CN115182560B - Vertical automatic wall brick pasting device for building construction - Google Patents

Abstract

The invention mainly relates to the field of wall brick paving, in particular to a vertical automatic wall brick paving device for building construction. The device comprises a bracket main body, wherein a lifting frame is arranged on the inner side of the bracket main body, a rotating base is arranged on the lower side of the lifting frame, and a fixing frame connected with the bottom of the lifting frame is arranged on the rotating base; the top of the lifting frame is provided with a lifting platform, and the upper side of the lifting platform is provided with a lifting mechanism; the rear side of the lifting mechanism is provided with a telescopic rod which is fixed on the lifting platform. The periphery of the probe forms threads, the probe stretches along the rotating shaft at the thread, and when the stretching length of the probe is identical, the tail end of each probe is contacted with the wall simultaneously, and then the ceramic tile clamped in the groove is parallel to the wall. There is echelonment bayonet socket through the spacer middle part, after the clearance between the flexible length determination adjacent ceramic tile of adjustment spacer, the spring clamp of being convenient for carries out the block to the not co-altitude position department of current bayonet socket and fixes the position of spacer.

Description

Vertical automatic wall brick pasting device for building construction

Technical Field

The invention mainly relates to the field of wall brick paving, in particular to a vertical automatic wall brick paving device for building construction.

Background

In the process of tiling by using an artificial or auxiliary bracket main body, construction is usually performed in three modes of tilting wall bodies (parallel tiling is performed on tilting wall surfaces), parallel tiling is performed on a small-radian curved wall body with adjacent tiling to form a plane with an arc surface, the conventional tiling equipment is constructed in a mode of being perpendicular to the ground, the wall bodies with incorrect tilting can be vertically corrected, when the tilting wall bodies are subjected to tiling construction, the tiling angles are required to be adjusted for multiple times, and when the arc wall bodies are trimmed to be planar tiling construction, the tiling equipment angles are required to be adjusted for multiple times, so that the tiling efficiency is greatly reduced.

Disclosure of Invention

In order to solve the problems, the invention adopts the following technical scheme.

The vertical automatic wall brick attaching device for building construction comprises a bracket main body, wherein a lifting frame is arranged on the inner side of the bracket main body, a rotating base is arranged on the lower side of the lifting frame, and a fixing frame connected with the bottom of the lifting frame is arranged on the rotating base; the top of the lifting frame is provided with a lifting platform, and the upper side of the lifting platform is provided with a lifting mechanism; the lifting mechanism is characterized in that a telescopic rod is arranged at the rear side of the lifting mechanism and fixed on the lifting platform.

Further, the lifting mechanism comprises a supporting plate and a spring clamp, the bottom end of the supporting plate is hinged to the lifting platform, a support is arranged on the rear side face of the supporting plate, and the support is connected with the telescopic rod.

Further, the recess is offered on the layer board leading flank, the left and right sides of layer board upper end and its left side middle part are provided with the pivot, the protruding fin that forms with the layer board block in pivot both ends, the pivot can rotate through the fin, it has the probe to run through in the pivot.

Further, the periphery of the probe is provided with threads, and the probe is arranged on the rotating shaft through the threads.

Further, a pressure sensor I is arranged at the front end of the probe.

Further, a spring clamp is arranged at the left lower end of the supporting plate, a plurality of spacers are arranged on the spring clamp in a penetrating manner, a pressure sensor II is arranged on the uppermost spacer, the front end of the spacer is a conical tip, the conical tip and the inner side wall of the groove are arranged on the same plane, a stepped bayonet is arranged in the middle of the spacer, and a spring clamp which is correspondingly clamped with the bayonet is arranged on the outer side of the spacer;

the spring clip forms a through opening I at the uppermost spacer.

Further, the probe diameter is the same as the septum tip thickness.

Further, the lifting mechanism is provided with a hopper above, the upper part of the bracket main body is provided with a chute which is clamped with two ends of the hopper, and the hopper can be lifted along the chute.

Further, a pressure sensor III is arranged on the right side face of the two rotating shafts on the left side, the two rotating shafts are connected through a transverse shaft, and the transverse shaft extends to one side of the spring clamp and is connected with the uppermost spacer.

Further, through openings II are formed in the left two rotating shafts.

The invention has the beneficial effects that:

1. the periphery of the probe forms threads, the probe stretches along the rotating shaft at the thread, and when the stretching length of the probe is identical, the tail end of each probe is contacted with the wall simultaneously, and then the ceramic tile clamped in the groove is parallel to the wall.

2. There is echelonment bayonet socket through the spacer middle part, after the clearance between the flexible length determination adjacent ceramic tile of adjustment spacer, the spring clamp of being convenient for carries out the block to the not co-altitude position department of current bayonet socket and fixes the position of spacer.

3. The diameter of the probe is the same as the thickness of the top end of the spacer, so that the probe drives the spacer to rotate through the transverse shaft, and the bottom surface of the spacer is tangential to the periphery of the probe and positioned on the same plane.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a schematic view of the internal structure of the bracket main body of the present invention.

Fig. 3 is a schematic view of the rear side structure of the pallet of the present invention.

Fig. 4 is a schematic view of a part of an enlarged structure of the spring card of the present invention.

Fig. 5 is a schematic diagram of the front side structure of the pallet of the present invention.

Fig. 6 is a schematic view of a partial enlarged structure of a spacer according to the present invention.

Reference numerals illustrate: 1. the support body, 2, the crane, 3, rotating base, 31, mount, 4, lifting mechanism, 41, telescopic link, 42, layer board, 421, recess, 422, pivot, 4221, probe, 4222, cross axle, 423, through-hole II, 43, spring clip, 431, spacer, 4311, bayonet socket, 432, spring clip, 433, through-hole I, 5, hopper.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The vertical automatic wall brick sticking device for building construction comprises a bracket main body 1, wherein a lifting frame 2 is arranged on the inner side of the bracket main body 1, a rotating base 3 is arranged on the lower side of the lifting frame 2, and a fixing frame 31 connected with the bottom of the lifting frame 2 is arranged on the rotating base 3;

the top of the lifting frame 2 is provided with a lifting platform, and the upper side of the lifting platform is provided with a lifting mechanism 4;

the lifting mechanism 4 is provided with a telescopic rod 41 at the rear side, and the telescopic rod 41 is fixed on the lifting platform.

The lifting mechanism 4 comprises a supporting plate 42 and a spring clamp 43, the bottom end of the supporting plate 42 is hinged with the lifting platform, a bracket is arranged on the rear side face of the supporting plate 42, and the bracket is connected with the telescopic rod 41.

The front side of the supporting plate 42 is provided with a groove 421, the left side and the right side of the upper end of the supporting plate 42 and the left side middle part of the upper end of the supporting plate 42 are provided with rotating shafts 422, protruding ribs which are engaged with the supporting plate 42 are formed at the two ends of the rotating shafts 422, the rotating shafts 422 can rotate through the protruding ribs, and probes 4221 penetrate through the rotating shafts 422.

The outer circumference of the probe 4221 is provided with a screw thread, and the probe 4221 is provided on the rotation shaft 422 by the screw thread.

The front end of the probe 4221 is provided with a pressure sensor I.

The left lower end of the supporting plate 42 is provided with a spring clamp 43, a plurality of spacers 431 are arranged on the spring clamp 43 in a penetrating manner, a pressure sensor II is arranged on the uppermost spacer 431, the front end of the spacer 431 is a conical tip, the conical tip and the inner side wall of the groove 421 are arranged on the same plane, a stepped bayonet 4311 is arranged in the middle of the spacer 431, and a spring clamp 432 which is correspondingly clamped with the bayonet 4311 is arranged on the outer side of the spacer 431;

the spring clip 43 forms a through opening i 433 at the uppermost spacer 431.

The tips of the diameter spacers 431 of probe 4221 are the same thickness.

The lifting mechanism 4 is provided with a hopper 5 above, the upper part of the bracket main body 1 is provided with sliding grooves which are clamped with two ends of the hopper 5, and the hopper 5 can lift along the sliding grooves.

The right side surfaces of the two rotary shafts 422 on the left side are provided with pressure sensors iii, and the two rotary shafts 422 are connected by a transverse shaft 4222, and the transverse shaft 4222 extends to the side of the spring clip 43 and is connected to the uppermost spacer 431.

The two rotating shafts 422 on the left side are provided with through openings II.

The using method of the device comprises the following steps:

step one: when vertical tiling is carried out, tiles are placed in the grooves 421, the smooth surfaces of the tiles are contacted with the supporting plates 42, concrete or other tiling paint is added into the hopper 5, the paint in the hopper 5 flows onto the rough surfaces of the tiles and gradually flows towards the lower end of the tiles along the gradient of the lifting mechanism 4, the rotating base 3 is rotated to enable the side surface of the lifting mechanism 4, which is close to one side of the wall, to be parallel to the wall, and the lifting frame 2 is lifted to adjust the height of the tiles.

Step two: the telescopic rod 41 pushes the lifting mechanism 4 to enable the lifting mechanism 4 to be gradually in a state of being perpendicular to the bottom surface, and at the moment, the ceramic tile is attached to the wall body to form a state of being perpendicular to the bottom surface.

Step three: when parallel tiling is carried out along the wall surface, the front and back positions of the bracket main body 1 and the inclination degree of the lifting mechanism 4 are adjusted through the data of the pressure sensors I, so that after the probes 4221 are contacted with the wall surface to the same extent, the ceramic tile is attached to the wall surface at the moment, and the parallel state of the ceramic tile and the wall surface is formed.

Step four: when the tile is trimmed by the small radian wall, the straight line connection direction of the two ends of the arc wall is determined, the right-most end of the arc wall is vertically tiled, the probe 4221 which is positioned on the right side of the upper end of the groove 421 and the right side of the middle of the groove 421 is rotated to the right side, the spacer 431 is driven to synchronously rotate through the transverse shaft 4222, at the moment, when the tile is tiled on the left side of the vertical tile, the inclination degree of the lifting mechanism 4 is adjusted, so that the pressure sensor II and the pressure sensor III squeeze the adjacent tile on the right side under the same pressure, the tile is attached to the wall at the moment, the tile and the adjacent tile on the right side are in a parallel state, and the smooth surface of the tile is positioned on the same plane.

The present invention can be easily implemented by those skilled in the art through the above specific embodiments. It should be understood that the invention is not limited to the particular embodiments described above. Based on the disclosed embodiments, a person skilled in the art may combine different technical features at will, so as to implement different technical solutions.

Claims (4)

1. The utility model provides a vertical automatic wall brick device is pasted to construction which characterized in that: the lifting device comprises a bracket main body (1), wherein a lifting frame (2) is arranged on the inner side of the bracket main body (1), a rotating base (3) is arranged on the lower side of the lifting frame (2), and a fixing frame (31) connected with the bottom of the lifting frame (2) is arranged on the rotating base (3);

a lifting platform is arranged at the top of the lifting frame (2), and a lifting mechanism (4) is arranged on the upper side of the lifting platform;

a telescopic rod (41) is arranged at the rear side of the lifting mechanism (4), and the telescopic rod (41) is fixed on the lifting platform;

the lifting mechanism (4) comprises a supporting plate (42) and a spring clamp (43), the bottom end of the supporting plate (42) is hinged with the lifting platform, a support is arranged on the rear side surface of the supporting plate (42), and the support is connected with the telescopic rod (41);

the front side of the supporting plate (42) is provided with a groove (421), the left side, the right side and the left side middle part of the upper end of the supporting plate (42) are provided with rotating shafts (422), protruding ribs which are clamped with the supporting plate (42) are formed at two ends of each rotating shaft (422), the rotating shafts (422) can rotate through the protruding ribs, and probes (4221) penetrate through the rotating shafts (422); the periphery of the probe (4221) is provided with threads, and the probe (4221) is arranged on the rotating shaft (422) through the threads; the front end of the probe (4221) is provided with a pressure sensor I;

the spring clamp (43) is arranged at the left lower end of the supporting plate (42), a plurality of spacers (431) are arranged on the spring clamp (43) in a penetrating manner, a pressure sensor II is arranged on the uppermost spacer (431), the front end of the spacer (431) is a conical tip, the conical tip and the inner side wall of the groove (421) are on the same plane, a stepped bayonet (4311) is arranged in the middle of the spacer (431), and a spring clamp (432) which is correspondingly clamped with the bayonet (4311) is arranged on the outer side of the spacer (431); the spring clip (43) forms a through-opening I (433) at the uppermost spacer (431);

the pressure sensor III is arranged on the right side surface of the two rotating shafts (422) on the left side, the two rotating shafts (422) are connected through a transverse shaft (4222), and the transverse shaft (4222) extends to one side of the spring clamp (43) and is connected with a spacer (431) on the uppermost side.

2. The vertical automatic wall brick attaching device for building construction according to claim 1, wherein: the diameter of the probe (4221) is the same as the thickness of the top end of the spacer (431).

3. The vertical automatic wall brick attaching device for building construction according to claim 1, wherein: the lifting mechanism is characterized in that a hopper (5) is arranged above the lifting mechanism (4), sliding grooves which are clamped with two ends of the hopper (5) are formed in the upper portion of the support body (1), and the hopper (5) can ascend and descend along the sliding grooves.

4. The vertical automatic wall brick attaching device for building construction according to claim 1, wherein: and through holes II are formed in the left two rotating shafts (422).