CN108438837B - Mosaic conveyor - Google Patents

Abstract

The mosaic conveying device comprises a main conveying belt and a receiving conveying belt, wherein the receiving conveying belt is arranged at the upstream end of the main conveying belt, and the receiving conveying belt is arranged above the main conveying belt; the middle part of the carrying conveyer belt is in a landslide shape to the upstream end, and the upstream end of the carrying conveyer belt is the lowest point; an arc-shaped sliding plate is arranged below the upstream end of the carrying conveyor belt, the upper end of the arc-shaped sliding plate is positioned behind the upstream end of the carrying conveyor belt, and a gap through which a mosaic passes is reserved between the arc-shaped sliding plate and the upstream end of the carrying conveyor belt; the lower end of the arc-shaped sliding plate is positioned above the main conveying belt. The invention aims to provide a mosaic conveying device which can sort mosaics in batches and enable the upper surfaces of the mosaics to face upwards uniformly.

Description

Mosaic conveyor

Technical Field

The invention relates to the field of building decoration ceramic equipment, in particular to a mosaic conveying device.

Background

Mosaic tiles are small tiles, most of which are used for being attached to the surface of a building and used for protecting and decorating the building, and in order to facilitate the attachment, the individual mosaics are usually spliced into a certain area and then are attached to the surface.

The surface of the mosaic has a decorative effect and is in a smooth state, and the design of the back surface is a rough surface, mainly for facilitating the lamination; when small mosaics are piled into large-area mosaics, the surface of the mosaics is required to be uniformly upwards or the back of the mosaics is required to be uniformly downwards, so that the disordered mosaics are required to be tidied, and the current tidying mode adopts manual tidying, so that the tidying mode is low in efficiency.

Disclosure of Invention

In view of the above-mentioned drawbacks, an object of the present invention is to provide a mosaic conveying device that can sort mosaics in batches so that the upper surfaces of the mosaics face upward uniformly.

To achieve the purpose, the invention adopts the following technical scheme:

the mosaic conveying device comprises a main conveying belt and a receiving conveying belt, wherein the receiving conveying belt is arranged at the upstream end of the main conveying belt, and the receiving conveying belt is arranged above the main conveying belt;

the middle part of the carrying conveyer belt is in a landslide shape to the upstream end, and the upstream end of the carrying conveyer belt is the lowest point;

an arc-shaped sliding plate is arranged below the upstream end of the carrying conveyor belt, the upper end of the arc-shaped sliding plate is positioned behind the upstream end of the carrying conveyor belt, and a gap for a mosaic to pass through is reserved between the arc-shaped sliding plate and the upstream end of the carrying conveyor belt;

the lower end of the arc-shaped sliding plate is positioned above the main conveying belt.

Preferably, the main conveyor belt is inclined, and the main conveyor belt is provided with a bearing plate;

the downstream end of the main conveyor belt is high, the upstream end of the main conveyor belt is low, and the bearing plate is arranged below the upstream end of the main conveyor belt.

Preferably, the feeding device comprises a feeding table and a roller brush;

the roller brush is arranged on the feeding table, and a gap between a roller surface of the roller brush and the feeding table is not smaller than the thickness of the mosaic.

Preferably, a guide plate is mounted at the downstream end of the receiving conveyor belt;

the guide plate is inclined, the upper end of the guide plate is positioned on the conveying surface in the downstream direction of the receiving conveyer belt, and the lower end of the guide plate is positioned above the main conveyer belt;

the distance between the lower end of the guide plate and the main conveying belt is not smaller than the thickness of the mosaic.

Further, the device also comprises a guide device, wherein the guide device comprises two guide strips, and the two guide strips are arranged above the main conveying belt in a horn shape;

the opening of the guide device faces the downstream direction of the receiving conveyor belt, and the closing-in of the guide device faces the downstream direction of the main conveyor belt.

Further, the bearing conveyor belt comprises a bearing frame, a front roller, a rear roller, a jacking roller and an industrial belt;

the roller on the carrying conveyer belt is arranged on the carrying frame, and the carrying frame is sequentially rotatably provided with a rear roller, a jacking roller and a front roller from the upstream direction to the downstream direction;

the inner ring of the industrial belt is sleeved on the front roller and the rear roller, and the jacking roller between the front roller and the rear roller jacks up the industrial belt upwards, so that the industrial belt is not conveyed upwards in a slope shape.

Further, the device also comprises a driving device, wherein the driving device is arranged on the main conveying belt and drives the main conveying belt to run;

the transmission roller of the main conveying belt is provided with a first synchronous wheel, the front roller for receiving the conveying belt is provided with a second synchronous wheel, and the first synchronous wheel and the second synchronous wheel are arranged through a synchronous belt or a synchronous chain.

Further, the arc-shaped sliding plate is detachably arranged on the bearing rack.

The invention has the beneficial effects that: 1. when the scheme is used, the mosaic is firstly conveyed to the upstream end of the receiving conveyer belt, and if the front side of the mosaic faces upwards, the mosaic is conveyed to the downstream direction of the receiving conveyer belt by the receiving conveyer belt and finally falls to the main conveyer belt; otherwise, if the back of the mosaic is upward, the mosaic slides into the arc-shaped sliding plate from the receiving conveyer belt, and the mosaic falls on the conveying surface of the main conveyer belt in a right-side upward posture after being guided by the arc-shaped sliding plate, so that the mosaic is output by the main conveyer belt in the right-side upward posture after passing through the receiving conveyer belt, and the mosaic is turned over in the right-side upward posture; according to the scheme, the mosaic conveying device formed by the bearing conveying belt, the arc-shaped sliding plate and the main conveying belt can carry out turning correction on the mosaics in batches, and compared with the current working state, the working efficiency is improved; 2. because the main conveying belt is inclined, when the main conveying belt is connected to the mosaic sliding out of the arc-shaped sliding plate, if the mosaic falls on the main conveying belt in a way that the smooth surface (front surface) is downward, the mosaic also slides to the bearing plate from the main conveying belt, and after being collected by the bearing plate, the mosaic is turned over again, so that the scattering of the mosaic is avoided, and the mosaic with the downward front surface is further screened.

Drawings

FIG. 1 is a schematic side view of an overall structure of one embodiment of the present invention;

FIG. 2 is a schematic diagram of a top view of the overall structure of one embodiment of the present invention;

fig. 3 is a partial enlarged view at a in fig. 1.

Wherein: the main conveyor belt 100, the receiving conveyor belt 200, the receiving frame 210, the front roller 220, the rear roller 230, the jack-up roller 240, the industrial belt 250, the arc-shaped slide plate 300, the carrier plate 400, the feeding device 500, the feeding table 510, the roller brush 520, the guide plate 600, the guide device 700, and the guide bar 710.

Detailed Description

The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.

As shown in fig. 1 to 3, a mosaic conveyor includes a main conveyor belt 100 and a receiving conveyor belt 200, the receiving conveyor belt 200 is mounted on an upstream end of the main conveyor belt 100, and the receiving conveyor belt 200 is mounted above the main conveyor belt 100;

the middle part of the carrying conveyer belt 200 is in a landslide shape to the upstream end, and the upstream end of the carrying conveyer belt 200 is the lowest point;

an arc-shaped sliding plate 300 is arranged below the upstream end of the carrying conveyor belt 200, the upper end of the arc-shaped sliding plate 300 is positioned behind the upstream end of the carrying conveyor belt 200, and a gap through which a mosaic passes is reserved between the arc-shaped sliding plate 300 and the upstream end of the carrying conveyor belt 200;

the lower end of the arc-shaped sled 300 is located above the main conveyor belt 100.

When the scheme is used, the mosaic is firstly conveyed to the upstream end of the receiving conveyer belt, and if the front side of the mosaic faces upwards at the moment, the mosaic is conveyed to the downstream direction of the receiving conveyer belt by the receiving conveyer belt 200 and finally falls to the main conveyer belt 100; if the back of the mosaic is upward, the mosaic slides from the receiving conveyor belt 200 into the arc-shaped slide plate 300, and the mosaic falls on the conveying surface of the main conveyor belt 100 in a right-side upward posture after being guided by the arc-shaped slide plate, so that the mosaic is output from the main conveyor belt 100 in the right-side upward posture after passing through the receiving conveyor belt 200, regardless of whether the mosaic is right-side upward or turned over upward; according to the scheme, the mosaic conveying device formed by the bearing conveying belt 200, the arc-shaped sliding plate 300 and the main conveying belt 100 can be used for carrying out turn-over correction on the mosaics in batches, and the working efficiency is improved relative to the current working state.

Wherein the main conveyor belt 100 is inclined, and the main conveyor belt 100 is provided with a carrier plate 400;

the downstream end of the main conveyor belt 100 is high, the upstream end of the main conveyor belt 100 is low, and the carrier plate 400 is installed below the upstream end of the main conveyor belt 100.

Since the main conveyor belt 100 is inclined, when the main conveyor belt 100 receives the mosaic sliding out of the arc-shaped slide plate 300, if the mosaic falls down on the main conveyor belt 100 with the smooth surface (front surface) facing downward, the mosaic also slides down from the main conveyor belt 100 to the carrier plate 400, and is turned again after being collected by the carrier plate 400, so that the mosaic is prevented from falling off, and the mosaic facing downward is further screened.

Wherein, the feeding device 500 is further included, the feeding device 500 includes a feeding table 510 and a roller brush 520;

the roller brush 520 is mounted on the feeding table 510, and a gap between a roller surface of the roller brush 520 and the feeding table 510 is not smaller than a thickness of the mosaic.

The feeding device 500 is arranged to change the mosaics in a stacked state on the feeding table 510 into a flat state, so that the mosaics do not fall in a disordered state when falling on the receiving conveyor 200, and the receiving conveyor is convenient to correct the mosaics.

Further, a guide plate 600 is installed at the downstream end of the receiving conveyor 200;

the guide plate 600 is inclined, the upper end of the guide plate 600 is positioned on the conveying surface of the receiving conveyor belt 200 in the downstream direction, and the lower end of the guide plate 600 is positioned above the main conveyor belt 100;

the lower end of the guide plate 600 is spaced from the main conveyor belt 100 by a distance not less than the thickness of the mosaic.

The guide plate 600 is provided so that the mosaic on the receiving conveyer 200 can be slid onto the main conveyer 100 in a smooth state, so that the receiving conveyer 200 and the main conveyer 100 can be well engaged.

In addition, the guide device 700 is further included, the guide device 700 includes two guide strips 710, and the two guide strips 710 are arranged above the main conveyor belt 100 in a horn shape;

the opening of the guide 700 faces in the downstream direction of the receiving conveyor 200, and the closing-in of the guide 700 faces in the downstream direction of the main conveyor 100.

The arrangement of the guiding device 700 enables the mosaics to be conveyed in a centralized manner at one position, and the mosaic typesetting device is usually installed at the outlet of the guiding device 700, so that the interval at the outlet of the guiding device 700 can be adjusted in actual use.

Wherein, the receiving conveyor 200 comprises a receiving frame 210, a front roller 220, a rear roller 230, a jacking roller 240 and an industrial belt 250;

the rollers on the carrying conveyor belt 200 are mounted on the carrying frame 210, and the carrying frame 210 is sequentially rotatably provided with a rear roller, a jacking roller 240 and a front roller 220 from the upstream direction to the downstream direction;

the inner ring of the industrial belt 250 is sleeved on the front roller 220 and the rear roller, and the jacking roller 240 between the front roller 220 and the rear roller 230 jacks up the industrial belt 250, so that the industrial belt 250 is not conveyed upwards in a slope shape.

The upper conveying surface of the carrying conveying belt 200 is arranged in a slope shape, and is opposite to the slope shape, and a jacking roller 240 is used in the middle of the conveying belt, so that the problem of middle concave is avoided, the industrial belt 250 can be ensured to always have an inclined surface state, the sliding of the mosaic is facilitated, of course, the back surface of the mosaic has enough friction force, and when the back surface of the mosaic is applied to the industrial belt 250, the mosaic cannot slide.

Wherein, the device also comprises a driving device, which is arranged on the main conveyor belt 100 and drives the main conveyor belt 100 to run;

the driving roller of the main conveyor belt 100 is provided with a first synchronizing wheel, the front roller 220 of the receiving conveyor belt 200 is provided with a second synchronizing wheel, and the first synchronizing wheel and the second synchronizing wheel are installed through a synchronous belt or a synchronous chain.

The main conveyor belt 100 and the receiving conveyor belt 200 are connected by a synchronous mechanism, so that the main conveyor belt 100 and the receiving conveyor belt 200 can run at the same speed, the receiving conveyor belt 200 and the main conveyor belt 100 can be connected at the same speed, instability caused by the speed is reduced, and the mosaic can stably finish the whole sorting and correcting process.

In addition, the arc-shaped sliding plate 300 is detachably mounted on the receiving frame 210.

The arc-shaped sliding plate 300 is detachably installed, so that maintenance of equipment is facilitated.

The technical principle of the present invention is described above in connection with the specific embodiments. The description is made for the purpose of illustrating the general principles of the invention and should not be taken in any way as limiting the scope of the invention. Other embodiments of the invention will be apparent to those skilled in the art from consideration of this specification without undue burden.

Claims (5)

1. The mosaic conveying device is characterized by comprising a main conveying belt and a receiving conveying belt, wherein the receiving conveying belt is arranged at the upstream end of the main conveying belt, and the receiving conveying belt is arranged above the main conveying belt;

the middle part of the carrying conveyer belt is in a landslide shape to the upstream end, and the upstream end of the carrying conveyer belt is the lowest point;

an arc-shaped sliding plate is arranged below the upstream end of the carrying conveyor belt, the upper end of the arc-shaped sliding plate is positioned behind the upstream end of the carrying conveyor belt, and a gap for a mosaic to pass through is reserved between the arc-shaped sliding plate and the upstream end of the carrying conveyor belt;

the lower end of the arc-shaped sliding plate is positioned above the main conveying belt;

the main conveying belt is inclined, and is provided with a bearing plate;

the downstream end of the main conveying belt is high, the upstream end of the main conveying belt is low, and the bearing plate is arranged below the upstream end of the main conveying belt;

the feeding device comprises a feeding table and a roller brush;

the roller brush is arranged on the feeding table, and the gap between the roller surface of the roller brush and the feeding table is not smaller than the thickness of the mosaic;

the bearing conveyor belt comprises a bearing frame, a front roller, a rear roller, a jacking roller and an industrial belt;

the roller on the carrying conveyer belt is arranged on the carrying frame, and the carrying frame is sequentially rotatably provided with a rear roller, a jacking roller and a front roller from the upstream direction to the downstream direction;

the inner ring of the industrial belt is sleeved on the front roller and the rear roller, and the jacking roller between the front roller and the rear roller jacks up the industrial belt upwards, so that the industrial belt is not conveyed upwards in a slope shape.

2. The mosaic conveyor of claim 1, wherein a guide plate is mounted to a downstream end of the receiving conveyor;

the guide plate is inclined, the upper end of the guide plate is positioned on the conveying surface in the downstream direction of the receiving conveyer belt, and the lower end of the guide plate is positioned above the main conveyer belt;

the distance between the lower end of the guide plate and the main conveying belt is not smaller than the thickness of the mosaic.

3. The mosaic transport device of claim 1, further comprising a guide device comprising two guide bars, the two guide bars being arranged above the main conveyor belt in a trumpet shape;

the opening of the guide device faces the downstream direction of the receiving conveyor belt, and the closing-in of the guide device faces the downstream direction of the main conveyor belt.

4. The mosaic conveyor of claim 1, further comprising a drive device mounted to said main conveyor belt, said drive device driving said main conveyor belt in operation;

the transmission roller of the main conveying belt is provided with a first synchronous wheel, the front roller for receiving the conveying belt is provided with a second synchronous wheel, and the first synchronous wheel and the second synchronous wheel are arranged through a synchronous belt or a synchronous chain.

5. The mosaic transport device of claim 4, wherein the arcuate slide is removably mounted to the receiving frame.