechanism for building construction as claimed in claim 1, wherein: the feeding assembly comprises a storage box (201), a sliding plate (202), a first connecting block (203), a first elastic telescopic rod (204), a first limiting rod (205), a first linkage plate (206), a spring (207), a first telescopic cylinder (208), a clamping plate (209), a second connecting block (2010), a multi-stage hydraulic rod (2011) and a push plate (2012); a storage box (201) is arranged at the lower part of the right side of the ascending component; the upper left part and the upper right part of the storage box (201) are both connected with a sliding plate (202) in a sliding way; the front parts of the two sliding plates (202) at the opposite sides are fixedly connected with a first connecting block (203); two first elastic telescopic rods (204) are fixedly connected to the front part of the inner side of the storage box (201); the telescopic ends of the two first elastic telescopic rods (204) are fixedly connected with the corresponding first connecting blocks (203) respectively; two first limiting rods (205) are fixedly connected to the upper sides of the two sliding plates (202); each two corresponding first limiting rods (205) are connected with a first linkage plate (206) in a sliding manner; the four first limiting rods (205) are sleeved with springs (207), the upper ends of the springs (207) are fixedly connected with the corresponding first limiting rods (205), and the lower ends of the springs (207) are fixedly connected with the corresponding first linkage plates (206); two first telescopic cylinders (208) are fixedly connected to the back sides of the two first linkage plates (206); the telescopic ends of every two corresponding first telescopic cylinders (208) are fixedly connected with a clamping plate (209), and rubber pads are arranged on the opposite sides of the two clamping plates (209); two second connecting blocks (2010) are fixedly connected to the middle of the lower side of the storage box (201); the lower parts of the two second connecting blocks (2010) are fixedly connected with a multi-stage hydraulic rod (2011); the telescopic ends of the two multi-stage hydraulic rods (2011) are fixedly connected with a push plate (2012).

3. The quantitative feeding mechanism for building construction as claimed in claim 2, wherein: the driving assembly comprises a first pushing block (301), a second pushing block (302), a rack (303), a first motor (304) and a straight gear (305); the upper part of the front side of the storage box (201) is connected with two first push blocks (301) in a sliding manner, and the rear side of each first push block (301) is an inclined plane; the front parts of the lower sides of the two first push blocks (301) are fixedly connected with a second push block (302); the middle parts of the upper sides of the two first push blocks (301) are fixedly connected with a rack (303); two first motors (304) are mounted at the upper part of the front side of the storage box (201), and the two first motors (304) are positioned at the inner sides of the two first push blocks (301); output shafts of the two first motors (304) are fixedly connected with a straight gear (305); the two straight gears (305) are respectively meshed with the corresponding racks (303).

4. The quantitative feeding mechanism for building construction as claimed in claim 3, wherein: the fixing component comprises a second telescopic cylinder (401), a first linkage frame (402), a second elastic telescopic rod (403), a second limiting rod (404) and a fixing plate (405); a second telescopic cylinder (401) is fixedly connected to the middle of the left side and the middle of the right side of the storage box (201); the telescopic ends of every two corresponding second telescopic cylinders (401) penetrate through the storage box (201) and are fixedly connected with a first linkage frame (402); the outer edges of the opposite sides of the two first linkage frames (402) are fixedly connected with four second elastic telescopic rods (403); the telescopic ends of every two adjacent upper and lower second elastic telescopic rods (403) are fixedly connected with a second limiting rod (404); two fixed plates (405) are fixed in the middle of the opposite sides of the two first linkage frames (402), and rubber pads are arranged on the opposite sides of the two fixed plates (405).

5. The quantitative feeding mechanism for building construction as claimed in claim 4, wherein: the protection assembly comprises a second support frame (501), an electric sliding rail (502), an electric sliding block (503), a baffle (504) and a bending plate (505); a second support frame (501) is fixedly connected to the middle of the right side of the storage box (201); an electric sliding rail (502) is fixedly connected to the upper side of the second support frame (501); an electric sliding block (503) is connected on the electric sliding rail (502) in a sliding way; a baffle (504) is fixedly connected to the upper side of the electric slide block (503); a bending plate (505) is fixedly connected to the right side of the baffle plate (504).

6. The quantitative feeding mechanism for building construction according to claim 5, wherein: the ascending assembly comprises a first connecting plate (601), a guide rail plate (602), a sliding block (603), a first rope (604), a first pulley frame (605), a second motor (606), a hollow cylinder (607), a second connecting plate (608), a third elastic telescopic rod (609), a limiting plate (6010), a first linkage block (6011), a second rope (6012), a fourth elastic telescopic rod (6013) and a second linkage block (6014); a first connecting plate (601) is fixedly connected to the lower part of the right side of the first support frame (1); a guide rail plate (602) is fixedly connected between the upper part of the right side of the first support frame (1) and the middle part of the right side of the first connecting plate (601); a sliding block (603) is connected on the guide rail plate (602) in a sliding way; a first rope (604) is fixedly connected to the left part of the upper side of the sliding block (603); a first pulley yoke (605) is fixedly connected to the upper part of the right side of the first support frame (1); a second motor (606) is arranged on the upper side of the wheel (2) positioned on the right front side; an output shaft of the second motor (606) is fixedly connected with a hollow cylinder (607); the first rope (604) is fixedly connected with the hollow cylinder (607) by bypassing the upper side of the first pulley yoke (605); a second connecting plate (608) is fixedly connected to the middle part of the guide rail plate (602); two third elastic telescopic rods (609) are fixedly connected to the left side and the right side of the second connecting plate (608); the telescopic ends of every two corresponding third elastic telescopic rods (609) are fixedly connected with a limiting plate (6010), and the two limiting plates (6010) are arranged in a bilateral symmetry manner; the middle parts of the opposite sides of the two limiting plates (6010) are fixedly connected with a first linkage block (6011); the two first linkage blocks (6011) are both in contact with the second connecting plate (608); a fourth elastic telescopic rod (6013) is fixedly connected to the middle part of the left side and the middle part of the right side of the second connecting plate (608); the telescopic ends of the two fourth elastic telescopic rods (6013) are fixedly connected with a second linkage block (6014); the two second linkage blocks (6014) are respectively contacted with the corresponding first linkage blocks (6011); both second linkage blocks (6014) are in contact with the second connecting plate (608); a second rope (6012) is fixedly connected to the front parts of the lower sides of the two second linkage blocks (6014); the lower ends of the two second ropes (6012) penetrate through the guide rail plate (602) and are connected with the guide rail plate in a sliding mode.

7. The quantitative feeding mechanism for building construction as claimed in claim 6, wherein: sliding block (603) inner wall left side and inner wall right side all are provided with a barb piece to the barb is down, and two barb pieces set up for bilateral symmetry moreover.

8. The quantitative feeding mechanism for building construction as claimed in claim 6, wherein: and the opposite sides of the two limiting plates (6010) are provided with upward barbs.

9. The quantitative feeding mechanism for building construction as claimed in claim 6, wherein: the upper side of the first linkage block (6011) is an inclined surface, and the lower side of the second linkage block (6014) is an inclined surface.

10. The quantitative feeding mechanism for building construction based on claim 6 is characterized in that: the lifting mechanism is characterized by further comprising a buffering assembly, the buffering assembly is mounted at the lower portion of the right side of the lifting assembly and comprises a fifth elastic telescopic rod (701), a second linkage frame (702), a sixth elastic telescopic rod (703), a second linkage plate (704), a third telescopic cylinder (705), a third linkage plate (706), a third rope (707) and a second pulley frame (708); a fifth elastic telescopic rod (701) is fixedly connected to the lower part of the front side and the lower part of the rear side of the guide rail plate (602); the telescopic ends of the two fifth elastic telescopic rods (701) are fixedly connected with a second linkage frame (702); two sixth elastic telescopic rods (703) are fixedly connected to the upper sides of the two second linkage frames (702); the telescopic ends of every two corresponding sixth elastic telescopic rods (703) are fixedly connected with a second linkage plate (704); a third telescopic cylinder (705) is fixedly connected to the middle of the left side of the first connecting plate (601); the telescopic end of the third telescopic cylinder (705) is fixedly connected with a third linkage plate (706); two third ropes (707) are fixedly connected to the upper side of the third linkage plate (706); two second pulley frames (708) are fixedly connected to the lower portion of the guide rail plate (602), and the two second pulley frames (708) are located below the two fifth elastic telescopic rods (701); the third rope (707) bypasses the upper side of the corresponding second pulley frame (708) and is fixedly connected with the corresponding second linkage frame (702); and two second ropes (6012) penetrate through the guide rail plate (602) and are fixedly connected with the third linkage plate (706).